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How to Publish a Research Paper – Step by Step Guide

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Publishing a research paper is an important step for researchers to disseminate their findings to a wider audience and contribute to the advancement of knowledge in their field. Whether you are a graduate student, a postdoctoral fellow, or an established researcher, publishing a paper requires careful planning, rigorous research, and clear writing. In this process, you will need to identify a research question , conduct a thorough literature review , design a methodology, analyze data, and draw conclusions. Additionally, you will need to consider the appropriate journals or conferences to submit your work to and adhere to their guidelines for formatting and submission. In this article, we will discuss some ways to publish your Research Paper.

How to Publish a Research Paper

To Publish a Research Paper follow the guide below:

Conduct original research : Conduct thorough research on a specific topic or problem. Collect data, analyze it, and draw conclusions based on your findings.
Write the paper : Write a detailed paper describing your research. It should include an abstract, introduction, literature review, methodology, results, discussion, and conclusion.
Choose a suitable journal or conference : Look for a journal or conference that specializes in your research area. You can check their submission guidelines to ensure your paper meets their requirements.
Prepare your submission: Follow the guidelines and prepare your submission, including the paper, abstract, cover letter, and any other required documents.
Submit the paper: Submit your paper online through the journal or conference website. Make sure you meet the submission deadline.
Peer-review process : Your paper will be reviewed by experts in the field who will provide feedback on the quality of your research, methodology, and conclusions.
Revisions : Based on the feedback you receive, revise your paper and resubmit it.
Acceptance : Once your paper is accepted, you will receive a notification from the journal or conference. You may need to make final revisions before the paper is published.
Publication : Your paper will be published online or in print. You can also promote your work through social media or other channels to increase its visibility.

How to Choose Journal for Research Paper Publication

Here are some steps to follow to help you select an appropriate journal:

Identify your research topic and audience : Your research topic and intended audience should guide your choice of journal. Identify the key journals in your field of research and read the scope and aim of the journal to determine if your paper is a good fit.
Analyze the journal’s impact and reputation : Check the impact factor and ranking of the journal, as well as its acceptance rate and citation frequency. A high-impact journal can give your paper more visibility and credibility.
Consider the journal’s publication policies : Look for the journal’s publication policies such as the word count limit, formatting requirements, open access options, and submission fees. Make sure that you can comply with the requirements and that the journal is in line with your publication goals.
Look at recent publications : Review recent issues of the journal to evaluate whether your paper would fit in with the journal’s current content and style.
Seek advice from colleagues and mentors: Ask for recommendations and suggestions from your colleagues and mentors in your field, especially those who have experience publishing in the same or similar journals.
Be prepared to make changes : Be prepared to revise your paper according to the requirements and guidelines of the chosen journal. It is also important to be open to feedback from the editor and reviewers.

List of Journals for Research Paper Publications

There are thousands of academic journals covering various fields of research. Here are some of the most popular ones, categorized by field:

General/Multidisciplinary

Nature: https://www.nature.com/
Science: https://www.sciencemag.org/
PLOS ONE: https://journals.plos.org/plosone/
Proceedings of the National Academy of Sciences (PNAS): https://www.pnas.org/
The Lancet: https://www.thelancet.com/
JAMA (Journal of the American Medical Association): https://jamanetwork.com/journals/jama

Social Sciences/Humanities

Journal of Personality and Social Psychology: https://www.apa.org/pubs/journals/psp
Journal of Consumer Research: https://www.journals.uchicago.edu/journals/jcr
Journal of Educational Psychology: https://www.apa.org/pubs/journals/edu
Journal of Applied Psychology: https://www.apa.org/pubs/journals/apl
Journal of Communication: https://academic.oup.com/joc
American Journal of Political Science: https://ajps.org/
Journal of International Business Studies: https://www.jibs.net/
Journal of Marketing Research: https://www.ama.org/journal-of-marketing-research/

Natural Sciences

Journal of Biological Chemistry: https://www.jbc.org/
Cell: https://www.cell.com/
Science Advances: https://advances.sciencemag.org/
Chemical Reviews: https://pubs.acs.org/journal/chreay
Angewandte Chemie: https://onlinelibrary.wiley.com/journal/15213765
Physical Review Letters: https://journals.aps.org/prl/
Journal of Geophysical Research: https://agupubs.onlinelibrary.wiley.com/journal/2156531X
Journal of High Energy Physics: https://link.springer.com/journal/13130

Engineering/Technology

IEEE Transactions on Neural Networks and Learning Systems: https://ieeexplore.ieee.org/xpl/RecentIssue.jsp?punumber=5962385
IEEE Transactions on Power Systems: https://ieeexplore.ieee.org/xpl/RecentIssue.jsp?punumber=59
IEEE Transactions on Medical Imaging: https://ieeexplore.ieee.org/xpl/RecentIssue.jsp?punumber=42
IEEE Transactions on Control Systems Technology: https://ieeexplore.ieee.org/xpl/RecentIssue.jsp?punumber=87
Journal of Engineering Mechanics: https://ascelibrary.org/journal/jenmdt
Journal of Materials Science: https://www.springer.com/journal/10853
Journal of Chemical Engineering of Japan: https://www.jstage.jst.go.jp/browse/jcej
Journal of Mechanical Design: https://asmedigitalcollection.asme.org/mechanicaldesign

Medical/Health Sciences

New England Journal of Medicine: https://www.nejm.org/
The BMJ (formerly British Medical Journal): https://www.bmj.com/
Journal of the American Medical Association (JAMA): https://jamanetwork.com/journals/jama
Annals of Internal Medicine: https://www.acpjournals.org/journal/aim
American Journal of Epidemiology: https://academic.oup.com/aje
Journal of Clinical Oncology: https://ascopubs.org/journal/jco
Journal of Infectious Diseases: https://academic.oup.com/jid

List of Conferences for Research Paper Publications

There are many conferences that accept research papers for publication. The specific conferences you should consider will depend on your field of research. Here are some suggestions for conferences in a few different fields:

Computer Science and Information Technology:

IEEE International Conference on Computer Communications (INFOCOM): https://www.ieee-infocom.org/
ACM SIGCOMM Conference on Data Communication: https://conferences.sigcomm.org/sigcomm/
IEEE Symposium on Security and Privacy (SP): https://www.ieee-security.org/TC/SP/
ACM Conference on Computer and Communications Security (CCS): https://www.sigsac.org/ccs/
ACM Conference on Human-Computer Interaction (CHI): https://chi2022.acm.org/

Engineering:

IEEE International Conference on Robotics and Automation (ICRA): https://www.ieee-icra.org/
International Conference on Mechanical and Aerospace Engineering (ICMAE): http://www.icmae.org/
International Conference on Civil and Environmental Engineering (ICCEE): http://www.iccee.org/
International Conference on Materials Science and Engineering (ICMSE): http://www.icmse.org/
International Conference on Energy and Power Engineering (ICEPE): http://www.icepe.org/

Natural Sciences:

American Chemical Society National Meeting & Exposition: https://www.acs.org/content/acs/en/meetings/national-meeting.html
American Physical Society March Meeting: https://www.aps.org/meetings/march/
International Conference on Environmental Science and Technology (ICEST): http://www.icest.org/
International Conference on Natural Science and Environment (ICNSE): http://www.icnse.org/
International Conference on Life Science and Biological Engineering (LSBE): http://www.lsbe.org/

Social Sciences:

Annual Meeting of the American Sociological Association (ASA): https://www.asanet.org/annual-meeting-2022
International Conference on Social Science and Humanities (ICSSH): http://www.icssh.org/
International Conference on Psychology and Behavioral Sciences (ICPBS): http://www.icpbs.org/
International Conference on Education and Social Science (ICESS): http://www.icess.org/
International Conference on Management and Information Science (ICMIS): http://www.icmis.org/

How to Publish a Research Paper in Journal

Publishing a research paper in a journal is a crucial step in disseminating scientific knowledge and contributing to the field. Here are the general steps to follow:

Choose a research topic : Select a topic of your interest and identify a research question or problem that you want to investigate. Conduct a literature review to identify the gaps in the existing knowledge that your research will address.
Conduct research : Develop a research plan and methodology to collect data and conduct experiments. Collect and analyze data to draw conclusions that address the research question.
Write a paper: Organize your findings into a well-structured paper with clear and concise language. Your paper should include an introduction, literature review, methodology, results, discussion, and conclusion. Use academic language and provide references for your sources.
Choose a journal: Choose a journal that is relevant to your research topic and audience. Consider factors such as impact factor, acceptance rate, and the reputation of the journal.
Follow journal guidelines : Review the submission guidelines and formatting requirements of the journal. Follow the guidelines carefully to ensure that your paper meets the journal’s requirements.
Submit your paper : Submit your paper to the journal through the online submission system or by email. Include a cover letter that briefly explains the significance of your research and why it is suitable for the journal.
Wait for reviews: Your paper will be reviewed by experts in the field. Be prepared to address their comments and make revisions to your paper.
Revise and resubmit: Make revisions to your paper based on the reviewers’ comments and resubmit it to the journal. If your paper is accepted, congratulations! If not, consider revising and submitting it to another journal.
Address reviewer comments : Reviewers may provide comments and suggestions for revisions to your paper. Address these comments carefully and thoughtfully to improve the quality of your paper.
Submit the final version: Once your revisions are complete, submit the final version of your paper to the journal. Be sure to follow any additional formatting guidelines and requirements provided by the journal.
Publication : If your paper is accepted, it will be published in the journal. Some journals provide online publication while others may publish a print version. Be sure to cite your published paper in future research and communicate your findings to the scientific community.

How to Publish a Research Paper for Students

Here are some steps you can follow to publish a research paper as an Under Graduate or a High School Student:

Select a topic: Choose a topic that is relevant and interesting to you, and that you have a good understanding of.
Conduct research : Gather information and data on your chosen topic through research, experiments, surveys, or other means.
Write the paper : Start with an outline, then write the introduction, methods, results, discussion, and conclusion sections of the paper. Be sure to follow any guidelines provided by your instructor or the journal you plan to submit to.
Edit and revise: Review your paper for errors in spelling, grammar, and punctuation. Ask a peer or mentor to review your paper and provide feedback for improvement.
Choose a journal : Look for journals that publish papers in your field of study and that are appropriate for your level of research. Some popular journals for students include PLOS ONE, Nature, and Science.
Submit the paper: Follow the submission guidelines for the journal you choose, which typically include a cover letter, abstract, and formatting requirements. Be prepared to wait several weeks to months for a response.
Address feedback : If your paper is accepted with revisions, address the feedback from the reviewers and resubmit your paper. If your paper is rejected, review the feedback and consider revising and resubmitting to a different journal.

How to Publish a Research Paper for Free

Publishing a research paper for free can be challenging, but it is possible. Here are some steps you can take to publish your research paper for free:

Choose a suitable open-access journal: Look for open-access journals that are relevant to your research area. Open-access journals allow readers to access your paper without charge, so your work will be more widely available.
Check the journal’s reputation : Before submitting your paper, ensure that the journal is reputable by checking its impact factor, publication history, and editorial board.
Follow the submission guidelines : Every journal has specific guidelines for submitting papers. Make sure to follow these guidelines carefully to increase the chances of acceptance.
Submit your paper : Once you have completed your research paper, submit it to the journal following their submission guidelines.
Wait for the review process: Your paper will undergo a peer-review process, where experts in your field will evaluate your work. Be patient during this process, as it can take several weeks or even months.
Revise your paper : If your paper is rejected, don’t be discouraged. Revise your paper based on the feedback you receive from the reviewers and submit it to another open-access journal.
Promote your research: Once your paper is published, promote it on social media and other online platforms. This will increase the visibility of your work and help it reach a wider audience.

Journals and Conferences for Free Research Paper publications

Here are the websites of the open-access journals and conferences mentioned:

Open-Access Journals:

PLOS ONE – https://journals.plos.org/plosone/
BMC Research Notes – https://bmcresnotes.biomedcentral.com/
Frontiers in… – https://www.frontiersin.org/
Journal of Open Research Software – https://openresearchsoftware.metajnl.com/
PeerJ – https://peerj.com/

Conferences:

IEEE Global Communications Conference (GLOBECOM) – https://globecom2022.ieee-globecom.org/
IEEE International Conference on Computer Communications (INFOCOM) – https://infocom2022.ieee-infocom.org/
IEEE International Conference on Data Mining (ICDM) – https://www.ieee-icdm.org/
ACM SIGCOMM Conference on Data Communication (SIGCOMM) – https://conferences.sigcomm.org/sigcomm/
ACM Conference on Computer and Communications Security (CCS) – https://www.sigsac.org/ccs/CCS2022/

Importance of Research Paper Publication

Research paper publication is important for several reasons, both for individual researchers and for the scientific community as a whole. Here are some reasons why:

Advancing scientific knowledge : Research papers provide a platform for researchers to present their findings and contribute to the body of knowledge in their field. These papers often contain novel ideas, experimental data, and analyses that can help to advance scientific understanding.
Building a research career : Publishing research papers is an essential component of building a successful research career. Researchers are often evaluated based on the number and quality of their publications, and having a strong publication record can increase one’s chances of securing funding, tenure, or a promotion.
Peer review and quality control: Publication in a peer-reviewed journal means that the research has been scrutinized by other experts in the field. This peer review process helps to ensure the quality and validity of the research findings.
Recognition and visibility : Publishing a research paper can bring recognition and visibility to the researchers and their work. It can lead to invitations to speak at conferences, collaborations with other researchers, and media coverage.
Impact on society : Research papers can have a significant impact on society by informing policy decisions, guiding clinical practice, and advancing technological innovation.

Advantages of Research Paper Publication

There are several advantages to publishing a research paper, including:

Recognition: Publishing a research paper allows researchers to gain recognition for their work, both within their field and in the academic community as a whole. This can lead to new collaborations, invitations to conferences, and other opportunities to share their research with a wider audience.
Career advancement : A strong publication record can be an important factor in career advancement, particularly in academia. Publishing research papers can help researchers secure funding, grants, and promotions.
Dissemination of knowledge : Research papers are an important way to share new findings and ideas with the broader scientific community. By publishing their research, scientists can contribute to the collective body of knowledge in their field and help advance scientific understanding.
Feedback and peer review : Publishing a research paper allows other experts in the field to provide feedback on the research, which can help improve the quality of the work and identify potential flaws or limitations. Peer review also helps ensure that research is accurate and reliable.
Citation and impact : Published research papers can be cited by other researchers, which can help increase the impact and visibility of the research. High citation rates can also help establish a researcher’s reputation and credibility within their field.

About the author

Muhammad Hassan

Researcher, Academic Writer, Web developer

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Research Papers

How to Write and Publish Your Research in a Journal

Last Updated: February 26, 2024 Fact Checked

Choosing a Journal

Writing the research paper, editing & revising your paper, submitting your paper, navigating the peer review process, research paper help.

This article was co-authored by Matthew Snipp, PhD and by wikiHow staff writer, Cheyenne Main . C. Matthew Snipp is the Burnet C. and Mildred Finley Wohlford Professor of Humanities and Sciences in the Department of Sociology at Stanford University. He is also the Director for the Institute for Research in the Social Science’s Secure Data Center. He has been a Research Fellow at the U.S. Bureau of the Census and a Fellow at the Center for Advanced Study in the Behavioral Sciences. He has published 3 books and over 70 articles and book chapters on demography, economic development, poverty and unemployment. He is also currently serving on the National Institute of Child Health and Development’s Population Science Subcommittee. He holds a Ph.D. in Sociology from the University of Wisconsin—Madison. There are 13 references cited in this article, which can be found at the bottom of the page. This article has been fact-checked, ensuring the accuracy of any cited facts and confirming the authority of its sources. This article has been viewed 697,786 times.

Publishing a research paper in a peer-reviewed journal allows you to network with other scholars, get your name and work into circulation, and further refine your ideas and research. Before submitting your paper, make sure it reflects all the work you’ve done and have several people read over it and make comments. Keep reading to learn how you can choose a journal, prepare your work for publication, submit it, and revise it after you get a response back.

Things You Should Know

Create a list of journals you’d like to publish your work in and choose one that best aligns with your topic and your desired audience.
Prepare your manuscript using the journal’s requirements and ask at least 2 professors or supervisors to review your paper.
Write a cover letter that “sells” your manuscript, says how your research adds to your field and explains why you chose the specific journal you’re submitting to.

Step 1 Create a list of journals you’d like to publish your work in.

Ask your professors or supervisors for well-respected journals that they’ve had good experiences publishing with and that they read regularly.
Many journals also only accept specific formats, so by choosing a journal before you start, you can write your article to their specifications and increase your chances of being accepted.
If you’ve already written a paper you’d like to publish, consider whether your research directly relates to a hot topic or area of research in the journals you’re looking into.

Step 2 Look at each journal’s audience, exposure, policies, and procedures.

Review the journal’s peer review policies and submission process to see if you’re comfortable creating or adjusting your work according to their standards.
Open-access journals can increase your readership because anyone can access them.

Step 1 Craft an effective introduction with a thesis statement.

Scientific research papers: Instead of a “thesis,” you might write a “research objective” instead. This is where you state the purpose of your research.
“This paper explores how George Washington’s experiences as a young officer may have shaped his views during difficult circumstances as a commanding officer.”
“This paper contends that George Washington’s experiences as a young officer on the 1750s Pennsylvania frontier directly impacted his relationship with his Continental Army troops during the harsh winter at Valley Forge.”

Step 2 Write the literature review and the body of your paper.

Scientific research papers: Include a “materials and methods” section with the step-by-step process you followed and the materials you used. [5] X Research source
Read other research papers in your field to see how they’re written. Their format, writing style, subject matter, and vocabulary can help guide your own paper. [6] X Research source

Step 3 Write your conclusion that ties back to your thesis or research objective.

If you’re writing about George Washington’s experiences as a young officer, you might emphasize how this research changes our perspective of the first president of the U.S.
Link this section to your thesis or research objective.
If you’re writing a paper about ADHD, you might discuss other applications for your research.

Step 4 Write an abstract that describes what your paper is about.

Scientific research papers: You might include your research and/or analytical methods, your main findings or results, and the significance or implications of your research.
Try to get as many people as you can to read over your abstract and provide feedback before you submit your paper to a journal.

Step 1 Prepare your manuscript according to the journal’s requirements.

They might also provide templates to help you structure your manuscript according to their specific guidelines. [11] X Research source

Step 2 Ask 2 colleagues to review your paper and revise it with their notes.

Not all journal reviewers will be experts on your specific topic, so a non-expert “outsider’s perspective” can be valuable.

Step 1 Check your sources for plagiarism and identify 5 to 6 keywords.

If you have a paper on the purification of wastewater with fungi, you might use both the words “fungi” and “mushrooms.”
Use software like iThenticate, Turnitin, or PlagScan to check for similarities between the submitted article and published material available online. [15] X Research source

Step 2 Write a cover letter explaining why you chose their journal.

Header: Address the editor who will be reviewing your manuscript by their name, include the date of submission, and the journal you are submitting to.
First paragraph: Include the title of your manuscript, the type of paper it is (like review, research, or case study), and the research question you wanted to answer and why.
Second paragraph: Explain what was done in your research, your main findings, and why they are significant to your field.
Third paragraph: Explain why the journal’s readers would be interested in your work and why your results are important to your field.
Conclusion: State the author(s) and any journal requirements that your work complies with (like ethical standards”).
“We confirm that this manuscript has not been published elsewhere and is not under consideration by another journal.”
“All authors have approved the manuscript and agree with its submission to [insert the name of the target journal].”

Step 3 Submit your article according to the journal’s submission guidelines.

Submit your article to only one journal at a time.
When submitting online, use your university email account. This connects you with a scholarly institution, which can add credibility to your work.

Step 1 Try not to panic when you get the journal’s initial response.

Accept: Only minor adjustments are needed, based on the provided feedback by the reviewers. A first submission will rarely be accepted without any changes needed.
Revise and Resubmit: Changes are needed before publication can be considered, but the journal is still very interested in your work.
Reject and Resubmit: Extensive revisions are needed. Your work may not be acceptable for this journal, but they might also accept it if significant changes are made.
Reject: The paper isn’t and won’t be suitable for this publication, but that doesn’t mean it might not work for another journal.

Step 2 Revise your paper based on the reviewers’ feedback.

Try organizing the reviewer comments by how easy it is to address them. That way, you can break your revisions down into more manageable parts.
If you disagree with a comment made by a reviewer, try to provide an evidence-based explanation when you resubmit your paper.

Step 3 Resubmit to the same journal or choose another from your list.

If you’re resubmitting your paper to the same journal, include a point-by-point response paper that talks about how you addressed all of the reviewers’ comments in your revision. [22] X Research source
If you’re not sure which journal to submit to next, you might be able to ask the journal editor which publications they recommend.

procedure for publishing a research paper

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About This Article

To publish a research paper, ask a colleague or professor to review your paper and give you feedback. Once you've revised your work, familiarize yourself with different academic journals so that you can choose the publication that best suits your paper. Make sure to look at the "Author's Guide" so you can format your paper according to the guidelines for that publication. Then, submit your paper and don't get discouraged if it is not accepted right away. You may need to revise your paper and try again. To learn about the different responses you might get from journals, see our reviewer's explanation below. Did this summary help you? Yes No

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Understanding the Publishing Process

What’s happening with my paper? The publication process explained

The path to publication can be unsettling when you’re unsure what’s happening with your paper. Learn about staple journal workflows to see the detailed steps required for ensuring a rigorous and ethical publication.

Your team has prepared the paper, written a cover letter and completed the submission form. From here, it can sometimes feel like a waiting game while the journal has your paper. It can be unclear exactly who is currently handling your paper as most individuals are only involved in a few steps of the overall process. Journals are responsible for overseeing the peer review, publication and archival process: editors, reviewers, technical editors, production staff and other internal staff all have their roles in ensuring submissions meet rigorous scientific and ethical reporting standards.

Read on for an inside look at how a conventional peer-reviewed journal helps authors transform their initial submission to a certified publication.

Note that the description below is based on the process at PLOS journals. It is likely that at other journals, various roles (e.g. technical editor) may in fact also be played by the editor, and some journals may not have journal staff at all, with all roles played by volunteer academics. As such, please consider the processes and waypoints, rather than who performs them, as the key information.

Internal Checks on New Submissions

Estimated time: 10 days.

When a journal first receives your submission, there are typically two separate checks to confirm that the paper is appropriate and ready for peer review:

Technical check. Performed by a technical editor to ensure that the submission has been properly completed and is ready for further assessment. Blurry figures, missing ethical statements, and incomplete author affiliations are common issues that are addressed at this initial stage. Typically, there are three technical checks: upon initial submission, alongside the first decision letter, and upon acceptance.
Editorial screening . Once a paper passes the first check, an editor with subject expertise assesses the paper and determines whether it is within the journal’s scope and if it could potentially meet the required publication criteria. While there may be requests for further information and minor edits from the author as needed, the paper will either be desk rejected by the editor or allowed to proceed to peer review.

Both editors at this point will additionally make notes for items to be followed-up on at later stages. The publication process involves finding a careful balance for when each check occurs. Early checks need to be thorough so that editors with relevant expertise can focus on the scientific content and more advanced reporting standards, but no one wants to be asked to reformat references only to have their paper desk rejected a few days later.

Peer Review

Estimated time: 1 month.

Depending on the journal’s editorial structure, the editor who performed the initial assessment may also oversee peer review or another editor with more specific expertise may be assigned. Regardless of the journal’s specific process, the various roles and responsibilities during peer review include:

When you have questions or are unsure who your manuscripts is currently with, reach out to the journal staff for help (eg. [email protected]). They will be your lifeline, connecting you to all the other contributors working to assess the manuscript.

Whether an editor needs a reminder that all reviews are complete or a reviewer has asked for an extension, the journal acts as a central hub of communication for those involved with the publication process. As editors and reviewers are used to hearing from journal staff about their duties, any messages you send to the journal can be forwarded to them with proper context and instructions on how to proceed appropriately. Additionally, journal staff will be able to inform you of any delays, such as reviewer availability during summer and holiday periods.

Revision Decision

Estimated time: 1 day.

Editors evaluate peer reviewer feedback and their own expert assessment of the manuscript to reach a decision. After your editor submits a decision on your manuscript, the journal may review it before formally processing the decision and sending it on to you.

A technical editor may scan the manuscript and the review comments to ensure that journal standards have been followed. At this stage, the technical editor will also add requests to ensure the paper, if published, will adhere to journal requirements for data sharing, copyright, ethical reporting and the like.

Performing the second technical check at this stage and adding the journal requirements to the decision letter ultimately saves time by allowing authors to resolve the journal’s queries while making revisions based on comments from the reviewers.

Revised Submission Received

Estimated time: 3 days.

Upon receiving your revised submission, a technical editor will assess the revisions to confirm that the requests from the journal have been properly addressed. Before the paper is returned to the editor for their consideration, the journal needs to be confident that the paper won’t have any issues related to the metadata and reporting standards that could prevent publication. The editor may contact you to resolve any serious issues, though minor items can wait until the paper is accepted.

Subsequent Peer Review

Estimated time: 2 weeks, highly variable.

When your resubmitted paper has passed the required checks, it’ll be assigned back to the same editor who handled it during the first round of peer review. At this point, your paper has gone through two sets of journal checks and one round of peer review. If all has gone well so far, the paper should feel quite solid both in terms of scientific content and proper reporting standards.

When the editor receives your revised paper, they are asked to check if all reviewer comments have been adequately addressed and if the paper now adheres to the journal’s publication criteria. Depending on the situation, some editors may feel confident making this decision based on their own expertise while others may re-invite the previous reviewers for their opinions.

Individual responsibilities are the same as the initial round of peer review, but it is generally expected that later stages of peer review proceed quicker unless new concerns have been introduced as part of the revision.

Preliminary Acceptance

Estimated time: 1 week.

Your editor is satisfied with the scientific quality of your work and has chosen to accept it in principle. Before it can proceed to production and typesetting, the journal office will perform it’s third and final technical check, requesting any formatting changes or additional details that may be required.

When fulfilling these final journal requests, double check the final files to confirm all information is correct. If you need to make changes beyond those specifically required in the decision letter, inform the journal and explain why you made the unrequested changes. Any change that could affect the scientific meaning of the work will need to be approved by the handling editor. While including your rationale for the changes will help avoid delays, if there are extensive changes made at this point the paper may need to go through another round of formal review.

Formal Acceptance and Publication

Estimated time: 2 weeks.

After a technical editor has confirmed that all requests from the provisional acceptance letter have been addressed, you will receive your formal acceptance letter. This letter indicates that your paper is being passed from the Editorial department to the production department—that all information has been editorially approved. The scientific content has been approved through peer review, and the journal’s publication requirements have been met.

Congratulations to you and your co-authors! Your article will be available as soon as the journal transforms the submission into a typeset, consistently structured scientific manuscript, ready to be read and cited by your peers.

The contents of the Peer Review Center are also available as a live, interactive training session, complete with slides, talking points, and activities. …

The contents of the Writing Center are also available as a live, interactive training session, complete with slides, talking points, and activities. …

There’s a lot to consider when deciding where to submit your work. Learn how to choose a journal that will help your study reach its audience, while reflecting your values as a researcher…

Home → Get Published → How to Publish a Research Paper: A Step-by-Step Guide

How to Publish a Research Paper: A Step-by-Step Guide

Jordan Kruszynski

January 4, 2024

You’re in academia.

You’re going steady.

Your research is going well and you begin to wonder: ‘ How exactly do I get a research paper published?’

If this is the question on your lips, then this step-by-step guide is the one for you. We’ll be walking you through the whole process of how to publish a research paper.

Publishing a research paper is a significant milestone for researchers and academics, as it allows you to share your findings, contribute to your field of study, and start to gain serious recognition within the wider academic community. So, want to know how to publish a research paper? By following our guide, you’ll get a firm grasp of the steps involved in this process, giving you the best chance of successfully navigating the publishing process and getting your work out there.

Understanding the Publishing Process

To begin, it’s crucial to understand that getting a research paper published is a multi-step process. From beginning to end, it could take as little as 2 months before you see your paper nestled in the pages of your chosen journal. On the other hand, it could take as long as a year .

Below, we set out the steps before going into more detail on each one. Getting a feel for these steps will help you to visualise what lies ahead, and prepare yourself for each of them in turn. It’s important to remember that you won’t actually have control over every step – in fact, some of them will be decided by people you’ll probably never meet. However, knowing which parts of the process are yours to decide will allow you to adjust your approach and attitude accordingly.

Each of the following stages will play a vital role in the eventual publication of your paper:

Preparing Your Research Paper
Finding the Right Journal
Crafting a Strong Manuscript
Navigating the Peer-Review Process
Submitting Your Paper
Dealing with Rejections and Revising Your Paper

Step 1: Preparing Your Research Paper

It all starts here. The quality and content of your research paper is of fundamental importance if you want to get it published. This step will be different for every researcher depending on the nature of your research, but if you haven’t yet settled on a topic, then consider the following advice:

Choose an interesting and relevant topic that aligns with current trends in your field. If your research touches on the passions and concerns of your academic peers or wider society, it may be more likely to capture attention and get published successfully.
Conduct a comprehensive literature review (link to lit. review article once it’s published) to identify the state of existing research and any knowledge gaps within it. Aiming to fill a clear gap in the knowledge of your field is a great way to increase the practicality of your research and improve its chances of getting published.
Structure your paper in a clear and organised manner, including all the necessary sections such as title, abstract, introduction (link to the ‘how to write a research paper intro’ article once it’s published) , methodology, results, discussion, and conclusion.
Adhere to the formatting guidelines provided by your target journal to ensure that your paper is accepted as viable for publishing. More on this in the next section…

Step 2: Finding the Right Journal

Understanding how to publish a research paper involves selecting the appropriate journal for your work. This step is critical for successful publication, and you should take several factors into account when deciding which journal to apply for:

Conduct thorough research to identify journals that specialise in your field of study and have published similar research. Naturally, if you submit a piece of research in molecular genetics to a journal that specialises in geology, you won’t be likely to get very far.
Consider factors such as the journal’s scope, impact factor, and target audience. Today there is a wide array of journals to choose from, including traditional and respected print journals, as well as numerous online, open-access endeavours. Some, like Nature , even straddle both worlds.
Review the submission guidelines provided by the journal and ensure your paper meets all the formatting requirements and word limits. This step is key. Nature, for example, offers a highly informative series of pages that tells you everything you need to know in order to satisfy their formatting guidelines (plus more on the whole submission process).
Note that these guidelines can differ dramatically from journal to journal, and details really do matter. You might submit an outstanding piece of research, but if it includes, for example, images in the wrong size or format, this could mean a lengthy delay to getting it published. If you get everything right first time, you’ll save yourself a lot of time and trouble, as well as strengthen your publishing chances in the first place.

Step 3: Crafting a Strong Manuscript

Crafting a strong manuscript is crucial to impress journal editors and reviewers. Look at your paper as a complete package, and ensure that all the sections tie together to deliver your findings with clarity and precision.

Begin by creating a clear and concise title that accurately reflects the content of your paper.
Compose an informative abstract that summarises the purpose, methodology, results, and significance of your study.
Craft an engaging introduction (link to the research paper introduction article) that draws your reader in.
Develop a well-structured methodology section, presenting your results effectively using tables and figures.
Write a compelling discussion and conclusion that emphasise the significance of your findings.

Step 4: Navigating the Peer-Review Process

Once you submit your research paper to a journal, it undergoes a rigorous peer-review process to ensure its quality and validity. In peer-review, experts in your field assess your research and provide feedback and suggestions for improvement, ultimately determining whether your paper is eligible for publishing or not. You are likely to encounter several models of peer-review, based on which party – author, reviewer, or both – remains anonymous throughout the process.

When your paper undergoes the peer-review process, be prepared for constructive criticism and address the comments you receive from your reviewer thoughtfully, providing clear and concise responses to their concerns or suggestions. These could make all the difference when it comes to making your next submission.

The peer-review process can seem like a closed book at times. Check out our discussion of the issue with philosopher and academic Amna Whiston in The Research Beat podcast!

Step 5: Submitting Your Paper

As we’ve already pointed out, one of the key elements in how to publish a research paper is ensuring that you meticulously follow the journal’s submission guidelines. Strive to comply with all formatting requirements, including citation styles, font, margins, and reference structure.

Before the final submission, thoroughly proofread your paper for errors, including grammar, spelling, and any inconsistencies in your data or analysis. At this stage, consider seeking feedback from colleagues or mentors to further improve the quality of your paper.

Step 6: Dealing with Rejections and Revising Your Paper

Rejection is a common part of the publishing process, but it shouldn’t discourage you. Analyse reviewer comments objectively and focus on the constructive feedback provided. Make necessary revisions and improvements to your paper to address the concerns raised by reviewers. If needed, consider submitting your paper to a different journal that is a better fit for your research.

For more tips on how to publish your paper out there, check out this thread by Dr. Asad Naveed ( @dr_asadnaveed ) – and if you need a refresher on the basics of how to publish under the Open Access model, watch this 5-minute video from Audemic Academy !

Final Thoughts

Successfully understanding how to publish a research paper requires dedication, attention to detail, and a systematic approach. By following the advice in our guide, you can increase your chances of navigating the publishing process effectively and achieving your goal of publication.

Remember, the journey may involve revisions, peer feedback, and potential rejections, but each step is an opportunity for growth and improvement. Stay persistent, maintain a positive mindset, and continue to refine your research paper until it reaches the standards of your target journal. Your contribution to your wider discipline through published research will not only advance your career, but also add to the growing body of collective knowledge in your field. Embrace the challenges and rewards that come with the publication process, and may your research paper make a significant impact in your area of study!

Looking for inspiration for your next big paper? Head to Audemic , where you can organise and listen to all the best and latest research in your field!

Keep striving, researchers! ✨

Behind the Scenes: What Does a Research Assistant Do?

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How to Write and Publish a Research Paper in 7 Steps

What comes next after you're done with your research? Publishing the results in a journal of course! We tell you how to present your work in the best way possible.

This post is part of a series, which serves to provide hands-on information and resources for authors and editors.

Things have gotten busy in scholarly publishing: These days, a new article gets published in the 50,000 most important peer-reviewed journals every few seconds, while each one takes on average 40 minutes to read. Hundreds of thousands of papers reach the desks of editors and reviewers worldwide each year and 50% of all submissions end up rejected at some stage.

In a nutshell: there is a lot of competition, and the people who decide upon the fate of your manuscript are short on time and overworked. But there are ways to make their lives a little easier and improve your own chances of getting your work published!

Well, it may seem obvious, but before submitting an academic paper, always make sure that it is an excellent reflection of the research you have done and that you present it in the most professional way possible. Incomplete or poorly presented manuscripts can create a great deal of frustration and annoyance for editors who probably won’t even bother wasting the time of the reviewers!

This post will discuss 7 steps to the successful publication of your research paper:

Check whether your research is publication-ready
Choose an article type
Choose a journal
Construct your paper
Decide the order of authors
Check and double-check
Submit your paper

1. Check Whether Your Research Is Publication-Ready

Should you publish your research at all?

If your work holds academic value – of course – a well-written scholarly article could open doors to your research community. However, if you are not yet sure, whether your research is ready for publication, here are some key questions to ask yourself depending on your field of expertise:

Have you done or found something new and interesting? Something unique?
Is the work directly related to a current hot topic?
Have you checked the latest results or research in the field?
Have you provided solutions to any difficult problems?
Have the findings been verified?
Have the appropriate controls been performed if required?
Are your findings comprehensive?

If the answers to all relevant questions are “yes”, you need to prepare a good, strong manuscript. Remember, a research paper is only useful if it is clearly understood, reproducible and if it is read and used .

2. Choose An Article Type

The first step is to determine which type of paper is most appropriate for your work and what you want to achieve. The following list contains the most important, usually peer-reviewed article types in the natural sciences:

Full original research papers disseminate completed research findings. On average this type of paper is 8-10 pages long, contains five figures, and 25-30 references. Full original research papers are an important part of the process when developing your career.

Review papers present a critical synthesis of a specific research topic. These papers are usually much longer than original papers and will contain numerous references. More often than not, they will be commissioned by journal editors. Reviews present an excellent way to solidify your research career.

Letters, Rapid or Short Communications are often published for the quick and early communication of significant and original advances. They are much shorter than full articles and usually limited in length by the journal. Journals specifically dedicated to short communications or letters are also published in some fields. In these the authors can present short preliminary findings before developing a full-length paper.

3. Choose a Journal

Are you looking for the right place to publish your paper? Find out here whether a De Gruyter journal might be the right fit.

Submit to journals that you already read, that you have a good feel for. If you do so, you will have a better appreciation of both its culture and the requirements of the editors and reviewers.

Other factors to consider are:

The specific subject area
The aims and scope of the journal
The type of manuscript you have written
The significance of your work
The reputation of the journal
The reputation of the editors within the community
The editorial/review and production speeds of the journal
The community served by the journal
The coverage and distribution
The accessibility ( open access vs. closed access)

4. Construct Your Paper

Each element of a paper has its purpose, so you should make these sections easy to index and search.

Don’t forget that requirements can differ highly per publication, so always make sure to apply a journal’s specific instructions – or guide – for authors to your manuscript, even to the first draft (text layout, paper citation, nomenclature, figures and table, etc.) It will save you time, and the editor’s.

Also, even in these days of Internet-based publishing, space is still at a premium, so be as concise as possible. As a good journalist would say: “Never use three words when one will do!”

Let’s look at the typical structure of a full research paper, but bear in mind certain subject disciplines may have their own specific requirements so check the instructions for authors on the journal’s home page.

4.1 The Title

It’s important to use the title to tell the reader what your paper is all about! You want to attract their attention, a bit like a newspaper headline does. Be specific and to the point. Keep it informative and concise, and avoid jargon and abbreviations (unless they are universally recognized like DNA, for example).

4.2 The Abstract

This could be termed as the “advertisement” for your article. Make it interesting and easily understood without the reader having to read the whole article. Be accurate and specific, and keep it as brief and concise as possible. Some journals (particularly in the medical fields) will ask you to structure the abstract in distinct, labeled sections, which makes it even more accessible.

A clear abstract will influence whether or not your work is considered and whether an editor should invest more time on it or send it for review.

4.3 Keywords

Keywords are used by abstracting and indexing services, such as PubMed and Web of Science. They are the labels of your manuscript, which make it “searchable” online by other researchers.

Include words or phrases (usually 4-8) that are closely related to your topic but not “too niche” for anyone to find them. Make sure to only use established abbreviations. Think about what scientific terms and its variations your potential readers are likely to use and search for. You can also do a test run of your selected keywords in one of the common academic search engines. Do similar articles to your own appear? Yes? Then that’s a good sign.

4.4 Introduction

This first part of the main text should introduce the problem, as well as any existing solutions you are aware of and the main limitations. Also, state what you hope to achieve with your research.

Do not confuse the introduction with the results, discussion or conclusion.

4.5 Methods

Every research article should include a detailed Methods section (also referred to as “Materials and Methods”) to provide the reader with enough information to be able to judge whether the study is valid and reproducible.

Include detailed information so that a knowledgeable reader can reproduce the experiment. However, use references and supplementary materials to indicate previously published procedures.

4.6 Results

In this section, you will present the essential or primary results of your study. To display them in a comprehensible way, you should use subheadings as well as illustrations such as figures, graphs, tables and photos, as appropriate.

4.7 Discussion

Here you should tell your readers what the results mean .

Do state how the results relate to the study’s aims and hypotheses and how the findings relate to those of other studies. Explain all possible interpretations of your findings and the study’s limitations.

Do not make “grand statements” that are not supported by the data. Also, do not introduce any new results or terms. Moreover, do not ignore work that conflicts or disagrees with your findings. Instead …

Be brave! Address conflicting study results and convince the reader you are the one who is correct.

4.8 Conclusion

Your conclusion isn’t just a summary of what you’ve already written. It should take your paper one step further and answer any unresolved questions.

Sum up what you have shown in your study and indicate possible applications and extensions. The main question your conclusion should answer is: What do my results mean for the research field and my community?

4.9 Acknowledgments and Ethical Statements

It is extremely important to acknowledge anyone who has helped you with your paper, including researchers who supplied materials or reagents (e.g. vectors or antibodies); and anyone who helped with the writing or English, or offered critical comments about the content.

Learn more about academic integrity in our blog post “Scholarly Publication Ethics: 4 Common Mistakes You Want To Avoid” .

Remember to state why people have been acknowledged and ask their permission . Ensure that you acknowledge sources of funding, including any grant or reference numbers.

Furthermore, if you have worked with animals or humans, you need to include information about the ethical approval of your study and, if applicable, whether informed consent was given. Also, state whether you have any competing interests regarding the study (e.g. because of financial or personal relationships.)

4.10 References

The end is in sight, but don’t relax just yet!

De facto, there are often more mistakes in the references than in any other part of the manuscript. It is also one of the most annoying and time-consuming problems for editors.

Remember to cite the main scientific publications on which your work is based. But do not inflate the manuscript with too many references. Avoid excessive – and especially unnecessary – self-citations. Also, avoid excessive citations of publications from the same institute or region.

5. Decide the Order of Authors

In the sciences, the most common way to order the names of the authors is by relative contribution.

Generally, the first author conducts and/or supervises the data analysis and the proper presentation and interpretation of the results. They put the paper together and usually submit the paper to the journal.

Co-authors make intellectual contributions to the data analysis and contribute to data interpretation. They review each paper draft. All of them must be able to present the paper and its results, as well as to defend the implications and discuss study limitations.

Do not leave out authors who should be included or add “gift authors”, i.e. authors who did not contribute significantly.

6. Check and Double-Check

As a final step before submission, ask colleagues to read your work and be constructively critical .

Make sure that the paper is appropriate for the journal – take a last look at their aims and scope. Check if all of the requirements in the instructions for authors are met.

Ensure that the cited literature is balanced. Are the aims, purpose and significance of the results clear?

Conduct a final check for language, either by a native English speaker or an editing service.

7. Submit Your Paper

When you and your co-authors have double-, triple-, quadruple-checked the manuscript: submit it via e-mail or online submission system. Along with your manuscript, submit a cover letter, which highlights the reasons why your paper would appeal to the journal and which ensures that you have received approval of all authors for submission.

It is up to the editors and the peer-reviewers now to provide you with their (ideally constructive and helpful) comments and feedback. Time to take a breather!

If the paper gets rejected, do not despair – it happens to literally everybody. If the journal suggests major or minor revisions, take the chance to provide a thorough response and make improvements as you see fit. If the paper gets accepted, congrats!

It’s now time to get writing and share your hard work – good luck!

If you are interested, check out this related blog post

[Title Image by Nick Morrison via Unsplash]

David Sleeman

David Sleeman worked as Senior Journals Manager in the field of Physical Sciences at De Gruyter.

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How to publish an article? – Step by step

If you plan to submit an article to one of our journals, or have any questions during the publication process, this helpdesk will guide you through manuscript submission, production and the services you can expect after your article’s publication.

1. Before you start

The following topics will be important during the early stages of writing your article.

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Preparation, publication.

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How To Publish Research Paper? Step-by-Step Procedure

Introduction

Publishing a research paper is a critical milestone for researchers, academics, and professionals. The process involves meticulous planning, data analysis, and clear communication of findings. However, the time-consuming nature of research often poses challenges for authors seeking to expedite the publication process. To address this and help you publish research paper easily, we’ll explore several key strategies that can significantly speed up the publication timeline without compromising the quality of your research.

How Do You Publish A Research Paper Immediately?

To publish your paper immediately, you must complete some preliminary steps. You must first figure out your technical area of interest. Ensure you have carried out enough studies on the basics of that topic. Then update yourself with the ongoing technological happenings in your chosen field. You can do this by reading a lot of technical papers, as there are a lot of journals and IEEE papers, or you can attend domestic and international conference to know the latest research and finding and know what fellow researchers are doing.

The next step is where to publish research paper ? You can publish the article in various reputable journals, but research them first. Research and identify reputed journals that align with your study’s subject matter. Look for journals with a high impact factor indexed in major academic databases.

Once you are done with the above steps, you are eligible to write a paper. Crafting a research paper around a relevant and novel topic can increase its chances of being accepted and cited by others. Conduct a thorough literature review to identify gaps in existing research and formulate a research question that addresses these gaps.

Where Can I Publish My Research Paper Easily?

Identifying the best place to publish paper easily involves consideration of many factors, which include:

Journal aim and scope
Publication of similar work
Journal rankings and measures of journal impact
Demonstration of good publishing practices

You can check conferencenext website, as it can help you identify trusted journals for your research. Moreover, you can check the simple checklist provided so you can assess the credentials of a journal or publisher.

Additionally, you can easily publish in the Open Access Journal as it allows you to share your work widely and bypass permission and paywall barriers so the public has greater access to your work. However, predatory publishers, many disguised as Open Access Journals, may solicit you for your research. If you encounter a potential predatory publisher, take the time to analyze the journal or publisher before submitting work to make sure they are not a predatory journal or publisher.

Step-by-Step Procedure to Publish Research Paper

(1) Writing and Structuring the Paper Writing an influential, compelling research paper is essential to get your research published. However, it can feel daunting to start if you are new to putting together academic or research papers. But if you have chosen the journal you want to publish in, you will get many examples published in that journal to base your article on.

Now, develop a well-structured outline for your research paper. Organize your key points, arguments, and evidence logically. A comprehensive summary will serve as a roadmap, making the writing process more efficient.

(2) Writing Concisely and Clearly Aim for concise and clear writing to present your research findings effectively. Avoid unnecessary jargon and ensure that your ideas are articulated in a manner that is easy for a broader audience to comprehend.

(3) Pay Attention to Formatting and Citations Adhere to the specific formatting guidelines of your chosen journal. Properly cite all sources to provide credit to previous research and avoid potential issues related to plagiarism.

(4) Preparing for Peer Review Conduct a meticulous self-review before you submit your paper for peer review in Scopus indexed journals . Check for any grammatical errors, inconsistencies, or incomplete sections. A well-polished article will make a positive impression on reviewers.

Also, you can ask your colleagues or mentors to review your research paper before submission. Constructive criticism can help identify any weak points and provide suggestions for improvement. The peer-review article ensures that the article’s methodology is excellent, the work can be replicated, and it fits the scope of the journal you are considering for publication.

(5) Navigating the Review Process It is common for research papers to undergo revisions after peer review. Be open to feedback and address reviewers’ comments and concerns promptly and thoroughly.

During the review process, maintain a professional and respectful attitude when communicating with reviewers. Address their comments and suggestions professionally and demonstrate your commitment to enhancing the paper’s quality.

(6) Finalizing and Publishing the Paper Once your paper is thoroughly revised and edited, it is time for publication. But ensure that your research paper complies with all the ethical guidelines. So, proofread the final version to eliminate any lingering errors. A polished and error-free manuscript enhances its chances of acceptance.

Also, remember to include the cover letter, as it highlights the relevance of your work to the journal and showcases your key findings. An effective cover letter can convince the editor to accept and review your manuscript immediately.

By following the tips outlined in this guide, you can significantly expedite publishing your research paper quickly without compromising its quality. Remember to choose the right journal, streamline your research process, write concisely, prepare for peer review diligently, and finalize your paper professionally. Embrace collaboration, seek feedback, and celebrate your accomplishment when your research paper is published successfully. With dedication and adherence to these practices, you can undoubtedly leave other websites behind and achieve top search rankings for your research paper.

Also Read: How to publish a research paper in India

So, if you are ready to embark on your research paper publication journey, start implementing these proven techniques today. However, if you need help publishing a research paper in international journals, Conference Next can help. We have various Scopus indexed journals and can help you publish your articles quickly and easily.

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9 Steps To Publish A Research Paper

Researchers and scholars undertake academic studies to advance knowledge in their respective fields of study. To this end, they also focus on getting their work published in high-impact and widely read journals. This helps them to highlight and disseminate their work, be known in their respective fields, and grow professionally in their careers.

However, the process of publishing a research paper can be challenging and time-consuming. It requires careful planning, attention to detail, and the ability to receive feedback constructively. In this blog, we outline nine steps to publish research papers successfully in high-impact journals and help researchers contribute to their fields of study.

9 Steps to Publish Research Papers Successfully

Publishing a well-written research paper can be confusing. To achieve a successful publication within a reasonable timeframe, researchers must grasp the intricacies of the publication process outlined below:

Finalize your research topic: A contemporary research topic, reflecting current challenges and trends in your respective field of study, is an aspect that you can seriously consider while finalizing your topic.
Choose the right journal and article type: It is crucial to identify early on the most appropriate journal for your research paper. This will save considerable time and effort and increase the likelihood of its acceptance. Discussing with peers and colleagues in the field who have authored and reviewed articles will undoubtedly be helpful. Review the aims, objectives, and scope of the journal and its area of specialization to assess if your research conforms to the necessary guidelines. Consider also the peer review process, the impact factor of the journal and the time taken to publish an article. Depending on the nature of your work, also decide on the type of article relevant to your work, which may be a completely original research paper, review paper or letter, rapid or short communication.
Write, format, and refine your paper for submission: Even before starting to write the paper , go through the author guidelines and formatting style followed by the journal. This will make the writing process easier. Structure the article according to the type of article you are writing. Going through the published articles in the target journal will also help you in the process. A standard structure for a research paper needs to have the title, abstract, keywords, introduction, methods, results, discussion, conclusion, acknowledgements, and references.
Prepare required documents like a cover letter and declaration of conflicts of interest: When you submit your manuscript, a cover letter is a must. It should highlight the central theme of your paper and the significance of your study. Further, clearly state that you comply with all basic requirements and declare any or no potential conflict of interest that could arise.
Check that your work is complete and submission-ready. Read your work several times to identify any gaps and ambiguities. Review your work for innovativeness, rigour, and contribution to topical issues in the field. Seek feedback from supervisors and peers.
Submit your manuscript to your chosen journal : Re-check the paper to ensure that there are no errors in grammar, wording, sentence construction, or formatting and that there is consistency in formatting. Professional proofreading is important in this regard. Check if there is a logical flow of arguments and that any images or graphs used are easy to understand and clear. Ensure that all co-authors have reviewed and approved the paper for submission.
Tackle post-submission revisions (including peer review comments): Nearly all papers submitted to journals undergo a peer review process, which ensures the quality of the papers published in the journal. The reviewers may provide comments and suggestions to strengthen your paper. Review the reviewer’s comments carefully and make sure to respond to each one. Aim to send your responses using the timeline given by the journal editors.
Revise and resubmit the manuscript (responding to peer review comments): It is essential to approach the comments as constructive criticism. Remember to be polite and respectful in your response. Make sure to provide a detailed response on how you have addressed each comment by the reviewers. If you do not agree with any comment, always respond professionally with care; avoid getting into a personal attack. Give a detailed explanation of your arguments. Resubmit the revised manuscript highlighting all the modifications carried out based on the comments by the reviewers. Along with the manuscript, provide a letter stating the author’s responses and that they have addressed the comments by the editor and the reviewers.
Get accepted for journal publication: Once the revisions are made to the satisfaction of the editor and reviewers, the paper is accepted for publication. If your paper is rejected, make the necessary revisions and send it to the journal of your second choice.

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How to Write and Publish a Research Paper for a Peer-Reviewed Journal

Affiliations.

1 Department of Maternal and Child Health, University of North Carolina Gillings School of Global Public Health, 135 Dauer Dr, 27599, Chapel Hill, NC, USA.
2 Department of Maternal and Child Health, University of North Carolina Gillings School of Global Public Health, 135 Dauer Dr, 27599, Chapel Hill, NC, USA. [email protected].
3 Department of Epidemiology, University of Michigan School of Public Health, 1415 Washington Heights, Ann Arbor, MI, 48109-2029, USA. [email protected].
PMID: 32356250
PMCID: PMC8520870
DOI: 10.1007/s13187-020-01751-z

Communicating research findings is an essential step in the research process. Often, peer-reviewed journals are the forum for such communication, yet many researchers are never taught how to write a publishable scientific paper. In this article, we explain the basic structure of a scientific paper and describe the information that should be included in each section. We also identify common pitfalls for each section and recommend strategies to avoid them. Further, we give advice about target journal selection and authorship. In the online resource 1, we provide an example of a high-quality scientific paper, with annotations identifying the elements we describe in this article.

Keywords: Manuscripts; Publishing; Scientific writing.

Communication
Publishing*

The Process of Publishing a Research paper in a Journal

The publication of a research paper in a journal is a long and painstaking process. It involves many stages that need to be completed at the author’s end before submission to a journal . After submission, there are further steps at the publisher’s end over which the author has no control. In order to get a successful publication in good time, it is important for an author to understand the various steps involved in the process.

It all starts with the draft manuscript. A properly edited research paper , with proper references along with a good title, a short but precise abstract, and a detailed cover letter is the first step.

Any research paper submission for publication in a journal goes through an editorial screening to start with. The authors must ensure their research paper matches the focus area and objectives of the selected journal so that it is not rejected at the first stage. The best way to go about it is to follow the journal ’s instructions with precision and consistency. Research paper s that clear editorial screening are then forwarded for peer review .

Peer review is often a time-consuming process. Two or more reviewers are usually chosen of which one might be picked from experts the authors suggested as potential reviewers in their initial submission. Those engaging in the peer-review process are professionals from their fields of expertise who have other engagements and hence they often take time to revert back. Reviewers recommend immediate acceptance without changes or immediate rejection without reconsideration, although reconsideration after minor/ major changes is the common response.

The final decision on any research paper is taken by the editor, who reverts back to the author with comments from the editorial team or peer review . The author has to respond to the editor with a revised manuscript along with a detailed letter that explains exactly what changes were made and a compelling academic or scientific reason why certain suggestions were not accommodated.

Depending on the gravity of changes involved, the editor may decide to take a call by themselves or re-share the research paper for the second round of peer review . These processes, even though they delay the publication process, only help improve the quality of the publication and hence are very important.

When the paper is finally accepted by the editor, it goes into production for final checking and reformatting to fit the journal ’s conventions and styles. The journal may revert to the author for a final proofread of the final manuscript they design for publication .

in case of a rejection, the journal will convey why the research paper was rejected. The author can take note and either rewrite the research paper to fit the journal or share it with some other journal for consideration.

Clarity over the publication process by a journal is important for authors, and they should prepare accordingly to ensure a smooth publication process.

How to write a literature review article for a journal.

Literature review articles are a critical form of publication. While all research articles require a literature review section, some articles are purely dedicated stand-alone literature reviews only, published as review articles or survey articles by journals. There exists a certain journal dedicated to such articles. Review articles are extremely popular with professionals, young students, and […]

What does peer review accomplish?

The scientific standard of a paper is guaranteed by peer review. An author’s manuscript is assessed by people having expertise in the same area of research. These experts are called peers. For any scholarly publication, a manuscript has to go through the peer review process of that particular journal. The Purpose of Peer Review Peer […]

Open access journals are vanishing from the web, Internet Archive stands ready to fill in the gaps

The advent of Open access journals was expected to revolutionize the academic journal publication sector. Various factors were driving the rise of open access journals, especially in the field of scientific studies. Some of the most common factors, such as time required to get published in conventional peer-reviewed journals or the high rate of rejections, […]

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How to Publish a Research Paper: A Step-by-Step Guide

How to Publish a Research Paper

Publishing a research paper or getting it published in an academic journal can be one of the most fulfilling accomplishments in your academic career. You’ve spent countless hours learning, researching, thinking and writing, and now you get to share your knowledge with others who share your interests and passion for research. This guide on how to publish a research paper will help you choose the best journal for publishing your work, what information to include in your manuscript and how to format it correctly and more!

Choose your topic

For many scientists, the goal of their research is publication. Every published paper not only contributes to the body of knowledge in a particular field, but also gives credit and recognition for individual accomplishment. Publishing can be an arduous process, however; take this step-by-step guide to help you get started.

Conduct your Literature Review

Find articles from reputable journals and use them to conduct your literature review. To start, you can conduct an academic search in Google Scholar , read the abstracts, and include these articles in your list of sources. Make sure that all the papers are on an appropriate scholarly level (peer reviewed, etc.) and published within 5 years of when you write your paper. Once you have compiled this list of academic sources, it is time to move on the steps.

Write your Introduction

In the introduction, you’ll summarize the paper’s content and specify its goals. After, you’ll establish a clear research question or problem that your research will try to answer. With this all done, you’ll introduce who your target audience is and outline how your findings will affect them. In short, the introduction must tell people what they’re getting themselves into.

Write your Methodology section

I will use the grading scale as an example of how to write a formal methodology section. I have been using this system in all my research writing classes, and it has been accepted by both instructors and readers. As such, I feel confident in saying that it is both efficient and effective. The steps are as follows: To begin, place the question or problem statement in brackets at the top of the page. For instance:

Write your Results section

1.Sit down and think about your research project from beginning to end; ask yourself, What are the major findings? What are my key messages? Once you have answered these questions, it is important to think about how the audience of your paper will react. Will they understand what you’re trying to say or explain? If not, can you simplify it?

2. It is a good idea to start by outlining your ideas in points and then reordering them into an outline that flows in sequential order.

3. This next step is one of the most crucial: having someone who understands English grammar and has excellent writing skills read over your paper for errors before submitting it for publishing.

Write your Discussion section

After thinking about the purpose of your research and reading related papers, formulate an original research question. Make sure your question is clear and has a single answer with some way to measure it, otherwise your results will be ambiguous. Once you have developed the best research question, start writing out how you are going to answer it by outlining what you need. Next, follow these steps when starting on your experimental procedures:

1. set up necessary materials and equipment;

2. construct study setup;

3. collect data; and finally

4. analyze data.

Be sure not to rush this process because you want everything in place before getting into the analysis step so that you can quickly find any errors or mistakes if they exist.

Write your Conclusion and Recommendations

In conclusion, I recommend that you write your introduction at the end of the paper. Then, work on the methods and results sections and finally the discussion section. Once you finish with those three sections, then write your introduction. I also recommend using reference materials like an index card and your computer during the process of writing. Remember that publishing a research paper can be fun and rewarding!

Get References from Sources

A lot of people ask me how to publish a research paper. Fortunately, this is pretty easy these days if you know where to start. Here’s how it works. You need your references from sources, of course. These should be from respected and reliable sources (e.g., journals with peer review) that are relevant for your topic area. Your reviewers may require them for approval purposes and/or help evaluating the quality of your research. You’ll want at least five good references – more is better, but not all papers need more than five good references, especially those on popular topics in academic circles or within a specific discipline.

Start Writing

The first step is coming up with a research question.

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AI Index Report

Welcome to the seventh edition of the AI Index report. The 2024 Index is our most comprehensive to date and arrives at an important moment when AI’s influence on society has never been more pronounced. This year, we have broadened our scope to more extensively cover essential trends such as technical advancements in AI, public perceptions of the technology, and the geopolitical dynamics surrounding its development. Featuring more original data than ever before, this edition introduces new estimates on AI training costs, detailed analyses of the responsible AI landscape, and an entirely new chapter dedicated to AI’s impact on science and medicine.

Read the 2024 AI Index Report

The AI Index report tracks, collates, distills, and visualizes data related to artificial intelligence (AI). Our mission is to provide unbiased, rigorously vetted, broadly sourced data in order for policymakers, researchers, executives, journalists, and the general public to develop a more thorough and nuanced understanding of the complex field of AI.

The AI Index is recognized globally as one of the most credible and authoritative sources for data and insights on artificial intelligence. Previous editions have been cited in major newspapers, including the The New York Times, Bloomberg, and The Guardian, have amassed hundreds of academic citations, and been referenced by high-level policymakers in the United States, the United Kingdom, and the European Union, among other places. This year’s edition surpasses all previous ones in size, scale, and scope, reflecting the growing significance that AI is coming to hold in all of our lives.

Steering Committee Co-Directors

Ray Perrault

Steering committee members.

Erik Brynjolfsson

John Etchemendy

Katrina Ligett

Terah Lyons

James Manyika

Juan Carlos Niebles

Vanessa Parli

Yoav Shoham

Russell Wald

Staff members.

Loredana Fattorini

Nestor Maslej

Letter from the co-directors.

A decade ago, the best AI systems in the world were unable to classify objects in images at a human level. AI struggled with language comprehension and could not solve math problems. Today, AI systems routinely exceed human performance on standard benchmarks.

Progress accelerated in 2023. New state-of-the-art systems like GPT-4, Gemini, and Claude 3 are impressively multimodal: They can generate fluent text in dozens of languages, process audio, and even explain memes. As AI has improved, it has increasingly forced its way into our lives. Companies are racing to build AI-based products, and AI is increasingly being used by the general public. But current AI technology still has significant problems. It cannot reliably deal with facts, perform complex reasoning, or explain its conclusions.

AI faces two interrelated futures. First, technology continues to improve and is increasingly used, having major consequences for productivity and employment. It can be put to both good and bad uses. In the second future, the adoption of AI is constrained by the limitations of the technology. Regardless of which future unfolds, governments are increasingly concerned. They are stepping in to encourage the upside, such as funding university R&D and incentivizing private investment. Governments are also aiming to manage the potential downsides, such as impacts on employment, privacy concerns, misinformation, and intellectual property rights.

As AI rapidly evolves, the AI Index aims to help the AI community, policymakers, business leaders, journalists, and the general public navigate this complex landscape. It provides ongoing, objective snapshots tracking several key areas: technical progress in AI capabilities, the community and investments driving AI development and deployment, public opinion on current and potential future impacts, and policy measures taken to stimulate AI innovation while managing its risks and challenges. By comprehensively monitoring the AI ecosystem, the Index serves as an important resource for understanding this transformative technological force.

On the technical front, this year’s AI Index reports that the number of new large language models released worldwide in 2023 doubled over the previous year. Two-thirds were open-source, but the highest-performing models came from industry players with closed systems. Gemini Ultra became the first LLM to reach human-level performance on the Massive Multitask Language Understanding (MMLU) benchmark; performance on the benchmark has improved by 15 percentage points since last year. Additionally, GPT-4 achieved an impressive 0.97 mean win rate score on the comprehensive Holistic Evaluation of Language Models (HELM) benchmark, which includes MMLU among other evaluations.

Although global private investment in AI decreased for the second consecutive year, investment in generative AI skyrocketed. More Fortune 500 earnings calls mentioned AI than ever before, and new studies show that AI tangibly boosts worker productivity. On the policymaking front, global mentions of AI in legislative proceedings have never been higher. U.S. regulators passed more AI-related regulations in 2023 than ever before. Still, many expressed concerns about AI’s ability to generate deepfakes and impact elections. The public became more aware of AI, and studies suggest that they responded with nervousness.

Ray Perrault Co-director, AI Index

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How Pew Research Center will report on generations moving forward

Journalists, researchers and the public often look at society through the lens of generation, using terms like Millennial or Gen Z to describe groups of similarly aged people. This approach can help readers see themselves in the data and assess where we are and where we’re headed as a country.

Pew Research Center has been at the forefront of generational research over the years, telling the story of Millennials as they came of age politically and as they moved more firmly into adult life . In recent years, we’ve also been eager to learn about Gen Z as the leading edge of this generation moves into adulthood.

But generational research has become a crowded arena. The field has been flooded with content that’s often sold as research but is more like clickbait or marketing mythology. There’s also been a growing chorus of criticism about generational research and generational labels in particular.

Recently, as we were preparing to embark on a major research project related to Gen Z, we decided to take a step back and consider how we can study generations in a way that aligns with our values of accuracy, rigor and providing a foundation of facts that enriches the public dialogue.

A typical generation spans 15 to 18 years. As many critics of generational research point out, there is great diversity of thought, experience and behavior within generations.

We set out on a yearlong process of assessing the landscape of generational research. We spoke with experts from outside Pew Research Center, including those who have been publicly critical of our generational analysis, to get their take on the pros and cons of this type of work. We invested in methodological testing to determine whether we could compare findings from our earlier telephone surveys to the online ones we’re conducting now. And we experimented with higher-level statistical analyses that would allow us to isolate the effect of generation.

What emerged from this process was a set of clear guidelines that will help frame our approach going forward. Many of these are principles we’ve always adhered to , but others will require us to change the way we’ve been doing things in recent years.

Here’s a short overview of how we’ll approach generational research in the future:

We’ll only do generational analysis when we have historical data that allows us to compare generations at similar stages of life. When comparing generations, it’s crucial to control for age. In other words, researchers need to look at each generation or age cohort at a similar point in the life cycle. (“Age cohort” is a fancy way of referring to a group of people who were born around the same time.)

When doing this kind of research, the question isn’t whether young adults today are different from middle-aged or older adults today. The question is whether young adults today are different from young adults at some specific point in the past.

To answer this question, it’s necessary to have data that’s been collected over a considerable amount of time – think decades. Standard surveys don’t allow for this type of analysis. We can look at differences across age groups, but we can’t compare age groups over time.

Another complication is that the surveys we conducted 20 or 30 years ago aren’t usually comparable enough to the surveys we’re doing today. Our earlier surveys were done over the phone, and we’ve since transitioned to our nationally representative online survey panel , the American Trends Panel . Our internal testing showed that on many topics, respondents answer questions differently depending on the way they’re being interviewed. So we can’t use most of our surveys from the late 1980s and early 2000s to compare Gen Z with Millennials and Gen Xers at a similar stage of life.

This means that most generational analysis we do will use datasets that have employed similar methodologies over a long period of time, such as surveys from the U.S. Census Bureau. A good example is our 2020 report on Millennial families , which used census data going back to the late 1960s. The report showed that Millennials are marrying and forming families at a much different pace than the generations that came before them.

Even when we have historical data, we will attempt to control for other factors beyond age in making generational comparisons. If we accept that there are real differences across generations, we’re basically saying that people who were born around the same time share certain attitudes or beliefs – and that their views have been influenced by external forces that uniquely shaped them during their formative years. Those forces may have been social changes, economic circumstances, technological advances or political movements.

When we see that younger adults have different views than their older counterparts, it may be driven by their demographic traits rather than the fact that they belong to a particular generation.

The tricky part is isolating those forces from events or circumstances that have affected all age groups, not just one generation. These are often called “period effects.” An example of a period effect is the Watergate scandal, which drove down trust in government among all age groups. Differences in trust across age groups in the wake of Watergate shouldn’t be attributed to the outsize impact that event had on one age group or another, because the change occurred across the board.

Changing demographics also may play a role in patterns that might at first seem like generational differences. We know that the United States has become more racially and ethnically diverse in recent decades, and that race and ethnicity are linked with certain key social and political views. When we see that younger adults have different views than their older counterparts, it may be driven by their demographic traits rather than the fact that they belong to a particular generation.

Controlling for these factors can involve complicated statistical analysis that helps determine whether the differences we see across age groups are indeed due to generation or not. This additional step adds rigor to the process. Unfortunately, it’s often absent from current discussions about Gen Z, Millennials and other generations.

When we can’t do generational analysis, we still see value in looking at differences by age and will do so where it makes sense. Age is one of the most common predictors of differences in attitudes and behaviors. And even if age gaps aren’t rooted in generational differences, they can still be illuminating. They help us understand how people across the age spectrum are responding to key trends, technological breakthroughs and historical events.

Each stage of life comes with a unique set of experiences. Young adults are often at the leading edge of changing attitudes on emerging social trends. Take views on same-sex marriage , for example, or attitudes about gender identity .

Many middle-aged adults, in turn, face the challenge of raising children while also providing care and support to their aging parents. And older adults have their own obstacles and opportunities. All of these stories – rooted in the life cycle, not in generations – are important and compelling, and we can tell them by analyzing our surveys at any given point in time.

When we do have the data to study groups of similarly aged people over time, we won’t always default to using the standard generational definitions and labels. While generational labels are simple and catchy, there are other ways to analyze age cohorts. For example, some observers have suggested grouping people by the decade in which they were born. This would create narrower cohorts in which the members may share more in common. People could also be grouped relative to their age during key historical events (such as the Great Recession or the COVID-19 pandemic) or technological innovations (like the invention of the iPhone).

By choosing not to use the standard generational labels when they’re not appropriate, we can avoid reinforcing harmful stereotypes or oversimplifying people’s complex lived experiences.

Existing generational definitions also may be too broad and arbitrary to capture differences that exist among narrower cohorts. A typical generation spans 15 to 18 years. As many critics of generational research point out, there is great diversity of thought, experience and behavior within generations. The key is to pick a lens that’s most appropriate for the research question that’s being studied. If we’re looking at political views and how they’ve shifted over time, for example, we might group people together according to the first presidential election in which they were eligible to vote.

With these considerations in mind, our audiences should not expect to see a lot of new research coming out of Pew Research Center that uses the generational lens. We’ll only talk about generations when it adds value, advances important national debates and highlights meaningful societal trends.

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ABOUT PEW RESEARCH CENTER Pew Research Center is a nonpartisan fact tank that informs the public about the issues, attitudes and trends shaping the world. It conducts public opinion polling, demographic research, media content analysis and other empirical social science research. Pew Research Center does not take policy positions. It is a subsidiary of The Pew Charitable Trusts .

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Successful Scientific Writing and Publishing: A Step-by-Step Approach

John k. iskander.

1 Centers for Disease Control and Prevention, Atlanta, Georgia

Sara Beth Wolicki

2 Association of Schools and Programs of Public Health, Washington, District of Columbia

Rebecca T. Leeb

Paul z. siegel.

Scientific writing and publication are essential to advancing knowledge and practice in public health, but prospective authors face substantial challenges. Authors can overcome barriers, such as lack of understanding about scientific writing and the publishing process, with training and resources. The objective of this article is to provide guidance and practical recommendations to help both inexperienced and experienced authors working in public health settings to more efficiently publish the results of their work in the peer-reviewed literature. We include an overview of basic scientific writing principles, a detailed description of the sections of an original research article, and practical recommendations for selecting a journal and responding to peer review comments. The overall approach and strategies presented are intended to contribute to individual career development while also increasing the external validity of published literature and promoting quality public health science.

Introduction

Publishing in the peer-reviewed literature is essential to advancing science and its translation to practice in public health ( 1 , 2 ). The public health workforce is diverse and practices in a variety of settings ( 3 ). For some public health professionals, writing and publishing the results of their work is a requirement. Others, such as program managers, policy makers, or health educators, may see publishing as being outside the scope of their responsibilities ( 4 ).

Disseminating new knowledge via writing and publishing is vital both to authors and to the field of public health ( 5 ). On an individual level, publishing is associated with professional development and career advancement ( 6 ). Publications share new research, results, and methods in a trusted format and advance scientific knowledge and practice ( 1 , 7 ). As more public health professionals are empowered to publish, the science and practice of public health will advance ( 1 ).

Unfortunately, prospective authors face barriers to publishing their work, including navigating the process of scientific writing and publishing, which can be time-consuming and cumbersome. Often, public health professionals lack both training opportunities and understanding of the process ( 8 ). To address these barriers and encourage public health professionals to publish their findings, the senior author (P.Z.S.) and others developed Successful Scientific Writing (SSW), a course about scientific writing and publishing. Over the past 30 years, this course has been taught to thousands of public health professionals, as well as hundreds of students at multiple graduate schools of public health. An unpublished longitudinal survey of course participants indicated that two-thirds agreed that SSW had helped them to publish a scientific manuscript or have a conference abstract accepted. The course content has been translated into this manuscript. The objective of this article is to provide prospective authors with the tools needed to write original research articles of high quality that have a good chance of being published.

Basic Recommendations for Scientific Writing

Prospective authors need to know and tailor their writing to the audience. When writing for scientific journals, 4 fundamental recommendations are: clearly stating the usefulness of the study, formulating a key message, limiting unnecessary words, and using strategic sentence structure.

To demonstrate usefulness, focus on how the study addresses a meaningful gap in current knowledge or understanding. What critical piece of information does the study provide that will help solve an important public health problem? For example, if a particular group of people is at higher risk for a specific condition, but the magnitude of that risk is unknown, a study to quantify the risk could be important for measuring the population’s burden of disease.

Scientific articles should have a clear and concise take-home message. Typically, this is expressed in 1 to 2 sentences that summarize the main point of the paper. This message can be used to focus the presentation of background information, results, and discussion of findings. As an early step in the drafting of an article, we recommend writing out the take-home message and sharing it with co-authors for their review and comment. Authors who know their key point are better able to keep their writing within the scope of the article and present information more succinctly. Once an initial draft of the manuscript is complete, the take-home message can be used to review the content and remove needless words, sentences, or paragraphs.

Concise writing improves the clarity of an article. Including additional words or clauses can divert from the main message and confuse the reader. Additionally, journal articles are typically limited by word count. The most important words and phrases to eliminate are those that do not add meaning, or are duplicative. Often, cutting adjectives or parenthetical statements results in a more concise paper that is also easier to read.

Sentence structure strongly influences the readability and comprehension of journal articles. Twenty to 25 words is a reasonable range for maximum sentence length. Limit the number of clauses per sentence, and place the most important or relevant clause at the end of the sentence ( 9 ). Consider the sentences:

By using these tips and tricks, an author may write and publish an additional 2 articles a year.
An author may write and publish an additional 2 articles a year by using these tips and tricks.

The focus of the first sentence is on the impact of using the tips and tricks, that is, 2 more articles published per year. In contrast, the second sentence focuses on the tips and tricks themselves.

Authors should use the active voice whenever possible. Consider the following example:

Active voice: Authors who use the active voice write more clearly.
Passive voice: Clarity of writing is promoted by the use of the active voice.

The active voice specifies who is doing the action described in the sentence. Using the active voice improves clarity and understanding, and generally uses fewer words. Scientific writing includes both active and passive voice, but authors should be intentional with their use of either one.

Sections of an Original Research Article

Original research articles make up most of the peer-reviewed literature ( 10 ), follow a standardized format, and are the focus of this article. The 4 main sections are the introduction, methods, results, and discussion, sometimes referred to by the initialism, IMRAD. These 4 sections are referred to as the body of an article. Two additional components of all peer-reviewed articles are the title and the abstract. Each section’s purpose and key components, along with specific recommendations for writing each section, are listed below.

Title. The purpose of a title is twofold: to provide an accurate and informative summary and to attract the target audience. Both prospective readers and database search engines use the title to screen articles for relevance ( 2 ). All titles should clearly state the topic being studied. The topic includes the who, what, when, and where of the study. Along with the topic, select 1 or 2 of the following items to include within the title: methods, results, conclusions, or named data set or study. The items chosen should emphasize what is new and useful about the study. Some sources recommend limiting the title to less than 150 characters ( 2 ). Articles with shorter titles are more frequently cited than articles with longer titles ( 11 ). Several title options are possible for the same study ( Figure ).

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Object name is PCD-15-E79s01.jpg

Two examples of title options for a single study.

Abstract . The abstract serves 2 key functions. Journals may screen articles for potential publication by using the abstract alone ( 12 ), and readers may use the abstract to decide whether to read further. Therefore, it is critical to produce an accurate and clear abstract that highlights the major purpose of the study, basic procedures, main findings, and principal conclusions ( 12 ). Most abstracts have a word limit and can be either structured following IMRAD, or unstructured. The abstract needs to stand alone from the article and tell the most important parts of the scientific story up front.

Introduction . The purpose of the introduction is to explain how the study sought to create knowledge that is new and useful. The introduction section may often require only 3 paragraphs. First, describe the scope, nature, or magnitude of the problem being addressed. Next, clearly articulate why better understanding this problem is useful, including what is currently known and the limitations of relevant previous studies. Finally, explain what the present study adds to the knowledge base. Explicitly state whether data were collected in a unique way or obtained from a previously unstudied data set or population. Presenting both the usefulness and novelty of the approach taken will prepare the reader for the remaining sections of the article.

Methods . The methods section provides the information necessary to allow others, given the same data, to recreate the analysis. It describes exactly how data relevant to the study purpose were collected, organized, and analyzed. The methods section describes the process of conducting the study — from how the sample was selected to which statistical methods were used to analyze the data. Authors should clearly name, define, and describe each study variable. Some journals allow detailed methods to be included in an appendix or supplementary document. If the analysis involves a commonly used public health data set, such as the Behavioral Risk Factor Surveillance System ( 13 ), general aspects of the data set can be provided to readers by using references. Because what was done is typically more important than who did it, use of the passive voice is often appropriate when describing methods. For example, “The study was a group randomized, controlled trial. A coin was tossed to select an intervention group and a control group.”

Results . The results section describes the main outcomes of the study or analysis but does not interpret the findings or place them in the context of previous research. It is important that the results be logically organized. Suggested organization strategies include presenting results pertaining to the entire population first, and then subgroup analyses, or presenting results according to increasing complexity of analysis, starting with demographic results before proceeding to univariate and multivariate analyses. Authors wishing to draw special attention to novel or unexpected results can present them first.

One strategy for writing the results section is to start by first drafting the figures and tables. Figures, which typically show trends or relationships, and tables, which show specific data points, should each support a main outcome of the study. Identify the figures and tables that best describe the findings and relate to the study’s purpose, and then develop 1 to 2 sentences summarizing each one. Data not relevant to the study purpose may be excluded, summarized briefly in the text, or included in supplemental data sets. When finalizing figures, ensure that axes are labeled and that readers can understand figures without having to refer to accompanying text.

Discussion . In the discussion section, authors interpret the results of their study within the context of both the related literature and the specific scientific gap the study was intended to fill. The discussion does not introduce results that were not presented in the results section. One way authors can focus their discussion is to limit this section to 4 paragraphs: start by reinforcing the study’s take-home message(s), contextualize key results within the relevant literature, state the study limitations, and lastly, make recommendations for further research or policy and practice changes. Authors can support assertions made in the discussion with either their own findings or by referencing related research. By interpreting their own study results and comparing them to others in the literature, authors can emphasize findings that are unique, useful, and relevant. Present study limitations clearly and without apology. Finally, state the implications of the study and provide recommendations or next steps, for example, further research into remaining gaps or changes to practice or policy. Statements or recommendations regarding policy may use the passive voice, especially in instances where the action to be taken is more important than who will implement the action.

Beginning the Writing Process

The process of writing a scientific article occurs before, during, and after conducting the study or analyses. Conducting a literature review is crucial to confirm the existence of the evidence gap that the planned analysis seeks to fill. Because literature searches are often part of applying for research funding or developing a study protocol, the citations used in the grant application or study proposal can also be used in subsequent manuscripts. Full-text databases such as PubMed Central ( 14 ), NIH RePORT ( 15 ), and CDC Stacks ( 16 ) can be useful when performing literature reviews. Authors should familiarize themselves with databases that are accessible through their institution and any assistance that may be available from reference librarians or interlibrary loan systems. Using citation management software is one way to establish and maintain a working reference list. Authors should clearly understand the distinction between primary and secondary references, and ensure that they are knowledgeable about the content of any primary or secondary reference that they cite.

Review of the literature may continue while organizing the material and writing begins. One way to organize material is to create an outline for the paper. Another way is to begin drafting small sections of the article such as the introduction. Starting a preliminary draft forces authors to establish the scope of their analysis and clearly articulate what is new and novel about the study. Furthermore, using information from the study protocol or proposal allows authors to draft the methods and part of the results sections while the study is in progress. Planning potential data comparisons or drafting “table shells” will help to ensure that the study team has collected all the necessary data. Drafting these preliminary sections early during the writing process and seeking feedback from co-authors and colleagues may help authors avoid potential pitfalls, including misunderstandings about study objectives.

The next step is to conduct the study or analyses and use the resulting data to fill in the draft table shells. The initial results will most likely require secondary analyses, that is, exploring the data in ways in addition to those originally planned. Authors should ensure that they regularly update their methods section to describe all changes to data analysis.

After completing table shells, authors should summarize the key finding of each table or figure in a sentence or two. Presenting preliminary results at meetings, conferences, and internal seminars is an established way to solicit feedback. Authors should pay close attention to questions asked by the audience, treating them as an informal opportunity for peer review. On the basis of the questions and feedback received, authors can incorporate revisions and improvements into subsequent drafts of the manuscript.

The relevant literature should be revisited periodically while writing to ensure knowledge of the most recent publications about the manuscript topic. Authors should focus on content and key message during the process of writing the first draft and should not spend too much time on issues of grammar or style. Drafts, or portions of drafts, should be shared frequently with trusted colleagues. Their recommendations should be reviewed and incorporated when they will improve the manuscript’s overall clarity.

For most authors, revising drafts of the manuscript will be the most time-consuming task involved in writing a paper. By regularly checking in with coauthors and colleagues, authors can adopt a systematic approach to rewriting. When the author has completed a draft of the manuscript, he or she should revisit the key take-home message to ensure that it still matches the final data and analysis. At this point, final comments and approval of the manuscript by coauthors can be sought.

Authors should then seek to identify journals most likely to be interested in considering the study for publication. Initial questions to consider when selecting a journal include:

Which audience is most interested in the paper’s message?
Would clinicians, public health practitioners, policy makers, scientists, or a broader audience find this useful in their field or practice?
Do colleagues have prior experience submitting a manuscript to this journal?
Is the journal indexed and peer-reviewed?
Is the journal subscription or open-access and are there any processing fees?
How competitive is the journal?

Authors should seek to balance the desire to be published in a top-tier journal (eg, Journal of the American Medical Association, BMJ, or Lancet) against the statistical likelihood of rejection. Submitting the paper initially to a journal more focused on the paper’s target audience may result in a greater chance of acceptance, as well as more timely dissemination of findings that can be translated into practice. Most of the 50 to 75 manuscripts published each week by authors from the Centers for Disease Control and Prevention (CDC) are published in specialty and subspecialty journals, rather than in top-tier journals ( 17 ).

The target journal’s website will include author guidelines, which will contain specific information about format requirements (eg, font, line spacing, section order, reference style and limit, table and figure formatting), authorship criteria, article types, and word limits for articles and abstracts.

We recommend returning to the previously drafted abstract and ensuring that it complies with the journal’s format and word limit. Authors should also verify that any changes made to the methods or results sections during the article’s drafting are reflected in the final version of the abstract. The abstract should not be written hurriedly just before submitting the manuscript; it is often apparent to editors and reviewers when this has happened. A cover letter to accompany the submission should be drafted; new and useful findings and the key message should be included.

Before submitting the manuscript and cover letter, authors should perform a final check to ensure that their paper complies with all journal requirements. Journals may elect to reject certain submissions on the basis of review of the abstract, or may send them to peer reviewers (typically 2 or 3) for consultation. Occasionally, on the basis of peer reviews, the journal will request only minor changes before accepting the paper for publication. Much more frequently, authors will receive a request to revise and resubmit their manuscript, taking into account peer review comments. Authors should recognize that while revise-and-resubmit requests may state that the manuscript is not acceptable in its current form, this does not constitute a rejection of the article. Authors have several options in responding to peer review comments:

Performing additional analyses and updating the article appropriately
Declining to perform additional analyses, but providing an explanation (eg, because the requested analysis goes beyond the scope of the article)
Providing updated references
Acknowledging reviewer comments that are simply comments without making changes

In addition to submitting a revised manuscript, authors should include a cover letter in which they list peer reviewer comments, along with the revisions they have made to the manuscript and their reply to the comment. The tone of such letters should be thankful and polite, but authors should make clear areas of disagreement with peer reviewers, and explain why they disagree. During the peer review process, authors should continue to consult with colleagues, especially ones who have more experience with the specific journal or with the peer review process.

There is no secret to successful scientific writing and publishing. By adopting a systematic approach and by regularly seeking feedback from trusted colleagues throughout the study, writing, and article submission process, authors can increase their likelihood of not only publishing original research articles of high quality but also becoming more scientifically productive overall.

Acknowledgments

The authors acknowledge PCD ’s former Associate Editor, Richard A. Goodman, MD, MPH, who, while serving as Editor in Chief of CDC’s Morbidity and Mortality Weekly Report Series, initiated a curriculum on scientific writing for training CDC’s Epidemic Intelligence Service Officers and other CDC public health professionals, and with whom the senior author of this article (P.Z.S.) collaborated in expanding training methods and contents, some of which are contained in this article. The authors acknowledge Juan Carlos Zevallos, MD, for his thoughtful critique and careful editing of previous Successful Scientific Writing materials. We also thank Shira Eisenberg for editorial assistance with the manuscript. This publication was supported by the Cooperative Agreement no. 1U360E000002 from CDC and the Association of Schools and Programs of Public Health. The findings and conclusions of this article do not necessarily represent the official views of CDC or the Association of Schools and Programs of Public Health. Names of journals and citation databases are provided for identification purposes only and do not constitute any endorsement by CDC.

The opinions expressed by authors contributing to this journal do not necessarily reflect the opinions of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors' affiliated institutions.

Suggested citation for this article: Iskander JK, Wolicki SB, Leeb RT, Siegel PZ. Successful Scientific Writing and Publishing: A Step-by-Step Approach. Prev Chronic Dis 2018;15:180085. DOI: https://doi.org/10.5888/pcd15.180085 .

EDITORIAL article

This article is part of the research topic.

Embryo Development and Selection: Advances in Genetics

Editorial: Embryo Development and Selection: Advances in Genetics Provisionally Accepted

1 Guilin Medical University, China
2 Hainan Medical University, China

The final, formatted version of the article will be published soon.

Assisted reproductive technologies (ART) are being utilized with increasing frequency across the globe to support individuals who face challenges in conceiving naturally. ART procedures facilitate pregnancy by extracting eggs from a woman's ovaries, fusing them with sperm in a laboratory setting, and subsequently reintroducing them into the woman's body. The efficacy of ART is subject to a multitude of factors, encompassing genetic considerations, historical medical and reproductive data, the specific medications employed during ART treatment, and any complications that may arise during pregnancy. The focus of this research topic is the selection of embryos during the ART process, and an exploration of the factors that influence embryo development and the overall success rate of ART. 1. Abu et al. evaluated the impact of supplementing a single-dose GnRH agonist to the standard progestogen regimen for luteal phase support in IVF treatments. Compared to using progestogens alone, they found that adding a GnRH agonist improved the overall IVF outcomes.2. Andreescu has conducted a review on the dysregulation of immune responses between the mother and fetus, a factor that heightens the risk of embryo rejection and reproductive failure.This paper provides an exhaustive overview of the current literature on the influence of Calcineurin inhibitors and anti-TNF treatment in enhancing the live birth rate post embryo transfer. It concludes that the suppression of immunological rejection and the promotion of immunological tolerance are vital in safeguarding embryos and averting immunological assaults. Therefore, it is important to exercise caution while selecting use of any immunosuppressive therapy in pregnancy. indicates that the risks associated with angular pregnancy following ART may not be as severe as previously thought. With regular, close monitoring, the majority of these cases can be managed expectantly, often resulting in live births. 5. Zhu and colleagues conducted a study to identify the risk factors that influence the occurrence of heterotopic pregnancies following IVF-ET. They also examined the outcomes of pregnancies after surgical intervention for heterotopic pregnancies. Their research indicates that a history of ectopic pregnancy, multiple abortions, tubal infertility, and multiple-embryo transfer may significantly increase the risk of a subsequent heterotopic pregnancy after IVF-ET.The study also found that for patients with heterotopic pregnancies who undergo surgery, factors such as a shorter operation duration, a smaller ectopic mass, and a location in the ampulla of the fallopian tube are associated with a more favorable reproductive prognosis. IVF success rates are influenced by a multitude of factors, including genetic considerations, historical medical and reproductive data, the types of medications used during ART treatment, and complications that may arise during pregnancy. The research papers discussed here offer significant insights into improving the success rates of IVF. They underscore the efficacy of a combined treatment approach using N-Acetylcysteine and Gonadotropins, which has been shown to enhance ovarian response to superovulation drugs and improve the quality of blastocysts in older women. The papers also identify surgical time, the size of ectopic masses, and their location in the ampulla of the fallopian tube as key factors in determining the reproductive prognosis in patients with ectopic pregnancies. Additionally, the use of GnRH agonists in the luteal phase has been found to increase IVF success rates. The papers also discuss the evaluation of cornual pregnancy following ART. The aim of these studies is to reduce the risks associated with assisted reproduction and increase pregnancy rates, thereby providing invaluable information for clinical IVF centers. The referenced studies investigate the influence of several factors on the success rate of IVF. These factors encompass the patient's medical history, the treatment protocol, the medications administered during treatment, and complications encountered during pregnancy.The insights and research outcomes presented are of immense value for improving the success rates of assisted reproductive techniques.

Keywords: assisted reproductive technologies, Pregnancy rates, Embryo development, Embryo selection, Influence factor

Received: 13 Apr 2024; Accepted: 22 Apr 2024.

Copyright: © 2024 Liu and Ma. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY) . The use, distribution or reproduction in other forums is permitted, provided the original author(s) or licensor are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

* Correspondence: Mx. Yanlin Ma, Hainan Medical University, Haikou, 571199, Hainan Province, China

People also looked at

In the brain, bursts of beta rhythms implement cognitive control

Bursts of brain rhythms with “beta” frequencies control where and when neurons in the cortex process sensory information and plan responses. Studying these bursts would improve understanding of cognition and clinical disorders, researchers argue in a new review.

The brain processes information on many scales. Individual cells electrochemically transmit signals in circuits but at the large scale required to produce cognition, millions of cells act in concert, driven by rhythmic signals at varying frequencies. Studying one frequency range in particular, beta rhythms between about 14-30 Hz, holds the key to understanding how the brain controls cognitive processes—or loses control in some disorders—a team of neuroscientists argues in a new review article.

Drawing on experimental data, mathematical modeling and theory, the scientists make the case that bursts of beta rhythms control cognition in the brain by regulating where and when higher gamma frequency waves can coordinate neurons to incorporate new information from the senses or formulate plans of action. Beta bursts, they argue, quickly establish flexible but controlled patterns of neural activity for implementing intentional thought.

“Cognition depends on organizing goal-directed thought, so if you want to understand cognition, you have to understand that organization,” said co-author Earl K. Miller , Picower Professor in The Picower Institute for Learning and Memory and the Department of Brain and Cognitive Sciences at MIT. “Beta is the range of frequencies that can control neurons at the right spatial scale to produce organized thought.”

Miller and colleagues Mikael Lundqvist, Jonatan Nordmark and Johan Liljefors at the Karolinska Institutet and Pawel Herman at the KTH Royal Institute of Technology in Sweden, write that studying bursts of beta rhythms to understand how they emerge and what they represent would not only help explain cognition, but also aid in diagnosing and treating cognitive disorders.

“Given the relevance of beta oscillations in cognition, we foresee a major change in the practice for biomarker identification, especially given the prominence of beta bursting in inhibitory control processes … and their importance in ADHD, schizophrenia and Alzheimer’s disease,” they write in the journal Trends in Cognitive Sciences .

Experimental studies covering several species including humans, a variety of brain regions, and numerous cognitive tasks have revealed key characteristics of beta waves in the cortex, the authors write: Beta rhythms occur in quick but powerful bursts; they inhibit the power of higher frequency gamma rhythms; and though they originate in deeper brain regions, they travel within specific locations of cortex. Considering these properties together, the authors write that they are all consistent with precise and flexible regulation, in space and time, of the gamma rhythm activity that experiments show carry signals of sensory information and motor plans.

A chart from a study plots bursts of brain waves of varying frequency at specific times. The bursts are represented as warm colors against a the blue background. When there are low frequency bursts there aren't high frequency bursts and vice versa.

“Beta bursts thus offer new opportunities for studying how sensory inputs are selectively processed, reshaped by inhibitory cognitive operations and ultimately result in motor actions,” the authors write.

For one example, Miller and colleagues have shown in animals that in the prefrontal cortex in working memory tasks, beta bursts direct when gamma activity can store new sensory information, read out the information when it needs to be used, and then discard it when it’s no longer relevant. For another example, other researchers have shown that beta rises when human volunteers are asked to suppress a previously learned association between word pairs, or to forget a cue because it will no longer be used in a task.

In a paper last year, Lundqvist, Herman, Miller and others cited several lines of experimental evidence to hypothesize that beta bursts implement cognitive control spatially in the brain , essentially constraining patches of the cortex to represent the general rules of a task even as individual neurons within those patches represent the specific contents of information. For example, if the working memory task is to remember a pad lock combination, beta rhythms will implement patches of cortex for the general steps “turn left,” “turn right,” “turn left again,” allowing gamma to enable neurons within each patch to store and later recall the specific numbers of the combination. The two-fold value of such an organizing principle, they noted, is that the brain can rapidly apply task rules to many neurons at a time and do so without having to re-establish the overall structure of the task if the individual numbers change (i.e. you set a new combination).

Another important phenomenon of beta bursts, the authors write, is that they propagate across long distances in the brain, spanning multiple regions. Studying the direction of their spatial travels, as well as their timing, could shed further light on how cognitive control is implemented.

New ideas beget new questions

Beta rhythm bursts can differ not only in their frequency, but also their duration, amplitude, origin and other characteristics. This variety speaks to their versatility, the authors write, but also obliges neuroscientists to study and understand these many different forms of the phenomenon and what they represent to harness more information from these neural signals.

“It quickly becomes very complicated, but I think the most important aspect of beta bursts is the very simple and basic premise that they shed light on the transient nature of oscillations and neural processes associated with cognition,” Lundqvist said.“This changes our models of cognition and will impact everything we do. For a long time we implicitly or explicitly assumed oscillations are ongoing which has colored experiments and analyses. Now we see a first wave of studies based on this new thinking, with new hypothesis and ways to analyze data, and it should only pick up in years to come.”

The authors acknowledge another major issue that must be resolved by further research—How do beta bursts emerge in the first place to perform their apparent role in cognitive control?

“It is unknown how beta bursts arise as a mediator of an executive command that cascades to other regions of the brain,” the authors write.

The authors don’t claim to have all the answers. Instead, they write, because beta rhythms appear to have an integral role in controlling cognition, the as yet unanswered questions are worth asking.

“We propose that beta bursts provide both experimental and computational studies with a window through which to explore the real-time organization and execution of cognitive functions,” they conclude. “To fully leverage this potential there is a need to address the outstanding questions with new experimental paradigms, analytical methods and modeling approaches.”

Paper: to understand cognition—and its dysfunction—neuroscientists must learn its rhythms.

Study reveals a universal pattern of brain wave frequencies

Anesthesia blocks sensation by cutting off communication within the cortex

Anesthesia technology precisely controls unconsciousness in animal tests

An operating room scene shows a patient on a table. Our perspective is from behind the anesthesiologist who holds a mask on the patient's face and watches a monitor with a bunch of indicators. A surgeon stands out of focus on the far end of the patient.

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Published: 17 April 2024

The economic commitment of climate change

Maximilian Kotz ORCID: orcid.org/0000-0003-2564-5043 1 , 2 ,
Anders Levermann ORCID: orcid.org/0000-0003-4432-4704 1 , 2 &
Leonie Wenz ORCID: orcid.org/0000-0002-8500-1568 1 , 3

Nature volume 628 , pages 551–557 ( 2024 ) Cite this article

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Environmental economics
Environmental health
Interdisciplinary studies
Projection and prediction

Global projections of macroeconomic climate-change damages typically consider impacts from average annual and national temperatures over long time horizons 1 , 2 , 3 , 4 , 5 , 6 . Here we use recent empirical findings from more than 1,600 regions worldwide over the past 40 years to project sub-national damages from temperature and precipitation, including daily variability and extremes 7 , 8 . Using an empirical approach that provides a robust lower bound on the persistence of impacts on economic growth, we find that the world economy is committed to an income reduction of 19% within the next 26 years independent of future emission choices (relative to a baseline without climate impacts, likely range of 11–29% accounting for physical climate and empirical uncertainty). These damages already outweigh the mitigation costs required to limit global warming to 2 °C by sixfold over this near-term time frame and thereafter diverge strongly dependent on emission choices. Committed damages arise predominantly through changes in average temperature, but accounting for further climatic components raises estimates by approximately 50% and leads to stronger regional heterogeneity. Committed losses are projected for all regions except those at very high latitudes, at which reductions in temperature variability bring benefits. The largest losses are committed at lower latitudes in regions with lower cumulative historical emissions and lower present-day income.

Climate damage projections beyond annual temperature

Paul Waidelich, Fulden Batibeniz, … Sonia I. Seneviratne

Investment incentive reduced by climate damages can be restored by optimal policy

Sven N. Willner, Nicole Glanemann & Anders Levermann

Climate economics support for the UN climate targets

Martin C. Hänsel, Moritz A. Drupp, … Thomas Sterner

Projections of the macroeconomic damage caused by future climate change are crucial to informing public and policy debates about adaptation, mitigation and climate justice. On the one hand, adaptation against climate impacts must be justified and planned on the basis of an understanding of their future magnitude and spatial distribution 9 . This is also of importance in the context of climate justice 10 , as well as to key societal actors, including governments, central banks and private businesses, which increasingly require the inclusion of climate risks in their macroeconomic forecasts to aid adaptive decision-making 11 , 12 . On the other hand, climate mitigation policy such as the Paris Climate Agreement is often evaluated by balancing the costs of its implementation against the benefits of avoiding projected physical damages. This evaluation occurs both formally through cost–benefit analyses 1 , 4 , 5 , 6 , as well as informally through public perception of mitigation and damage costs 13 .

Projections of future damages meet challenges when informing these debates, in particular the human biases relating to uncertainty and remoteness that are raised by long-term perspectives 14 . Here we aim to overcome such challenges by assessing the extent of economic damages from climate change to which the world is already committed by historical emissions and socio-economic inertia (the range of future emission scenarios that are considered socio-economically plausible 15 ). Such a focus on the near term limits the large uncertainties about diverging future emission trajectories, the resulting long-term climate response and the validity of applying historically observed climate–economic relations over long timescales during which socio-technical conditions may change considerably. As such, this focus aims to simplify the communication and maximize the credibility of projected economic damages from future climate change.

In projecting the future economic damages from climate change, we make use of recent advances in climate econometrics that provide evidence for impacts on sub-national economic growth from numerous components of the distribution of daily temperature and precipitation 3 , 7 , 8 . Using fixed-effects panel regression models to control for potential confounders, these studies exploit within-region variation in local temperature and precipitation in a panel of more than 1,600 regions worldwide, comprising climate and income data over the past 40 years, to identify the plausibly causal effects of changes in several climate variables on economic productivity 16 , 17 . Specifically, macroeconomic impacts have been identified from changing daily temperature variability, total annual precipitation, the annual number of wet days and extreme daily rainfall that occur in addition to those already identified from changing average temperature 2 , 3 , 18 . Moreover, regional heterogeneity in these effects based on the prevailing local climatic conditions has been found using interactions terms. The selection of these climate variables follows micro-level evidence for mechanisms related to the impacts of average temperatures on labour and agricultural productivity 2 , of temperature variability on agricultural productivity and health 7 , as well as of precipitation on agricultural productivity, labour outcomes and flood damages 8 (see Extended Data Table 1 for an overview, including more detailed references). References 7 , 8 contain a more detailed motivation for the use of these particular climate variables and provide extensive empirical tests about the robustness and nature of their effects on economic output, which are summarized in Methods . By accounting for these extra climatic variables at the sub-national level, we aim for a more comprehensive description of climate impacts with greater detail across both time and space.

Constraining the persistence of impacts

A key determinant and source of discrepancy in estimates of the magnitude of future climate damages is the extent to which the impact of a climate variable on economic growth rates persists. The two extreme cases in which these impacts persist indefinitely or only instantaneously are commonly referred to as growth or level effects 19 , 20 (see Methods section ‘Empirical model specification: fixed-effects distributed lag models’ for mathematical definitions). Recent work shows that future damages from climate change depend strongly on whether growth or level effects are assumed 20 . Following refs. 2 , 18 , we provide constraints on this persistence by using distributed lag models to test the significance of delayed effects separately for each climate variable. Notably, and in contrast to refs. 2 , 18 , we use climate variables in their first-differenced form following ref. 3 , implying a dependence of the growth rate on a change in climate variables. This choice means that a baseline specification without any lags constitutes a model prior of purely level effects, in which a permanent change in the climate has only an instantaneous effect on the growth rate 3 , 19 , 21 . By including lags, one can then test whether any effects may persist further. This is in contrast to the specification used by refs. 2 , 18 , in which climate variables are used without taking the first difference, implying a dependence of the growth rate on the level of climate variables. In this alternative case, the baseline specification without any lags constitutes a model prior of pure growth effects, in which a change in climate has an infinitely persistent effect on the growth rate. Consequently, including further lags in this alternative case tests whether the initial growth impact is recovered 18 , 19 , 21 . Both of these specifications suffer from the limiting possibility that, if too few lags are included, one might falsely accept the model prior. The limitations of including a very large number of lags, including loss of data and increasing statistical uncertainty with an increasing number of parameters, mean that such a possibility is likely. By choosing a specification in which the model prior is one of level effects, our approach is therefore conservative by design, avoiding assumptions of infinite persistence of climate impacts on growth and instead providing a lower bound on this persistence based on what is observable empirically (see Methods section ‘Empirical model specification: fixed-effects distributed lag models’ for further exposition of this framework). The conservative nature of such a choice is probably the reason that ref. 19 finds much greater consistency between the impacts projected by models that use the first difference of climate variables, as opposed to their levels.

We begin our empirical analysis of the persistence of climate impacts on growth using ten lags of the first-differenced climate variables in fixed-effects distributed lag models. We detect substantial effects on economic growth at time lags of up to approximately 8–10 years for the temperature terms and up to approximately 4 years for the precipitation terms (Extended Data Fig. 1 and Extended Data Table 2 ). Furthermore, evaluation by means of information criteria indicates that the inclusion of all five climate variables and the use of these numbers of lags provide a preferable trade-off between best-fitting the data and including further terms that could cause overfitting, in comparison with model specifications excluding climate variables or including more or fewer lags (Extended Data Fig. 3 , Supplementary Methods Section 1 and Supplementary Table 1 ). We therefore remove statistically insignificant terms at later lags (Supplementary Figs. 1 – 3 and Supplementary Tables 2 – 4 ). Further tests using Monte Carlo simulations demonstrate that the empirical models are robust to autocorrelation in the lagged climate variables (Supplementary Methods Section 2 and Supplementary Figs. 4 and 5 ), that information criteria provide an effective indicator for lag selection (Supplementary Methods Section 2 and Supplementary Fig. 6 ), that the results are robust to concerns of imperfect multicollinearity between climate variables and that including several climate variables is actually necessary to isolate their separate effects (Supplementary Methods Section 3 and Supplementary Fig. 7 ). We provide a further robustness check using a restricted distributed lag model to limit oscillations in the lagged parameter estimates that may result from autocorrelation, finding that it provides similar estimates of cumulative marginal effects to the unrestricted model (Supplementary Methods Section 4 and Supplementary Figs. 8 and 9 ). Finally, to explicitly account for any outstanding uncertainty arising from the precise choice of the number of lags, we include empirical models with marginally different numbers of lags in the error-sampling procedure of our projection of future damages. On the basis of the lag-selection procedure (the significance of lagged terms in Extended Data Fig. 1 and Extended Data Table 2 , as well as information criteria in Extended Data Fig. 3 ), we sample from models with eight to ten lags for temperature and four for precipitation (models shown in Supplementary Figs. 1 – 3 and Supplementary Tables 2 – 4 ). In summary, this empirical approach to constrain the persistence of climate impacts on economic growth rates is conservative by design in avoiding assumptions of infinite persistence, but nevertheless provides a lower bound on the extent of impact persistence that is robust to the numerous tests outlined above.

Committed damages until mid-century

We combine these empirical economic response functions (Supplementary Figs. 1 – 3 and Supplementary Tables 2 – 4 ) with an ensemble of 21 climate models (see Supplementary Table 5 ) from the Coupled Model Intercomparison Project Phase 6 (CMIP-6) 22 to project the macroeconomic damages from these components of physical climate change (see Methods for further details). Bias-adjusted climate models that provide a highly accurate reproduction of observed climatological patterns with limited uncertainty (Supplementary Table 6 ) are used to avoid introducing biases in the projections. Following a well-developed literature 2 , 3 , 19 , these projections do not aim to provide a prediction of future economic growth. Instead, they are a projection of the exogenous impact of future climate conditions on the economy relative to the baselines specified by socio-economic projections, based on the plausibly causal relationships inferred by the empirical models and assuming ceteris paribus. Other exogenous factors relevant for the prediction of economic output are purposefully assumed constant.

A Monte Carlo procedure that samples from climate model projections, empirical models with different numbers of lags and model parameter estimates (obtained by 1,000 block-bootstrap resamples of each of the regressions in Supplementary Figs. 1 – 3 and Supplementary Tables 2 – 4 ) is used to estimate the combined uncertainty from these sources. Given these uncertainty distributions, we find that projected global damages are statistically indistinguishable across the two most extreme emission scenarios until 2049 (at the 5% significance level; Fig. 1 ). As such, the climate damages occurring before this time constitute those to which the world is already committed owing to the combination of past emissions and the range of future emission scenarios that are considered socio-economically plausible 15 . These committed damages comprise a permanent income reduction of 19% on average globally (population-weighted average) in comparison with a baseline without climate-change impacts (with a likely range of 11–29%, following the likelihood classification adopted by the Intergovernmental Panel on Climate Change (IPCC); see caption of Fig. 1 ). Even though levels of income per capita generally still increase relative to those of today, this constitutes a permanent income reduction for most regions, including North America and Europe (each with median income reductions of approximately 11%) and with South Asia and Africa being the most strongly affected (each with median income reductions of approximately 22%; Fig. 1 ). Under a middle-of-the road scenario of future income development (SSP2, in which SSP stands for Shared Socio-economic Pathway), this corresponds to global annual damages in 2049 of 38 trillion in 2005 international dollars (likely range of 19–59 trillion 2005 international dollars). Compared with empirical specifications that assume pure growth or pure level effects, our preferred specification that provides a robust lower bound on the extent of climate impact persistence produces damages between these two extreme assumptions (Extended Data Fig. 3 ).

Estimates of the projected reduction in income per capita from changes in all climate variables based on empirical models of climate impacts on economic output with a robust lower bound on their persistence (Extended Data Fig. 1 ) under a low-emission scenario compatible with the 2 °C warming target and a high-emission scenario (SSP2-RCP2.6 and SSP5-RCP8.5, respectively) are shown in purple and orange, respectively. Shading represents the 34% and 10% confidence intervals reflecting the likely and very likely ranges, respectively (following the likelihood classification adopted by the IPCC), having estimated uncertainty from a Monte Carlo procedure, which samples the uncertainty from the choice of physical climate models, empirical models with different numbers of lags and bootstrapped estimates of the regression parameters shown in Supplementary Figs. 1 – 3 . Vertical dashed lines show the time at which the climate damages of the two emission scenarios diverge at the 5% and 1% significance levels based on the distribution of differences between emission scenarios arising from the uncertainty sampling discussed above. Note that uncertainty in the difference of the two scenarios is smaller than the combined uncertainty of the two respective scenarios because samples of the uncertainty (climate model and empirical model choice, as well as model parameter bootstrap) are consistent across the two emission scenarios, hence the divergence of damages occurs while the uncertainty bounds of the two separate damage scenarios still overlap. Estimates of global mitigation costs from the three IAMs that provide results for the SSP2 baseline and SSP2-RCP2.6 scenario are shown in light green in the top panel, with the median of these estimates shown in bold.

Damages already outweigh mitigation costs

We compare the damages to which the world is committed over the next 25 years to estimates of the mitigation costs required to achieve the Paris Climate Agreement. Taking estimates of mitigation costs from the three integrated assessment models (IAMs) in the IPCC AR6 database 23 that provide results under comparable scenarios (SSP2 baseline and SSP2-RCP2.6, in which RCP stands for Representative Concentration Pathway), we find that the median committed climate damages are larger than the median mitigation costs in 2050 (six trillion in 2005 international dollars) by a factor of approximately six (note that estimates of mitigation costs are only provided every 10 years by the IAMs and so a comparison in 2049 is not possible). This comparison simply aims to compare the magnitude of future damages against mitigation costs, rather than to conduct a formal cost–benefit analysis of transitioning from one emission path to another. Formal cost–benefit analyses typically find that the net benefits of mitigation only emerge after 2050 (ref. 5 ), which may lead some to conclude that physical damages from climate change are simply not large enough to outweigh mitigation costs until the second half of the century. Our simple comparison of their magnitudes makes clear that damages are actually already considerably larger than mitigation costs and the delayed emergence of net mitigation benefits results primarily from the fact that damages across different emission paths are indistinguishable until mid-century (Fig. 1 ).

Although these near-term damages constitute those to which the world is already committed, we note that damage estimates diverge strongly across emission scenarios after 2049, conveying the clear benefits of mitigation from a purely economic point of view that have been emphasized in previous studies 4 , 24 . As well as the uncertainties assessed in Fig. 1 , these conclusions are robust to structural choices, such as the timescale with which changes in the moderating variables of the empirical models are estimated (Supplementary Figs. 10 and 11 ), as well as the order in which one accounts for the intertemporal and international components of currency comparison (Supplementary Fig. 12 ; see Methods for further details).

Damages from variability and extremes

Committed damages primarily arise through changes in average temperature (Fig. 2 ). This reflects the fact that projected changes in average temperature are larger than those in other climate variables when expressed as a function of their historical interannual variability (Extended Data Fig. 4 ). Because the historical variability is that on which the empirical models are estimated, larger projected changes in comparison with this variability probably lead to larger future impacts in a purely statistical sense. From a mechanistic perspective, one may plausibly interpret this result as implying that future changes in average temperature are the most unprecedented from the perspective of the historical fluctuations to which the economy is accustomed and therefore will cause the most damage. This insight may prove useful in terms of guiding adaptation measures to the sources of greatest damage.

Estimates of the median projected reduction in sub-national income per capita across emission scenarios (SSP2-RCP2.6 and SSP2-RCP8.5) as well as climate model, empirical model and model parameter uncertainty in the year in which climate damages diverge at the 5% level (2049, as identified in Fig. 1 ). a , Impacts arising from all climate variables. b – f , Impacts arising separately from changes in annual mean temperature ( b ), daily temperature variability ( c ), total annual precipitation ( d ), the annual number of wet days (>1 mm) ( e ) and extreme daily rainfall ( f ) (see Methods for further definitions). Data on national administrative boundaries are obtained from the GADM database version 3.6 and are freely available for academic use ( https://gadm.org/ ).

Nevertheless, future damages based on empirical models that consider changes in annual average temperature only and exclude the other climate variables constitute income reductions of only 13% in 2049 (Extended Data Fig. 5a , likely range 5–21%). This suggests that accounting for the other components of the distribution of temperature and precipitation raises net damages by nearly 50%. This increase arises through the further damages that these climatic components cause, but also because their inclusion reveals a stronger negative economic response to average temperatures (Extended Data Fig. 5b ). The latter finding is consistent with our Monte Carlo simulations, which suggest that the magnitude of the effect of average temperature on economic growth is underestimated unless accounting for the impacts of other correlated climate variables (Supplementary Fig. 7 ).

In terms of the relative contributions of the different climatic components to overall damages, we find that accounting for daily temperature variability causes the largest increase in overall damages relative to empirical frameworks that only consider changes in annual average temperature (4.9 percentage points, likely range 2.4–8.7 percentage points, equivalent to approximately 10 trillion international dollars). Accounting for precipitation causes smaller increases in overall damages, which are—nevertheless—equivalent to approximately 1.2 trillion international dollars: 0.01 percentage points (−0.37–0.33 percentage points), 0.34 percentage points (0.07–0.90 percentage points) and 0.36 percentage points (0.13–0.65 percentage points) from total annual precipitation, the number of wet days and extreme daily precipitation, respectively. Moreover, climate models seem to underestimate future changes in temperature variability 25 and extreme precipitation 26 , 27 in response to anthropogenic forcing as compared with that observed historically, suggesting that the true impacts from these variables may be larger.

The distribution of committed damages

The spatial distribution of committed damages (Fig. 2a ) reflects a complex interplay between the patterns of future change in several climatic components and those of historical economic vulnerability to changes in those variables. Damages resulting from increasing annual mean temperature (Fig. 2b ) are negative almost everywhere globally, and larger at lower latitudes in regions in which temperatures are already higher and economic vulnerability to temperature increases is greatest (see the response heterogeneity to mean temperature embodied in Extended Data Fig. 1a ). This occurs despite the amplified warming projected at higher latitudes 28 , suggesting that regional heterogeneity in economic vulnerability to temperature changes outweighs heterogeneity in the magnitude of future warming (Supplementary Fig. 13a ). Economic damages owing to daily temperature variability (Fig. 2c ) exhibit a strong latitudinal polarisation, primarily reflecting the physical response of daily variability to greenhouse forcing in which increases in variability across lower latitudes (and Europe) contrast decreases at high latitudes 25 (Supplementary Fig. 13b ). These two temperature terms are the dominant determinants of the pattern of overall damages (Fig. 2a ), which exhibits a strong polarity with damages across most of the globe except at the highest northern latitudes. Future changes in total annual precipitation mainly bring economic benefits except in regions of drying, such as the Mediterranean and central South America (Fig. 2d and Supplementary Fig. 13c ), but these benefits are opposed by changes in the number of wet days, which produce damages with a similar pattern of opposite sign (Fig. 2e and Supplementary Fig. 13d ). By contrast, changes in extreme daily rainfall produce damages in all regions, reflecting the intensification of daily rainfall extremes over global land areas 29 , 30 (Fig. 2f and Supplementary Fig. 13e ).

The spatial distribution of committed damages implies considerable injustice along two dimensions: culpability for the historical emissions that have caused climate change and pre-existing levels of socio-economic welfare. Spearman’s rank correlations indicate that committed damages are significantly larger in countries with smaller historical cumulative emissions, as well as in regions with lower current income per capita (Fig. 3 ). This implies that those countries that will suffer the most from the damages already committed are those that are least responsible for climate change and which also have the least resources to adapt to it.

Estimates of the median projected change in national income per capita across emission scenarios (RCP2.6 and RCP8.5) as well as climate model, empirical model and model parameter uncertainty in the year in which climate damages diverge at the 5% level (2049, as identified in Fig. 1 ) are plotted against cumulative national emissions per capita in 2020 (from the Global Carbon Project) and coloured by national income per capita in 2020 (from the World Bank) in a and vice versa in b . In each panel, the size of each scatter point is weighted by the national population in 2020 (from the World Bank). Inset numbers indicate the Spearman’s rank correlation ρ and P -values for a hypothesis test whose null hypothesis is of no correlation, as well as the Spearman’s rank correlation weighted by national population.

To further quantify this heterogeneity, we assess the difference in committed damages between the upper and lower quartiles of regions when ranked by present income levels and historical cumulative emissions (using a population weighting to both define the quartiles and estimate the group averages). On average, the quartile of countries with lower income are committed to an income loss that is 8.9 percentage points (or 61%) greater than the upper quartile (Extended Data Fig. 6 ), with a likely range of 3.8–14.7 percentage points across the uncertainty sampling of our damage projections (following the likelihood classification adopted by the IPCC). Similarly, the quartile of countries with lower historical cumulative emissions are committed to an income loss that is 6.9 percentage points (or 40%) greater than the upper quartile, with a likely range of 0.27–12 percentage points. These patterns reemphasize the prevalence of injustice in climate impacts 31 , 32 , 33 in the context of the damages to which the world is already committed by historical emissions and socio-economic inertia.

Contextualizing the magnitude of damages

The magnitude of projected economic damages exceeds previous literature estimates 2 , 3 , arising from several developments made on previous approaches. Our estimates are larger than those of ref. 2 (see first row of Extended Data Table 3 ), primarily because of the facts that sub-national estimates typically show a steeper temperature response (see also refs. 3 , 34 ) and that accounting for other climatic components raises damage estimates (Extended Data Fig. 5 ). However, we note that our empirical approach using first-differenced climate variables is conservative compared with that of ref. 2 in regard to the persistence of climate impacts on growth (see introduction and Methods section ‘Empirical model specification: fixed-effects distributed lag models’), an important determinant of the magnitude of long-term damages 19 , 21 . Using a similar empirical specification to ref. 2 , which assumes infinite persistence while maintaining the rest of our approach (sub-national data and further climate variables), produces considerably larger damages (purple curve of Extended Data Fig. 3 ). Compared with studies that do take the first difference of climate variables 3 , 35 , our estimates are also larger (see second and third rows of Extended Data Table 3 ). The inclusion of further climate variables (Extended Data Fig. 5 ) and a sufficient number of lags to more adequately capture the extent of impact persistence (Extended Data Figs. 1 and 2 ) are the main sources of this difference, as is the use of specifications that capture nonlinearities in the temperature response when compared with ref. 35 . In summary, our estimates develop on previous studies by incorporating the latest data and empirical insights 7 , 8 , as well as in providing a robust empirical lower bound on the persistence of impacts on economic growth, which constitutes a middle ground between the extremes of the growth-versus-levels debate 19 , 21 (Extended Data Fig. 3 ).

Compared with the fraction of variance explained by the empirical models historically (<5%), the projection of reductions in income of 19% may seem large. This arises owing to the fact that projected changes in climatic conditions are much larger than those that were experienced historically, particularly for changes in average temperature (Extended Data Fig. 4 ). As such, any assessment of future climate-change impacts necessarily requires an extrapolation outside the range of the historical data on which the empirical impact models were evaluated. Nevertheless, these models constitute the most state-of-the-art methods for inference of plausibly causal climate impacts based on observed data. Moreover, we take explicit steps to limit out-of-sample extrapolation by capping the moderating variables of the interaction terms at the 95th percentile of the historical distribution (see Methods ). This avoids extrapolating the marginal effects outside what was observed historically. Given the nonlinear response of economic output to annual mean temperature (Extended Data Fig. 1 and Extended Data Table 2 ), this is a conservative choice that limits the magnitude of damages that we project. Furthermore, back-of-the-envelope calculations indicate that the projected damages are consistent with the magnitude and patterns of historical economic development (see Supplementary Discussion Section 5 ).

Missing impacts and spatial spillovers

Despite assessing several climatic components from which economic impacts have recently been identified 3 , 7 , 8 , this assessment of aggregate climate damages should not be considered comprehensive. Important channels such as impacts from heatwaves 31 , sea-level rise 36 , tropical cyclones 37 and tipping points 38 , 39 , as well as non-market damages such as those to ecosystems 40 and human health 41 , are not considered in these estimates. Sea-level rise is unlikely to be feasibly incorporated into empirical assessments such as this because historical sea-level variability is mostly small. Non-market damages are inherently intractable within our estimates of impacts on aggregate monetary output and estimates of these impacts could arguably be considered as extra to those identified here. Recent empirical work suggests that accounting for these channels would probably raise estimates of these committed damages, with larger damages continuing to arise in the global south 31 , 36 , 37 , 38 , 39 , 40 , 41 , 42 .

Moreover, our main empirical analysis does not explicitly evaluate the potential for impacts in local regions to produce effects that ‘spill over’ into other regions. Such effects may further mitigate or amplify the impacts we estimate, for example, if companies relocate production from one affected region to another or if impacts propagate along supply chains. The current literature indicates that trade plays a substantial role in propagating spillover effects 43 , 44 , making their assessment at the sub-national level challenging without available data on sub-national trade dependencies. Studies accounting for only spatially adjacent neighbours indicate that negative impacts in one region induce further negative impacts in neighbouring regions 45 , 46 , 47 , 48 , suggesting that our projected damages are probably conservative by excluding these effects. In Supplementary Fig. 14 , we assess spillovers from neighbouring regions using a spatial-lag model. For simplicity, this analysis excludes temporal lags, focusing only on contemporaneous effects. The results show that accounting for spatial spillovers can amplify the overall magnitude, and also the heterogeneity, of impacts. Consistent with previous literature, this indicates that the overall magnitude (Fig. 1 ) and heterogeneity (Fig. 3 ) of damages that we project in our main specification may be conservative without explicitly accounting for spillovers. We note that further analysis that addresses both spatially and trade-connected spillovers, while also accounting for delayed impacts using temporal lags, would be necessary to adequately address this question fully. These approaches offer fruitful avenues for further research but are beyond the scope of this manuscript, which primarily aims to explore the impacts of different climate conditions and their persistence.

Policy implications

We find that the economic damages resulting from climate change until 2049 are those to which the world economy is already committed and that these greatly outweigh the costs required to mitigate emissions in line with the 2 °C target of the Paris Climate Agreement (Fig. 1 ). This assessment is complementary to formal analyses of the net costs and benefits associated with moving from one emission path to another, which typically find that net benefits of mitigation only emerge in the second half of the century 5 . Our simple comparison of the magnitude of damages and mitigation costs makes clear that this is primarily because damages are indistinguishable across emissions scenarios—that is, committed—until mid-century (Fig. 1 ) and that they are actually already much larger than mitigation costs. For simplicity, and owing to the availability of data, we compare damages to mitigation costs at the global level. Regional estimates of mitigation costs may shed further light on the national incentives for mitigation to which our results already hint, of relevance for international climate policy. Although these damages are committed from a mitigation perspective, adaptation may provide an opportunity to reduce them. Moreover, the strong divergence of damages after mid-century reemphasizes the clear benefits of mitigation from a purely economic perspective, as highlighted in previous studies 1 , 4 , 6 , 24 .

Historical climate data

Historical daily 2-m temperature and precipitation totals (in mm) are obtained for the period 1979–2019 from the W5E5 database. The W5E5 dataset comes from ERA-5, a state-of-the-art reanalysis of historical observations, but has been bias-adjusted by applying version 2.0 of the WATCH Forcing Data to ERA-5 reanalysis data and precipitation data from version 2.3 of the Global Precipitation Climatology Project to better reflect ground-based measurements 49 , 50 , 51 . We obtain these data on a 0.5° × 0.5° grid from the Inter-Sectoral Impact Model Intercomparison Project (ISIMIP) database. Notably, these historical data have been used to bias-adjust future climate projections from CMIP-6 (see the following section), ensuring consistency between the distribution of historical daily weather on which our empirical models were estimated and the climate projections used to estimate future damages. These data are publicly available from the ISIMIP database. See refs. 7 , 8 for robustness tests of the empirical models to the choice of climate data reanalysis products.

Future climate data

Daily 2-m temperature and precipitation totals (in mm) are taken from 21 climate models participating in CMIP-6 under a high (RCP8.5) and a low (RCP2.6) greenhouse gas emission scenario from 2015 to 2100. The data have been bias-adjusted and statistically downscaled to a common half-degree grid to reflect the historical distribution of daily temperature and precipitation of the W5E5 dataset using the trend-preserving method developed by the ISIMIP 50 , 52 . As such, the climate model data reproduce observed climatological patterns exceptionally well (Supplementary Table 5 ). Gridded data are publicly available from the ISIMIP database.

Historical economic data

Historical economic data come from the DOSE database of sub-national economic output 53 . We use a recent revision to the DOSE dataset that provides data across 83 countries, 1,660 sub-national regions with varying temporal coverage from 1960 to 2019. Sub-national units constitute the first administrative division below national, for example, states for the USA and provinces for China. Data come from measures of gross regional product per capita (GRPpc) or income per capita in local currencies, reflecting the values reported in national statistical agencies, yearbooks and, in some cases, academic literature. We follow previous literature 3 , 7 , 8 , 54 and assess real sub-national output per capita by first converting values from local currencies to US dollars to account for diverging national inflationary tendencies and then account for US inflation using a US deflator. Alternatively, one might first account for national inflation and then convert between currencies. Supplementary Fig. 12 demonstrates that our conclusions are consistent when accounting for price changes in the reversed order, although the magnitude of estimated damages varies. See the documentation of the DOSE dataset for further discussion of these choices. Conversions between currencies are conducted using exchange rates from the FRED database of the Federal Reserve Bank of St. Louis 55 and the national deflators from the World Bank 56 .

Future socio-economic data

Baseline gridded gross domestic product (GDP) and population data for the period 2015–2100 are taken from the middle-of-the-road scenario SSP2 (ref. 15 ). Population data have been downscaled to a half-degree grid by the ISIMIP following the methodologies of refs. 57 , 58 , which we then aggregate to the sub-national level of our economic data using the spatial aggregation procedure described below. Because current methodologies for downscaling the GDP of the SSPs use downscaled population to do so, per-capita estimates of GDP with a realistic distribution at the sub-national level are not readily available for the SSPs. We therefore use national-level GDP per capita (GDPpc) projections for all sub-national regions of a given country, assuming homogeneity within countries in terms of baseline GDPpc. Here we use projections that have been updated to account for the impact of the COVID-19 pandemic on the trajectory of future income, while remaining consistent with the long-term development of the SSPs 59 . The choice of baseline SSP alters the magnitude of projected climate damages in monetary terms, but when assessed in terms of percentage change from the baseline, the choice of socio-economic scenario is inconsequential. Gridded SSP population data and national-level GDPpc data are publicly available from the ISIMIP database. Sub-national estimates as used in this study are available in the code and data replication files.

Climate variables

Following recent literature 3 , 7 , 8 , we calculate an array of climate variables for which substantial impacts on macroeconomic output have been identified empirically, supported by further evidence at the micro level for plausible underlying mechanisms. See refs. 7 , 8 for an extensive motivation for the use of these particular climate variables and for detailed empirical tests on the nature and robustness of their effects on economic output. To summarize, these studies have found evidence for independent impacts on economic growth rates from annual average temperature, daily temperature variability, total annual precipitation, the annual number of wet days and extreme daily rainfall. Assessments of daily temperature variability were motivated by evidence of impacts on agricultural output and human health, as well as macroeconomic literature on the impacts of volatility on growth when manifest in different dimensions, such as government spending, exchange rates and even output itself 7 . Assessments of precipitation impacts were motivated by evidence of impacts on agricultural productivity, metropolitan labour outcomes and conflict, as well as damages caused by flash flooding 8 . See Extended Data Table 1 for detailed references to empirical studies of these physical mechanisms. Marked impacts of daily temperature variability, total annual precipitation, the number of wet days and extreme daily rainfall on macroeconomic output were identified robustly across different climate datasets, spatial aggregation schemes, specifications of regional time trends and error-clustering approaches. They were also found to be robust to the consideration of temperature extremes 7 , 8 . Furthermore, these climate variables were identified as having independent effects on economic output 7 , 8 , which we further explain here using Monte Carlo simulations to demonstrate the robustness of the results to concerns of imperfect multicollinearity between climate variables (Supplementary Methods Section 2 ), as well as by using information criteria (Supplementary Table 1 ) to demonstrate that including several lagged climate variables provides a preferable trade-off between optimally describing the data and limiting the possibility of overfitting.

We calculate these variables from the distribution of daily, d , temperature, T x , d , and precipitation, P x , d , at the grid-cell, x , level for both the historical and future climate data. As well as annual mean temperature, ${\bar{T}}_{x,y}$ , and annual total precipitation, P x , y , we calculate annual, y , measures of daily temperature variability, ${\widetilde{T}}_{x,y}$ :

the number of wet days, Pwd x , y :

and extreme daily rainfall:

in which T x , d , m , y is the grid-cell-specific daily temperature in month m and year y , ${\bar{T}}_{x,m,{y}}$ is the year and grid-cell-specific monthly, m , mean temperature, D m and D y the number of days in a given month m or year y , respectively, H the Heaviside step function, 1 mm the threshold used to define wet days and P 99.9 x is the 99.9th percentile of historical (1979–2019) daily precipitation at the grid-cell level. Units of the climate measures are degrees Celsius for annual mean temperature and daily temperature variability, millimetres for total annual precipitation and extreme daily precipitation, and simply the number of days for the annual number of wet days.

We also calculated weighted standard deviations of monthly rainfall totals as also used in ref. 8 but do not include them in our projections as we find that, when accounting for delayed effects, their effect becomes statistically indistinct and is better captured by changes in total annual rainfall.

Spatial aggregation

We aggregate grid-cell-level historical and future climate measures, as well as grid-cell-level future GDPpc and population, to the level of the first administrative unit below national level of the GADM database, using an area-weighting algorithm that estimates the portion of each grid cell falling within an administrative boundary. We use this as our baseline specification following previous findings that the effect of area or population weighting at the sub-national level is negligible 7 , 8 .

Empirical model specification: fixed-effects distributed lag models

Following a wide range of climate econometric literature 16 , 60 , we use panel regression models with a selection of fixed effects and time trends to isolate plausibly exogenous variation with which to maximize confidence in a causal interpretation of the effects of climate on economic growth rates. The use of region fixed effects, μ r , accounts for unobserved time-invariant differences between regions, such as prevailing climatic norms and growth rates owing to historical and geopolitical factors. The use of yearly fixed effects, η y , accounts for regionally invariant annual shocks to the global climate or economy such as the El Niño–Southern Oscillation or global recessions. In our baseline specification, we also include region-specific linear time trends, k r y , to exclude the possibility of spurious correlations resulting from common slow-moving trends in climate and growth.

The persistence of climate impacts on economic growth rates is a key determinant of the long-term magnitude of damages. Methods for inferring the extent of persistence in impacts on growth rates have typically used lagged climate variables to evaluate the presence of delayed effects or catch-up dynamics 2 , 18 . For example, consider starting from a model in which a climate condition, C r , y , (for example, annual mean temperature) affects the growth rate, Δlgrp r , y (the first difference of the logarithm of gross regional product) of region r in year y :

which we refer to as a ‘pure growth effects’ model in the main text. Typically, further lags are included,

and the cumulative effect of all lagged terms is evaluated to assess the extent to which climate impacts on growth rates persist. Following ref. 18 , in the case that,

the implication is that impacts on the growth rate persist up to NL years after the initial shock (possibly to a weaker or a stronger extent), whereas if

then the initial impact on the growth rate is recovered after NL years and the effect is only one on the level of output. However, we note that such approaches are limited by the fact that, when including an insufficient number of lags to detect a recovery of the growth rates, one may find equation ( 6 ) to be satisfied and incorrectly assume that a change in climatic conditions affects the growth rate indefinitely. In practice, given a limited record of historical data, including too few lags to confidently conclude in an infinitely persistent impact on the growth rate is likely, particularly over the long timescales over which future climate damages are often projected 2 , 24 . To avoid this issue, we instead begin our analysis with a model for which the level of output, lgrp r , y , depends on the level of a climate variable, C r , y :

Given the non-stationarity of the level of output, we follow the literature 19 and estimate such an equation in first-differenced form as,

which we refer to as a model of ‘pure level effects’ in the main text. This model constitutes a baseline specification in which a permanent change in the climate variable produces an instantaneous impact on the growth rate and a permanent effect only on the level of output. By including lagged variables in this specification,

we are able to test whether the impacts on the growth rate persist any further than instantaneously by evaluating whether α L > 0 are statistically significantly different from zero. Even though this framework is also limited by the possibility of including too few lags, the choice of a baseline model specification in which impacts on the growth rate do not persist means that, in the case of including too few lags, the framework reverts to the baseline specification of level effects. As such, this framework is conservative with respect to the persistence of impacts and the magnitude of future damages. It naturally avoids assumptions of infinite persistence and we are able to interpret any persistence that we identify with equation ( 9 ) as a lower bound on the extent of climate impact persistence on growth rates. See the main text for further discussion of this specification choice, in particular about its conservative nature compared with previous literature estimates, such as refs. 2 , 18 .

We allow the response to climatic changes to vary across regions, using interactions of the climate variables with historical average (1979–2019) climatic conditions reflecting heterogenous effects identified in previous work 7 , 8 . Following this previous work, the moderating variables of these interaction terms constitute the historical average of either the variable itself or of the seasonal temperature difference, ${\hat{T}}_{r}$ , or annual mean temperature, ${\bar{T}}_{r}$ , in the case of daily temperature variability 7 and extreme daily rainfall, respectively 8 .

The resulting regression equation with N and M lagged variables, respectively, reads:

in which Δlgrp r , y is the annual, regional GRPpc growth rate, measured as the first difference of the logarithm of real GRPpc, following previous work 2 , 3 , 7 , 8 , 18 , 19 . Fixed-effects regressions were run using the fixest package in R (ref. 61 ).

Estimates of the coefficients of interest α i , L are shown in Extended Data Fig. 1 for N = M = 10 lags and for our preferred choice of the number of lags in Supplementary Figs. 1 – 3 . In Extended Data Fig. 1 , errors are shown clustered at the regional level, but for the construction of damage projections, we block-bootstrap the regressions by region 1,000 times to provide a range of parameter estimates with which to sample the projection uncertainty (following refs. 2 , 31 ).

Spatial-lag model

In Supplementary Fig. 14 , we present the results from a spatial-lag model that explores the potential for climate impacts to ‘spill over’ into spatially neighbouring regions. We measure the distance between centroids of each pair of sub-national regions and construct spatial lags that take the average of the first-differenced climate variables and their interaction terms over neighbouring regions that are at distances of 0–500, 500–1,000, 1,000–1,500 and 1,500–2000 km (spatial lags, ‘SL’, 1 to 4). For simplicity, we then assess a spatial-lag model without temporal lags to assess spatial spillovers of contemporaneous climate impacts. This model takes the form:

in which SL indicates the spatial lag of each climate variable and interaction term. In Supplementary Fig. 14 , we plot the cumulative marginal effect of each climate variable at different baseline climate conditions by summing the coefficients for each climate variable and interaction term, for example, for average temperature impacts as:

These cumulative marginal effects can be regarded as the overall spatially dependent impact to an individual region given a one-unit shock to a climate variable in that region and all neighbouring regions at a given value of the moderating variable of the interaction term.

Constructing projections of economic damage from future climate change

We construct projections of future climate damages by applying the coefficients estimated in equation ( 10 ) and shown in Supplementary Tables 2 – 4 (when including only lags with statistically significant effects in specifications that limit overfitting; see Supplementary Methods Section 1 ) to projections of future climate change from the CMIP-6 models. Year-on-year changes in each primary climate variable of interest are calculated to reflect the year-to-year variations used in the empirical models. 30-year moving averages of the moderating variables of the interaction terms are calculated to reflect the long-term average of climatic conditions that were used for the moderating variables in the empirical models. By using moving averages in the projections, we account for the changing vulnerability to climate shocks based on the evolving long-term conditions (Supplementary Figs. 10 and 11 show that the results are robust to the precise choice of the window of this moving average). Although these climate variables are not differenced, the fact that the bias-adjusted climate models reproduce observed climatological patterns across regions for these moderating variables very accurately (Supplementary Table 6 ) with limited spread across models (<3%) precludes the possibility that any considerable bias or uncertainty is introduced by this methodological choice. However, we impose caps on these moderating variables at the 95th percentile at which they were observed in the historical data to prevent extrapolation of the marginal effects outside the range in which the regressions were estimated. This is a conservative choice that limits the magnitude of our damage projections.

Time series of primary climate variables and moderating climate variables are then combined with estimates of the empirical model parameters to evaluate the regression coefficients in equation ( 10 ), producing a time series of annual GRPpc growth-rate reductions for a given emission scenario, climate model and set of empirical model parameters. The resulting time series of growth-rate impacts reflects those occurring owing to future climate change. By contrast, a future scenario with no climate change would be one in which climate variables do not change (other than with random year-to-year fluctuations) and hence the time-averaged evaluation of equation ( 10 ) would be zero. Our approach therefore implicitly compares the future climate-change scenario to this no-climate-change baseline scenario.

The time series of growth-rate impacts owing to future climate change in region r and year y , δ r , y , are then added to the future baseline growth rates, π r , y (in log-diff form), obtained from the SSP2 scenario to yield trajectories of damaged GRPpc growth rates, ρ r , y . These trajectories are aggregated over time to estimate the future trajectory of GRPpc with future climate impacts:

in which GRPpc r , y =2020 is the initial log level of GRPpc. We begin damage estimates in 2020 to reflect the damages occurring since the end of the period for which we estimate the empirical models (1979–2019) and to match the timing of mitigation-cost estimates from most IAMs (see below).

For each emission scenario, this procedure is repeated 1,000 times while randomly sampling from the selection of climate models, the selection of empirical models with different numbers of lags (shown in Supplementary Figs. 1 – 3 and Supplementary Tables 2 – 4 ) and bootstrapped estimates of the regression parameters. The result is an ensemble of future GRPpc trajectories that reflect uncertainty from both physical climate change and the structural and sampling uncertainty of the empirical models.

Estimates of mitigation costs

We obtain IPCC estimates of the aggregate costs of emission mitigation from the AR6 Scenario Explorer and Database hosted by IIASA 23 . Specifically, we search the AR6 Scenarios Database World v1.1 for IAMs that provided estimates of global GDP and population under both a SSP2 baseline and a SSP2-RCP2.6 scenario to maintain consistency with the socio-economic and emission scenarios of the climate damage projections. We find five IAMs that provide data for these scenarios, namely, MESSAGE-GLOBIOM 1.0, REMIND-MAgPIE 1.5, AIM/GCE 2.0, GCAM 4.2 and WITCH-GLOBIOM 3.1. Of these five IAMs, we use the results only from the first three that passed the IPCC vetting procedure for reproducing historical emission and climate trajectories. We then estimate global mitigation costs as the percentage difference in global per capita GDP between the SSP2 baseline and the SSP2-RCP2.6 emission scenario. In the case of one of these IAMs, estimates of mitigation costs begin in 2020, whereas in the case of two others, mitigation costs begin in 2010. The mitigation cost estimates before 2020 in these two IAMs are mostly negligible, and our choice to begin comparison with damage estimates in 2020 is conservative with respect to the relative weight of climate damages compared with mitigation costs for these two IAMs.

Data availability

Data on economic production and ERA-5 climate data are publicly available at https://doi.org/10.5281/zenodo.4681306 (ref. 62 ) and https://www.ecmwf.int/en/forecasts/datasets/reanalysis-datasets/era5 , respectively. Data on mitigation costs are publicly available at https://data.ene.iiasa.ac.at/ar6/#/downloads . Processed climate and economic data, as well as all other necessary data for reproduction of the results, are available at the public repository https://doi.org/10.5281/zenodo.10562951 (ref. 63 ).

Code availability

All code necessary for reproduction of the results is available at the public repository https://doi.org/10.5281/zenodo.10562951 (ref. 63 ).

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Acknowledgements

We gratefully acknowledge financing from the Volkswagen Foundation and the Deutsche Gesellschaft für Internationale Zusammenarbeit (GIZ) GmbH on behalf of the Government of the Federal Republic of Germany and Federal Ministry for Economic Cooperation and Development (BMZ).

Open access funding provided by Potsdam-Institut für Klimafolgenforschung (PIK) e.V.

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Extended data figures and tables

Extended data fig. 1 constraining the persistence of historical climate impacts on economic growth rates..

The results of a panel-based fixed-effects distributed lag model for the effects of annual mean temperature ( a ), daily temperature variability ( b ), total annual precipitation ( c ), the number of wet days ( d ) and extreme daily precipitation ( e ) on sub-national economic growth rates. Point estimates show the effects of a 1 °C or one standard deviation increase (for temperature and precipitation variables, respectively) at the lower quartile, median and upper quartile of the relevant moderating variable (green, orange and purple, respectively) at different lagged periods after the initial shock (note that these are not cumulative effects). Climate variables are used in their first-differenced form (see main text for discussion) and the moderating climate variables are the annual mean temperature, seasonal temperature difference, total annual precipitation, number of wet days and annual mean temperature, respectively, in panels a – e (see Methods for further discussion). Error bars show the 95% confidence intervals having clustered standard errors by region. The within-region R 2 , Bayesian and Akaike information criteria for the model are shown at the top of the figure. This figure shows results with ten lags for each variable to demonstrate the observed levels of persistence, but our preferred specifications remove later lags based on the statistical significance of terms shown above and the information criteria shown in Extended Data Fig. 2 . The resulting models without later lags are shown in Supplementary Figs. 1 – 3 .

Extended Data Fig. 2 Incremental lag-selection procedure using information criteria and within-region R 2 .

Starting from a panel-based fixed-effects distributed lag model estimating the effects of climate on economic growth using the real historical data (as in equation ( 4 )) with ten lags for all climate variables (as shown in Extended Data Fig. 1 ), lags are incrementally removed for one climate variable at a time. The resulting Bayesian and Akaike information criteria are shown in a – e and f – j , respectively, and the within-region R 2 and number of observations in k – o and p – t , respectively. Different rows show the results when removing lags from different climate variables, ordered from top to bottom as annual mean temperature, daily temperature variability, total annual precipitation, the number of wet days and extreme annual precipitation. Information criteria show minima at approximately four lags for precipitation variables and ten to eight for temperature variables, indicating that including these numbers of lags does not lead to overfitting. See Supplementary Table 1 for an assessment using information criteria to determine whether including further climate variables causes overfitting.

Extended Data Fig. 3 Damages in our preferred specification that provides a robust lower bound on the persistence of climate impacts on economic growth versus damages in specifications of pure growth or pure level effects.

Estimates of future damages as shown in Fig. 1 but under the emission scenario RCP8.5 for three separate empirical specifications: in orange our preferred specification, which provides an empirical lower bound on the persistence of climate impacts on economic growth rates while avoiding assumptions of infinite persistence (see main text for further discussion); in purple a specification of ‘pure growth effects’ in which the first difference of climate variables is not taken and no lagged climate variables are included (the baseline specification of ref. 2 ); and in pink a specification of ‘pure level effects’ in which the first difference of climate variables is taken but no lagged terms are included.

Extended Data Fig. 4 Climate changes in different variables as a function of historical interannual variability.

Changes in each climate variable of interest from 1979–2019 to 2035–2065 under the high-emission scenario SSP5-RCP8.5, expressed as a percentage of the historical variability of each measure. Historical variability is estimated as the standard deviation of each detrended climate variable over the period 1979–2019 during which the empirical models were identified (detrending is appropriate because of the inclusion of region-specific linear time trends in the empirical models). See Supplementary Fig. 13 for changes expressed in standard units. Data on national administrative boundaries are obtained from the GADM database version 3.6 and are freely available for academic use ( https://gadm.org/ ).

Extended Data Fig. 5 Contribution of different climate variables to overall committed damages.

a , Climate damages in 2049 when using empirical models that account for all climate variables, changes in annual mean temperature only or changes in both annual mean temperature and one other climate variable (daily temperature variability, total annual precipitation, the number of wet days and extreme daily precipitation, respectively). b , The cumulative marginal effects of an increase in annual mean temperature of 1 °C, at different baseline temperatures, estimated from empirical models including all climate variables or annual mean temperature only. Estimates and uncertainty bars represent the median and 95% confidence intervals obtained from 1,000 block-bootstrap resamples from each of three different empirical models using eight, nine or ten lags of temperature terms.

Extended Data Fig. 6 The difference in committed damages between the upper and lower quartiles of countries when ranked by GDP and cumulative historical emissions.

Quartiles are defined using a population weighting, as are the average committed damages across each quartile group. The violin plots indicate the distribution of differences between quartiles across the two extreme emission scenarios (RCP2.6 and RCP8.5) and the uncertainty sampling procedure outlined in Methods , which accounts for uncertainty arising from the choice of lags in the empirical models, uncertainty in the empirical model parameter estimates, as well as the climate model projections. Bars indicate the median, as well as the 10th and 90th percentiles and upper and lower sixths of the distribution reflecting the very likely and likely ranges following the likelihood classification adopted by the IPCC.

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Kotz, M., Levermann, A. & Wenz, L. The economic commitment of climate change. Nature 628 , 551–557 (2024). https://doi.org/10.1038/s41586-024-07219-0

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Facility for Rare Isotope Beams

At michigan state university, frib researchers lead team to merge nuclear physics experiments and astronomical observations to advance equation-of-state research, world-class particle-accelerator facilities and recent advances in neutron-star observation give physicists a new toolkit for describing nuclear interactions at a wide range of densities..

For most stars, neutron stars and black holes are their final resting places. When a supergiant star runs out of fuel, it expands and then rapidly collapses on itself. This act creates a neutron star—an object denser than our sun crammed into a space 13 to 18 miles wide. In such a heavily condensed stellar environment, most electrons combine with protons to make neutrons, resulting in a dense ball of matter consisting mainly of neutrons. Researchers try to understand the forces that control this process by creating dense matter in the laboratory through colliding neutron-rich nuclei and taking detailed measurements.

A research team—led by William Lynch and Betty Tsang at FRIB—is focused on learning about neutrons in dense environments. Lynch, Tsang, and their collaborators used 20 years of experimental data from accelerator facilities and neutron-star observations to understand how particles interact in nuclear matter under a wide range of densities and pressures. The team wanted to determine how the ratio of neutrons to protons influences nuclear forces in a system. The team recently published its findings in Nature Astronomy .

“In nuclear physics, we are often confined to studying small systems, but we know exactly what particles are in our nuclear systems. Stars provide us an unbelievable opportunity, because they are large systems where nuclear physics plays a vital role, but we do not know for sure what particles are in their interiors,” said Lynch, professor of nuclear physics at FRIB and in the Michigan State University (MSU) Department of Physics and Astronomy. “They are interesting because the density varies greatly within such large systems. Nuclear forces play a dominant role within them, yet we know comparatively little about that role.”

When a star with a mass that is 20-30 times that of the sun exhausts its fuel, it cools, collapses, and explodes in a supernova. After this explosion, only the matter in the deepest part of the star’s interior coalesces to form a neutron star. This neutron star has no fuel to burn and over time, it radiates its remaining heat into the surrounding space. Scientists expect that matter in the outer core of a cold neutron star is roughly similar to the matter in atomic nuclei but with three differences: neutron stars are much larger, they are denser in their interiors, and a larger fraction of their nucleons are neutrons. Deep within the inner core of a neutron star, the composition of neutron star matter remains a mystery.

“If experiments could provide more guidance about the forces that act in their interiors, we could make better predictions of their interior composition and of phase transitions within them. Neutron stars present a great research opportunity to combine these disciplines,” said Lynch.

Accelerator facilities like FRIB help physicists study how subatomic particles interact under exotic conditions that are more common in neutron stars. When researchers compare these experiments to neutron-star observations, they can calculate the equation of state (EOS) of particles interacting in low-temperature, dense environments. The EOS describes matter in specific conditions, and how its properties change with density. Solving EOS for a wide range of settings helps researchers understand the strong nuclear force’s effects within dense objects, like neutron stars, in the cosmos. It also helps us learn more about neutron stars as they cool.

“This is the first time that we pulled together such a wealth of experimental data to explain the equation of state under these conditions, and this is important,” said Tsang, professor of nuclear science at FRIB. “Previous efforts have used theory to explain the low-density and low-energy end of nuclear matter. We wanted to use all the data we had available to us from our previous experiences with accelerators to obtain a comprehensive equation of state.”

Researchers seeking the EOS often calculate it at higher temperatures or lower densities. They then draw conclusions for the system across a wider range of conditions. However, physicists have come to understand in recent years that an EOS obtained from an experiment is only relevant for a specific range of densities. As a result, the team needed to pull together data from a variety of accelerator experiments that used different measurements of colliding nuclei to replace those assumptions with data. “In this work, we asked two questions,” said Lynch. “For a given measurement, what density does that measurement probe? After that, we asked what that measurement tells us about the equation of state at that density.”

In its recent paper, the team combined its own experiments from accelerator facilities in the United States and Japan. It pulled together data from 12 different experimental constraints and three neutron-star observations. The researchers focused on determining the EOS for nuclear matter ranging from half to three times a nuclei’s saturation density—the density found at the core of all stable nuclei. By producing this comprehensive EOS, the team provided new benchmarks for the larger nuclear physics and astrophysics communities to more accurately model interactions of nuclear matter.

The team improved its measurements at intermediate densities that neutron star observations do not provide through experiments at the GSI Helmholtz Centre for Heavy Ion Research in Germany, the RIKEN Nishina Center for Accelerator-Based Science in Japan, and the National Superconducting Cyclotron Laboratory (FRIB’s predecessor). To enable key measurements discussed in this article, their experiments helped fund technical advances in data acquisition for active targets and time projection chambers that are being employed in many other experiments world-wide.

In running these experiments at FRIB, Tsang and Lynch can continue to interact with MSU students who help advance the research with their own input and innovation. MSU operates FRIB as a scientific user facility for the U.S. Department of Energy Office of Science (DOE-SC), supporting the mission of the DOE-SC Office of Nuclear Physics. FRIB is the only accelerator-based user facility on a university campus as one of 28 DOE-SC user facilities . Chun Yen Tsang, the first author on the Nature Astronomy paper, was a graduate student under Betty Tsang during this research and is now a researcher working jointly at Brookhaven National Laboratory and Kent State University.

“Projects like this one are essential for attracting the brightest students, which ultimately makes these discoveries possible, and provides a steady pipeline to the U.S. workforce in nuclear science,” Tsang said.

The proposed FRIB energy upgrade ( FRIB400 ), supported by the scientific user community in the 2023 Nuclear Science Advisory Committee Long Range Plan , will allow the team to probe at even higher densities in the years to come. FRIB400 will double the reach of FRIB along the neutron dripline into a region relevant for neutron-star crusts and to allow study of extreme, neutron-rich nuclei such as calcium-68.

Eric Gedenk is a freelance science writer.

Michigan State University operates the Facility for Rare Isotope Beams (FRIB) as a user facility for the U.S. Department of Energy Office of Science (DOE-SC), supporting the mission of the DOE-SC Office of Nuclear Physics. Hosting what is designed to be the most powerful heavy-ion accelerator, FRIB enables scientists to make discoveries about the properties of rare isotopes in order to better understand the physics of nuclei, nuclear astrophysics, fundamental interactions, and applications for society, including in medicine, homeland security, and industry.

The U.S. Department of Energy Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of today’s most pressing challenges. For more information, visit energy.gov/science.

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Here's a list of steps to keep in mind before publishing a research paper : Step 1: Identifying the Right Journal. Step 2: Preparing Step 3: Your Manuscript. Step 3: Conducting a Thorough Review. Step 4: Writing a Compelling Cover Letter. Step 5: Navigating the Peer Review Process. Step 6: Handling Rejections.
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How to Publish a Research Paper – Step by Step Guide

How to Publish a Research Paper

How to Choose Journal for Research Paper Publication

List of Journals for Research Paper Publications

List of Conferences for Research Paper Publications

How to Publish a Research Paper in Journal

How to Publish a Research Paper for Students

How to Publish a Research Paper for Free

Journals and Conferences for Free Research Paper publications

Importance of Research Paper Publication

Advantages of Research Paper Publication

About the author

Muhammad Hassan

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How to Write and Publish Your Research in a Journal

Choosing a Journal

Things You Should Know

Expert Q&A

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Understanding the Publishing Process

What’s happening with my paper? The publication process explained

Internal Checks on New Submissions

Peer Review

Revision Decision

Revised Submission Received

Subsequent Peer Review

Preliminary Acceptance

Formal Acceptance and Publication

How to Publish a Research Paper: A Step-by-Step Guide

Jordan Kruszynski

Understanding the Publishing Process

Step 1: Preparing Your Research Paper

Step 2: Finding the Right Journal

Step 3: Crafting a Strong Manuscript

Step 4: Navigating the Peer-Review Process

Step 5: Submitting Your Paper

Step 6: Dealing with Rejections and Revising Your Paper

Final Thoughts

Table of Contents

Behind the Scenes: What Does a Research Assistant Do?

How to Write a Research Paper Introduction: Hook, Line, and Sinker

Discover more from Audemic: Access any academic research via audio

How to Write and Publish a Research Paper in 7 Steps

1. Check Whether Your Research Is Publication-Ready

2. Choose An Article Type

3. Choose a Journal

4. Construct Your Paper

4.1 The Title

4.2 The Abstract

4.3 Keywords

4.4 Introduction

4.5 Methods

4.6 Results

4.7 Discussion

4.8 Conclusion

4.9 Acknowledgments and Ethical Statements

4.10 References

5. Decide the Order of Authors

6. Check and Double-Check

7. Submit Your Paper

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