teaching problem solving skills to high school students

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How Students Can Rethink Problem Solving

Finding, shaping, and solving problems puts high school students in charge of their learning and bolsters critical-thinking skills.

As an educator for over 20 years, I’ve heard a lot about critical thinking , problem-solving , and inquiry and how they foster student engagement. However, I’ve also seen students draw a blank when they’re given a problem to solve. This happens when the problem is too vast for them to develop a solution or they don’t think the situation is problematic.

As I’ve tried, failed, and tried again to engage my students in critical thinking, problem-solving, and inquiry, I’ve experienced greater engagement when I allow them to problem-find, problem-shape, and problem-solve. This shift in perspective has helped my students take direct ownership over their learning.

Encourage Students to Find the Problem

When students ask a question that prompts their curiosity, it motivates them to seek out an answer. This answer often highlights a problem.

For example, I gave my grade 11 students a list of topics to explore, and they signed up for a topic that they were interested in. From that, they had to develop a research question. This allowed them to narrow the topic down to what they were specifically curious about.

Developing a research question initiated the research process. Students launched into reading information from reliable sources including Britannica , Newsela , and EBSCOhost . Through the reading process, they were able to access information so that they could attempt to find an answer to their question.

The nature of a good question is that there isn’t an “answer.” Instead, there are a variety of answers. This allowed students to feel safe in sharing their answers because they couldn’t be “wrong.” If they had reliable, peer-reviewed academic research to support their answer, they were “right.”

Shaping a Problem Makes Overcoming It More Feasible

When students identify a problem, they’re compelled to do something about it; however, if the problem is too large, it can be overwhelming for them. When they’re overwhelmed, they might shut down and stop learning. For that reason, it’s important for them to shape the problem by taking on a piece they can handle.

To help guide students, provide a list of topics and allow them to choose one. In my experience, choosing their own topic prompts students’ curiosity—which drives them to persevere through a challenging task. Additionally, I have students maintain their scope at a school, regional, or national level. Keeping the focus away from an international scope allows them to filter down the number of results when they begin researching. Shaping the problem this way allowed students to address it in a manageable way.

Students Can Problem-Solve with Purpose

Once students identified a slice of a larger problem that they could manage, they started to read and think about it, collaborate together, and figure out how to solve it. To further support them in taking on a manageable piece of the problem, the parameters of the solution were that it had to be something they could implement immediately. For example, raising $3 million to build a shelter for those experiencing homelessness in the community isn’t something that students can do tomorrow. Focusing on a solution that could be implemented immediately made it easier for them to come up with viable options.

With the problem shaped down to a manageable piece, students were better able to come up with a solution that would have a big impact. This problem-solving process also invites ingenuity and innovation because it allows teens to critically look at their day-to-day lives and experiences to consider what actions they could take to make a difference in the world. It prompts them to look at their world through a different lens.

When the conditions for inquiry are created by allowing students to problem-find, problem-shape and problem-solve, it allows students to do the following:

Critically examine their world to identify problems that exist
Feel empowered because they realize that they can be part of a solution
Innovate by developing new solutions to old problems

Put it All Together to Promote Change

Here are two examples of what my grade 11 students came up with when tasked with examining the national news to problem-find, problem-shape, and problem-solve.

Topic: Indigenous Issues in Canada

Question: How are Indigenous peoples impacted by racism?

Problem-find: The continued racism against Indigenous peoples has led to the families of murdered women not attaining justice, Indigenous peoples not being able to gain employment, and Indigenous communities not being able to access basic necessities like healthcare and clean water.

Problem-shape: A lot of the issues that Indigenous peoples face require government intervention. What can high school teens do to combat these issues?

Problem-solve: Teens need to stop supporting professional sports teams that tokenize Indigenous peoples, and if they see a peer wearing something from such a sports team, we need to educate them about how the team’s logo perpetuates racism.

Topic: People With Disabilities in Canada

Question: What leads students with a hearing impairment to feel excluded?

Problem-find: Students with a hearing impairment struggle to engage with course texts like films and videos.

Problem-shape: A lot of the issues that students with a hearing impairment face in schools require teachers to take action. What can high school teens do to help their hearing-impaired peers feel included?

Problem-solve: When teens share a video on social media, they should turn the closed-captioning on, so that all students can consume the media being shared.

Once my students came up with solutions, they wanted to do something about it and use their voices to engage in global citizenship. This led them to create TikTok and Snapchat videos and Instagram posts that they shared and re-shared among their peer group.

The learning that students engaged in led to their wanting to teach others—which allowed a greater number of students to learn. This whole process engendered conversations about our world and helped them realize that they aren’t powerless; they can do things to initiate change in areas that they’re interested in and passionate about. It allowed them to use their voices to educate others and promote change.

Why Every Educator Needs to Teach Problem-Solving Skills

Strong problem-solving skills will help students be more resilient and will increase their academic and career success .

Want to learn more about how to measure and teach students’ higher-order skills, including problem solving, critical thinking, and written communication?

Problem-solving skills are essential in school, careers, and life.

Problem-solving skills are important for every student to master. They help individuals navigate everyday life and find solutions to complex issues and challenges. These skills are especially valuable in the workplace, where employees are often required to solve problems and make decisions quickly and effectively.

Problem-solving skills are also needed for students’ personal growth and development because they help individuals overcome obstacles and achieve their goals. By developing strong problem-solving skills, students can improve their overall quality of life and become more successful in their personal and professional endeavors.

teaching problem solving skills to high school students

Problem-Solving Skills Help Students…

develop resilience.

Problem-solving skills are an integral part of resilience and the ability to persevere through challenges and adversity. To effectively work through and solve a problem, students must be able to think critically and creatively. Critical and creative thinking help students approach a problem objectively, analyze its components, and determine different ways to go about finding a solution.

This process in turn helps students build self-efficacy . When students are able to analyze and solve a problem, this increases their confidence, and they begin to realize the power they have to advocate for themselves and make meaningful change.

When students gain confidence in their ability to work through problems and attain their goals, they also begin to build a growth mindset . According to leading resilience researcher, Carol Dweck, “in a growth mindset, people believe that their most basic abilities can be developed through dedication and hard work—brains and talent are just the starting point. This view creates a love of learning and a resilience that is essential for great accomplishment.”

Set and Achieve Goals

Students who possess strong problem-solving skills are better equipped to set and achieve their goals. By learning how to identify problems, think critically, and develop solutions, students can become more self-sufficient and confident in their ability to achieve their goals. Additionally, problem-solving skills are used in virtually all fields, disciplines, and career paths, which makes them important for everyone. Building strong problem-solving skills will help students enhance their academic and career performance and become more competitive as they begin to seek full-time employment after graduation or pursue additional education and training.

Resolve Conflicts

In addition to increased social and emotional skills like self-efficacy and goal-setting, problem-solving skills teach students how to cooperate with others and work through disagreements and conflicts. Problem-solving promotes “thinking outside the box” and approaching a conflict by searching for different solutions. This is a very different (and more effective!) method than a more stagnant approach that focuses on placing blame or getting stuck on elements of a situation that can’t be changed.

While it’s natural to get frustrated or feel stuck when working through a conflict, students with strong problem-solving skills will be able to work through these obstacles, think more rationally, and address the situation with a more solution-oriented approach. These skills will be valuable for students in school, their careers, and throughout their lives.

Achieve Success

We are all faced with problems every day. Problems arise in our personal lives, in school and in our jobs, and in our interactions with others. Employers especially are looking for candidates with strong problem-solving skills. In today’s job market, most jobs require the ability to analyze and effectively resolve complex issues. Students with strong problem-solving skills will stand out from other applicants and will have a more desirable skill set.

In a recent opinion piece published by The Hechinger Report , Virgel Hammonds, Chief Learning Officer at KnowledgeWorks, stated “Our world presents increasingly complex challenges. Education must adapt so that it nurtures problem solvers and critical thinkers.” Yet, the “traditional K–12 education system leaves little room for students to engage in real-world problem-solving scenarios.” This is the reason that a growing number of K–12 school districts and higher education institutions are transforming their instructional approach to personalized and competency-based learning, which encourage students to make decisions, problem solve and think critically as they take ownership of and direct their educational journey.

Problem-Solving Skills Can Be Measured and Taught

Research shows that problem-solving skills can be measured and taught. One effective method is through performance-based assessments which require students to demonstrate or apply their knowledge and higher-order skills to create a response or product or do a task.

What Are Performance-Based Assessments?

With the No Child Left Behind Act (2002), the use of standardized testing became the primary way to measure student learning in the U.S. The legislative requirements of this act shifted the emphasis to standardized testing, and this led to a decline in nontraditional testing methods .

But many educators, policy makers, and parents have concerns with standardized tests. Some of the top issues include that they don’t provide feedback on how students can perform better, they don’t value creativity, they are not representative of diverse populations, and they can be disadvantageous to lower-income students.

While standardized tests are still the norm, U.S. Secretary of Education Miguel Cardona is encouraging states and districts to move away from traditional multiple choice and short response tests and instead use performance-based assessment, competency-based assessments, and other more authentic methods of measuring students abilities and skills rather than rote learning.

Performance-based assessments measure whether students can apply the skills and knowledge learned from a unit of study. Typically, a performance task challenges students to use their higher-order skills to complete a project or process. Tasks can range from an essay to a complex proposal or design.

Preview a Performance-Based Assessment

Want a closer look at how performance-based assessments work? Preview CAE’s K–12 and Higher Education assessments and see how CAE’s tools help students develop critical thinking, problem-solving, and written communication skills.

Performance-Based Assessments Help Students Build and Practice Problem-Solving Skills

In addition to effectively measuring students’ higher-order skills, including their problem-solving skills, performance-based assessments can help students practice and build these skills. Through the assessment process, students are given opportunities to practically apply their knowledge in real-world situations. By demonstrating their understanding of a topic, students are required to put what they’ve learned into practice through activities such as presentations, experiments, and simulations.

This type of problem-solving assessment tool requires students to analyze information and choose how to approach the presented problems. This process enhances their critical thinking skills and creativity, as well as their problem-solving skills. Unlike traditional assessments based on memorization or reciting facts, performance-based assessments focus on the students’ decisions and solutions, and through these tasks students learn to bridge the gap between theory and practice.

Performance-based assessments like CAE’s College and Career Readiness Assessment (CRA+) and Collegiate Learning Assessment (CLA+) provide students with in-depth reports that show them which higher-order skills they are strongest in and which they should continue to develop. This feedback helps students and their teachers plan instruction and supports to deepen their learning and improve their mastery of critical skills.

Explore CAE’s Problem-Solving Assessments

CAE offers performance-based assessments that measure student proficiency in higher-order skills including problem solving, critical thinking, and written communication.

College and Career Readiness Assessment (CCRA+) for secondary education and
Collegiate Learning Assessment (CLA+) for higher education.

Our solution also includes instructional materials, practice models, and professional development.

We can help you create a program to build students’ problem-solving skills that includes:

Measuring students’ problem-solving skills through a performance-based assessment
Using the problem-solving assessment data to inform instruction and tailor interventions
Teaching students problem-solving skills and providing practice opportunities in real-life scenarios
Supporting educators with quality professional development

Get started with our problem-solving assessment tools to measure and build students’ problem-solving skills today! These skills will be invaluable to students now and in the future.

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Learn more about cae’s suite of products and let’s get started measuring and teaching students important higher-order skills like problem solving..

Don’t Just Tell Students to Solve Problems. Teach Them How.

The positive impact of an innovative uc san diego problem-solving educational curriculum continues to grow.

Daniel Kane - [email protected]

Published Date

Not getting stuck

One of the overarching goals of this project is to teach both problem-identification and problem-solving skills that help students avoid getting stuck during the learning process. Stuck feelings lead to frustration – and when it’s a Science, Technology, Engineering and Math (STEM) project, that frustration can lead students to feel they don’t belong in a STEM major or a STEM career. Instead, the UC San Diego curriculum is designed to give students the tools that lead to reactions like “this class is hard, but I know I can do this!” – as Ogo, a celebrated high school biomedical sciences and technology teacher, put it.

Three years into the curriculum development effort, the light-hearted energy of the students combined with their intense focus points to success. On the last day of the class, Mourad Mjahed PhD, Director of the MESA Program at Southwestern College’s School of Mathematics, Science and Engineering came to UC San Diego to see the final project presentations made by his 22 MESA students.

“Industry is looking for students who have learned from their failures and who have worked outside of their comfort zones,” said Mjahed. The UC San Diego problem-solving curriculum, Mjahed noted, is an opportunity for students to build the skills and the confidence to learn from their failures and to work outside their comfort zone. “And from there, they see pathways to real careers,” he said.

What does it mean to explicitly teach problem solving?

This approach to teaching problem solving includes a significant focus on learning to identify the problem that actually needs to be solved, in order to avoid solving the wrong problem. The curriculum is organized so that each day is a complete experience. It begins with the teacher introducing the problem-identification or problem-solving strategy of the day. The teacher then presents case studies of that particular strategy in action. Next, the students get introduced to the day’s challenge project. Working in teams, the students compete to win the challenge while integrating the day’s technique. Finally, the class reconvenes to reflect. They discuss what worked and didn't work with their designs as well as how they could have used the day’s problem-identification or problem-solving technique more effectively.

The challenges are designed to be engaging – and over three years, they have been refined to be even more engaging. But the student engagement is about much more than being entertained. Many of the students recognize early on that the problem-identification and problem-solving skills they are learning can be applied not just in the classroom, but in other classes and in life in general.

Gabriel from Southwestern College is one of the students who saw benefits outside the classroom almost immediately. In addition to taking the UC San Diego problem-solving course, Gabriel was concurrently enrolled in an online computer science programming class. He said he immediately started applying the UC San Diego problem-identification and troubleshooting strategies to his coding assignments.

Gabriel noted that he was given a coding-specific troubleshooting strategy in the computer science course, but the more general problem-identification strategies from the UC San Diego class had been extremely helpful. It’s critical to “find the right problem so you can get the right solution. The strategies here,” he said, “they work everywhere.”

Phan echoed this sentiment. “We believe this curriculum can prepare students for the technical workforce. It can prepare students to be impactful for any career path.”

The goal is to be able to offer the course in community colleges for course credit that transfers to the UC, and to possibly offer a version of the course to incoming students at UC San Diego.

As the team continues to work towards integrating the curriculum in both standardized high school courses such as physics, and incorporating the content as a part of the general education curriculum at UC San Diego, the project is expected to impact thousands more students across San Diego annually.

Portrait of the Problem-Solving Curriculum

On a sunny Wednesday in July 2023, an experiential-learning classroom was full of San Diego community college students. They were about half-way through the three-week problem-solving course at UC San Diego, held in the campus’ EnVision Arts and Engineering Maker Studio. On this day, the students were challenged to build a contraption that would propel at least six ping pong balls along a kite string spanning the laboratory. The only propulsive force they could rely on was the air shooting out of a party balloon.

A team of three students from Southwestern College – Valeria, Melissa and Alondra – took an early lead in the classroom competition. They were the first to use a plastic bag instead of disposable cups to hold the ping pong balls. Using a bag, their design got more than half-way to the finish line – better than any other team at the time – but there was more work to do.

As the trio considered what design changes to make next, they returned to the problem-solving theme of the day: unintended consequences. Earlier in the day, all the students had been challenged to consider unintended consequences and ask questions like: When you design to reduce friction, what happens? Do new problems emerge? Did other things improve that you hadn’t anticipated?

Other groups soon followed Valeria, Melissa and Alondra’s lead and began iterating on their own plastic-bag solutions to the day’s challenge. New unintended consequences popped up everywhere. Switching from cups to a bag, for example, reduced friction but sometimes increased wind drag.

Over the course of several iterations, Valeria, Melissa and Alondra made their bag smaller, blew their balloon up bigger, and switched to a different kind of tape to get a better connection with the plastic straw that slid along the kite string, carrying the ping pong balls.

One of the groups on the other side of the room watched the emergence of the plastic-bag solution with great interest.

“We tried everything, then we saw a team using a bag,” said Alexander, a student from City College. His team adopted the plastic-bag strategy as well, and iterated on it like everyone else. They also chose to blow up their balloon with a hand pump after the balloon was already attached to the bag filled with ping pong balls – which was unique.

“I don’t want to be trying to put the balloon in place when it's about to explode,” Alexander explained.

Asked about whether the structured problem solving approaches were useful, Alexander’s teammate Brianna, who is a Southwestern College student, talked about how the problem-solving tools have helped her get over mental blocks. “Sometimes we make the most ridiculous things work,” she said. “It’s a pretty fun class for sure.”

Yoshadara, a City College student who is the third member of this team, described some of the problem solving techniques this way: “It’s about letting yourself be a little absurd.”

Alexander jumped back into the conversation. “The value is in the abstraction. As students, we learn to look at the problem solving that worked and then abstract out the problem solving strategy that can then be applied to other challenges. That’s what mathematicians do all the time,” he said, adding that he is already thinking about how he can apply the process of looking at unintended consequences to improve both how he plays chess and how he goes about solving math problems.

Looking ahead, the goal is to empower as many students as possible in the San Diego area and beyond to learn to problem solve more enjoyably. It’s a concrete way to give students tools that could encourage them to thrive in the growing number of technical careers that require sharp problem-solving skills, whether or not they require a four-year degree.

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Center for Teaching

Teaching problem solving.

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Tips and Techniques

Expert vs. novice problem solvers, communicate.

Have students identify specific problems, difficulties, or confusions . Don’t waste time working through problems that students already understand.
If students are unable to articulate their concerns, determine where they are having trouble by asking them to identify the specific concepts or principles associated with the problem.
In a one-on-one tutoring session, ask the student to work his/her problem out loud . This slows down the thinking process, making it more accurate and allowing you to access understanding.
When working with larger groups you can ask students to provide a written “two-column solution.” Have students write up their solution to a problem by putting all their calculations in one column and all of their reasoning (in complete sentences) in the other column. This helps them to think critically about their own problem solving and helps you to more easily identify where they may be having problems. Two-Column Solution (Math) Two-Column Solution (Physics)

Encourage Independence

Model the problem solving process rather than just giving students the answer. As you work through the problem, consider how a novice might struggle with the concepts and make your thinking clear
Have students work through problems on their own. Ask directing questions or give helpful suggestions, but provide only minimal assistance and only when needed to overcome obstacles.
Don’t fear group work ! Students can frequently help each other, and talking about a problem helps them think more critically about the steps needed to solve the problem. Additionally, group work helps students realize that problems often have multiple solution strategies, some that might be more effective than others

Be sensitive

Frequently, when working problems, students are unsure of themselves. This lack of confidence may hamper their learning. It is important to recognize this when students come to us for help, and to give each student some feeling of mastery. Do this by providing positive reinforcement to let students know when they have mastered a new concept or skill.

Encourage Thoroughness and Patience

Try to communicate that the process is more important than the answer so that the student learns that it is OK to not have an instant solution. This is learned through your acceptance of his/her pace of doing things, through your refusal to let anxiety pressure you into giving the right answer, and through your example of problem solving through a step-by step process.

Experts (teachers) in a particular field are often so fluent in solving problems from that field that they can find it difficult to articulate the problem solving principles and strategies they use to novices (students) in their field because these principles and strategies are second nature to the expert. To teach students problem solving skills, a teacher should be aware of principles and strategies of good problem solving in his or her discipline .

The mathematician George Polya captured the problem solving principles and strategies he used in his discipline in the book How to Solve It: A New Aspect of Mathematical Method (Princeton University Press, 1957). The book includes a summary of Polya’s problem solving heuristic as well as advice on the teaching of problem solving.

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Teaching Problem-Solving Skills

Many instructors design opportunities for students to solve “problems”. But are their students solving true problems or merely participating in practice exercises? The former stresses critical thinking and decision making skills whereas the latter requires only the application of previously learned procedures.

Problem solving is often broadly defined as "the ability to understand the environment, identify complex problems, review related information to develop, evaluate strategies and implement solutions to build the desired outcome" (Fissore, C. et al, 2021). True problem solving is the process of applying a method – not known in advance – to a problem that is subject to a specific set of conditions and that the problem solver has not seen before, in order to obtain a satisfactory solution.

Below you will find some basic principles for teaching problem solving and one model to implement in your classroom teaching.

Principles for teaching problem solving

Model a useful problem-solving method . Problem solving can be difficult and sometimes tedious. Show students how to be patient and persistent, and how to follow a structured method, such as Woods’ model described below. Articulate your method as you use it so students see the connections.
Teach within a specific context . Teach problem-solving skills in the context in which they will be used by students (e.g., mole fraction calculations in a chemistry course). Use real-life problems in explanations, examples, and exams. Do not teach problem solving as an independent, abstract skill.
Help students understand the problem . In order to solve problems, students need to define the end goal. This step is crucial to successful learning of problem-solving skills. If you succeed at helping students answer the questions “what?” and “why?”, finding the answer to “how?” will be easier.
Take enough time . When planning a lecture/tutorial, budget enough time for: understanding the problem and defining the goal (both individually and as a class); dealing with questions from you and your students; making, finding, and fixing mistakes; and solving entire problems in a single session.
Ask questions and make suggestions . Ask students to predict “what would happen if …” or explain why something happened. This will help them to develop analytical and deductive thinking skills. Also, ask questions and make suggestions about strategies to encourage students to reflect on the problem-solving strategies that they use.
Link errors to misconceptions . Use errors as evidence of misconceptions, not carelessness or random guessing. Make an effort to isolate the misconception and correct it, then teach students to do this by themselves. We can all learn from mistakes.

Woods’ problem-solving model

Define the problem.

The system . Have students identify the system under study (e.g., a metal bridge subject to certain forces) by interpreting the information provided in the problem statement. Drawing a diagram is a great way to do this.
Known(s) and concepts . List what is known about the problem, and identify the knowledge needed to understand (and eventually) solve it.
Unknown(s) . Once you have a list of knowns, identifying the unknown(s) becomes simpler. One unknown is generally the answer to the problem, but there may be other unknowns. Be sure that students understand what they are expected to find.
Units and symbols . One key aspect in problem solving is teaching students how to select, interpret, and use units and symbols. Emphasize the use of units whenever applicable. Develop a habit of using appropriate units and symbols yourself at all times.
Constraints . All problems have some stated or implied constraints. Teach students to look for the words "only", "must", "neglect", or "assume" to help identify the constraints.
Criteria for success . Help students consider, from the beginning, what a logical type of answer would be. What characteristics will it possess? For example, a quantitative problem will require an answer in some form of numerical units (e.g., $/kg product, square cm, etc.) while an optimization problem requires an answer in the form of either a numerical maximum or minimum.

Think about it

“Let it simmer”. Use this stage to ponder the problem. Ideally, students will develop a mental image of the problem at hand during this stage.
Identify specific pieces of knowledge . Students need to determine by themselves the required background knowledge from illustrations, examples and problems covered in the course.
Collect information . Encourage students to collect pertinent information such as conversion factors, constants, and tables needed to solve the problem.

Plan a solution

Consider possible strategies . Often, the type of solution will be determined by the type of problem. Some common problem-solving strategies are: compute; simplify; use an equation; make a model, diagram, table, or chart; or work backwards.
Choose the best strategy . Help students to choose the best strategy by reminding them again what they are required to find or calculate.

Carry out the plan

Be patient . Most problems are not solved quickly or on the first attempt. In other cases, executing the solution may be the easiest step.
Be persistent . If a plan does not work immediately, do not let students get discouraged. Encourage them to try a different strategy and keep trying.

Encourage students to reflect. Once a solution has been reached, students should ask themselves the following questions:

Does the answer make sense?
Does it fit with the criteria established in step 1?
Did I answer the question(s)?
What did I learn by doing this?
Could I have done the problem another way?

If you would like support applying these tips to your own teaching, CTE staff members are here to help. View the CTE Support page to find the most relevant staff member to contact.

Fissore, C., Marchisio, M., Roman, F., & Sacchet, M. (2021). Development of problem solving skills with Maple in higher education. In: Corless, R.M., Gerhard, J., Kotsireas, I.S. (eds) Maple in Mathematics Education and Research. MC 2020. Communications in Computer and Information Science, vol 1414. Springer, Cham. https://doi.org/10.1007/978-3-030-81698-8_15
Foshay, R., & Kirkley, J. (1998). Principles for Teaching Problem Solving. TRO Learning Inc., Edina MN. (PDF) Principles for Teaching Problem Solving (researchgate.net)
Hayes, J.R. (1989). The Complete Problem Solver. 2nd Edition. Hillsdale, NJ: Lawrence Erlbaum Associates.
Woods, D.R., Wright, J.D., Hoffman, T.W., Swartman, R.K., Doig, I.D. (1975). Teaching Problem solving Skills.
Engineering Education. Vol 1, No. 1. p. 238. Washington, DC: The American Society for Engineering Education.

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Critical Thinking Resources for High School Teachers

Developing critical thinking abilities is a necessary skill for all high school students but teaching these skills is not the easiest task for high school teachers. Fortunately, there is a wealth of information online to provide teachers the resources needed for creating critical thinking lesson plans.

These online resources provide lessons plans, videos, and small but helpful tips that can be used everyday in the classroom to reinforce lessons and ideas. Below are some of the top resources for teaching critical thinking to high school students.

A site devoted to all things related to critical thinking

The Critical Thinking Community, from the Center for Critical Thinking, provides one of the best sites for critical thinking resources and has a special section aimed at helping high school teachers prepare appropriate lesson plans: Critical Thinking Community for High School Teachers .

“Critical thinking is essential if we are to get to the root of our problems and develop reasonable solutions,” reads the site’s About Us page. “After all, the quality of everything we do is determined by the quality of our thinking.”

Therefore it’s no surprise that the site provides many free online resources for high school teachers, as well as other materials that can be ordered online for a small fee.

One example of an online resource for critical thinking for high school students is the article “How to Study and Learn (Part One)”. This introductory article lays the ground work for the importance of thinking critically, illustrated by the following passage:

“To study well and learn any subject is to learn how to think with discipline within that subject. It is to learn to think within its logic, to:

raise vital questions and problems within it, formulating them clearly and precisely
gather and assess information, using ideas to interpret that information insightfully
come to well-reasoned conclusions and solutions, testing them against relevant criteria and standards
adopt the point of view of the discipline, recognizing and assessing, as needs be, its assumptions, implications, and practical consequences
communicate effectively with others using the language of the discipline and that of educated public discourse
relate what one is learning in the subject to other subjects and to what is significant in human life”

State critical thinking resources

Additionally, many states offer free online critical thinking resources, such as the handbook compiled by faculty members of Prince George’s Community College and put on Maryland’s official website: Handbook of Critical Thinking Resources .

In addition to providing a wealth of outside information resources, the handbook details how thinking critically can help students while they are in high school and in the future:

“Improving students’ critical thinking skills will help students:

improve their thinking about their course work
use sound thinking on tests, assignments, and projects in their courses
have the strategic, analytical, problem solving, and decision-making skills they need when they transfer to another college
have the strategic, analytical, problem solving, and decision-making skills they need when they transition to the workplace”

Keeping up to date on current trends

Other sites, such as Edutopia.org, are constantly updated with new information to provide teachers with the most current information possible. The site, which is part of the George Lucas Educational Foundation, is divided by grade level and has a special section focused on producing critical thinking high school students: Grades 9-12 High School .

The site describes three fundamental skills it believes necessary for students to become lifelong learners in the 21 st Century:

how to find information
how to assess the quality of information
how to creatively and effectively use information to accomplish a goal

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Strategies for teaching metacognition in classrooms

Subscribe to the center for universal education bulletin, david owen and do david owen history and politics teacher - melbourne high school - victoria, australia alvin vista alvin vista former brookings expert @alvin_vista.

November 15, 2017

This is the third piece in a six-part blog series on teaching 21st century skills , including problem solving , metacognition , critical thinking , and collaboration , in classrooms.

Metacognition is thinking about thinking. It is an increasingly useful mechanism to enhance student learning, both for immediate outcomes and for helping students to understand their own learning processes. So metacognition is a broad concept that refers to the knowledge and thought processes regarding one’s own learning. Importantly, there is research evidence (e.g., Moely and colleagues, 1995 ; Schraw, 1998 ) that metacognition is a teachable skill that is central to other skills sets such as problem solving, decisionmaking, and critical thinking. Reflective thinking, as a component of metacognition, is the ability to reflect critically on learning experiences and processes in order to inform future progress.

David Owen, who teaches history and politics at Melbourne High School in Victoria, Australia, discusses a simple but effective approach to encourage student self-reflection:

I have rethought some of my classroom strategies this year. I teach at a secondary school which prides itself on its high level of student achievement, and I had always believed my students performed accordingly. They always ask for help before, during, and after class. Their varied queries could be superficial knowledge-based questions or more general questions about their progress, but I’d always read this habit as a sign that my students had an open mindset: they were inquisitive, cared about their learning, and charted their progress.

But having students asking a million questions of the teacher poses another challenge entirely, which can be framed: “Why aren’t students asking these questions of themselves?”

Recent shifts in pedagogy have emphasized the importance of encouraging students to figure out how to be independent, self-regulated learners. The teacher cannot be there to hold their hand beyond school. This demands that students reflect on their learning in meaningful ways. It also requires students be critical analysts of their own thinking in order to overcome complex or unexpected problems.

I’ve begun to highlight strategies which might better encourage this kind of metacognition. For younger adolescents, I’ve found that “Exit Tickets” are an opportunity for students to reflect on what they have accomplished and what they could improve on. Exit Tickets are a family of feedback tools that students complete for a few minutes at the end of each lesson. They prompt students to think about how and what they learn, as well as what challenges they are still facing.

“Traffic Lights” is a simple yet effective Exit Ticket which emphasizes three key factors:

When students encountered a challenge;
When students had thought differently about something; and
When students were learning well.

Over time I’ve found myself more interested in student responses to the Yellow Light, because it requires students to think about how they were thinking, rather than when (the emphasis of the Red and Green lights). The Yellow Light encourages reflective thinking as well as “thinking about thinking, or what is known as metacognition.” The possibilities for Exit Tickets are numerous and easily adaptable to the content and specific skills taught in any lesson.

Another example of reflective, self-directed learning which is suited to group work is setting a classroom rule that groups ask a question together , rather than individually. What this means is that rather than immediately ask the teacher for help, a student who has encountered a problem must consult with their group first. If the group cannot collectively find the solution, they can raise their hands simultaneously—a sign that the question has been fielded to the group already. There are various ways to modify this rule: highlighting with traffic-light colors, like in the Exit Ticket activity, is one such example.

For older students, setting a few rules before requesting aid from the teacher has seen their self-directed learning—and my feedback—improve markedly. I have emphasized that students seek specific feedback concerning their trial exams. I ask students to ensure they have highlighted and annotated their responses before seeing me. This approach shifts student thinking from the simplistic “submission to feedback” principle towards a more involved process, where students must consider what feedback they would want, what advice they would give themselves, and where they think they need to improve. This approach encourages the students to independently exercise control over their learning and progress, thereby making them more independent and self-directed learners.

Evidence supporting the impact of metacognition suggests that students applying metacognitive strategies to learning tasks outperform those who do not ( Mason, Boldrin & Ariasi, 2010 ; Dignath & Buettner, 2008 ). The classroom approaches that David Owen uses in his classroom demonstrates one way of developing parts of this important complex skill. Interestingly, although these skills are so important in our modern world, the approaches discussed here are practical, do not require 21st century technology or resources, and can be applied in almost any classroom setting.

Problem-Solving

Jabberwocky

Problem-solving is the ability to identify and solve problems by applying appropriate skills systematically.

Problem-solving is a process—an ongoing activity in which we take what we know to discover what we don't know. It involves overcoming obstacles by generating hypo-theses, testing those predictions, and arriving at satisfactory solutions.

Problem-solving involves three basic functions:

Seeking information

Generating new knowledge

Making decisions

Problem-solving is, and should be, a very real part of the curriculum. It presupposes that students can take on some of the responsibility for their own learning and can take personal action to solve problems, resolve conflicts, discuss alternatives, and focus on thinking as a vital element of the curriculum. It provides students with opportunities to use their newly acquired knowledge in meaningful, real-life activities and assists them in working at higher levels of thinking (see Levels of Questions ).

Here is a five-stage model that most students can easily memorize and put into action and which has direct applications to many areas of the curriculum as well as everyday life:

Expert Opinion

Here are some techniques that will help students understand the nature of a problem and the conditions that surround it:

List all related relevant facts.
Make a list of all the given information.
Restate the problem in their own words.
List the conditions that surround a problem.
Describe related known problems.

It's Elementary

For younger students, illustrations are helpful in organizing data, manipulating information, and outlining the limits of a problem and its possible solution(s). Students can use drawings to help them look at a problem from many different perspectives.

Understand the problem. It's important that students understand the nature of a problem and its related goals. Encourage students to frame a problem in their own words.

Describe any barriers. Students need to be aware of any barriers or constraints that may be preventing them from achieving their goal. In short, what is creating the problem? Encouraging students to verbalize these impediments is always an important step.

Identify various solutions. After the nature and parameters of a problem are understood, students will need to select one or more appropriate strategies to help resolve the problem. Students need to understand that they have many strategies available to them and that no single strategy will work for all problems. Here are some problem-solving possibilities:

Create visual images. Many problem-solvers find it useful to create “mind pictures” of a problem and its potential solutions prior to working on the problem. Mental imaging allows the problem-solvers to map out many dimensions of a problem and “see” it clearly.

Guesstimate. Give students opportunities to engage in some trial-and-error approaches to problem-solving. It should be understood, however, that this is not a singular approach to problem-solving but rather an attempt to gather some preliminary data.

Create a table. A table is an orderly arrangement of data. When students have opportunities to design and create tables of information, they begin to understand that they can group and organize most data relative to a problem.

Use manipulatives. By moving objects around on a table or desk, students can develop patterns and organize elements of a problem into recognizable and visually satisfying components.

Work backward. It's frequently helpful for students to take the data presented at the end of a problem and use a series of computations to arrive at the data presented at the beginning of the problem.

Look for a pattern. Looking for patterns is an important problem-solving strategy because many problems are similar and fall into predictable patterns. A pattern, by definition, is a regular, systematic repetition and may be numerical, visual, or behavioral.

Create a systematic list. Recording information in list form is a process used quite frequently to map out a plan of attack for defining and solving problems. Encourage students to record their ideas in lists to determine regularities, patterns, or similarities between problem elements.

Try out a solution. When working through a strategy or combination of strategies, it will be important for students to …

Keep accurate and up-to-date records of their thoughts, proceedings, and procedures. Recording the data collected, the predictions made, and the strategies used is an important part of the problem solving process.

Try to work through a selected strategy or combination of strategies until it becomes evident that it's not working, it needs to be modified, or it is yielding inappropriate data. As students become more proficient problem-solvers, they should feel comfortable rejecting potential strategies at any time during their quest for solutions.

Monitor with great care the steps undertaken as part of a solution. Although it might be a natural tendency for students to “rush” through a strategy to arrive at a quick answer, encourage them to carefully assess and monitor their progress.

Feel comfortable putting a problem aside for a period of time and tackling it at a later time. For example, scientists rarely come up with a solution the first time they approach a problem. Students should also feel comfortable letting a problem rest for a while and returning to it later.

Evaluate the results. It's vitally important that students have multiple opportunities to assess their own problem-solving skills and the solutions they generate from using those skills. Frequently, students are overly dependent upon teachers to evaluate their performance in the classroom. The process of self-assessment is not easy, however. It involves risk-taking, self-assurance, and a certain level of independence. But it can be effectively promoted by asking students questions such as “How do you feel about your progress so far?” “Are you satisfied with the results you obtained?” and “Why do you believe this is an appropriate response to the problem?”

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Creative problem solving tools and skills for students and teachers

Creative Problem Solving: What Is It?

Creative Problem Solving, or CPS , refers to the use of imagination and innovation to find solutions to problems when formulaic or conventional processes have failed.

Despite its rather dry definition – creative problem-solving in its application can be a lot of fun for learners and teachers alike.

Why Are Creative Problem-Solving Skills Important?

By definition, creative problem-solving challenges students to think beyond the conventional and to avoid well-trodden, sterile paths of thinking.

Not only does this motivate student learning, encourage engagement, and inspire deeper learning, but the practical applications of this higher-level thinking skill are virtually inexhaustible.

For example, given the rapidly changing world of work, it is hard to conceive of a skill that will be more valuable than the ability to generate innovative solutions to the unique problems that will arise and that are impossible to predict ahead of time.

Outside the world of work, in our busy daily lives, the endless problems arising from day-to-day living can also be overcome by a creative problem-solving approach.

When students have developed their creative problem-solving abilities effectively, they will have added a powerful tool to attack problems that they will encounter, whether in school, work, or in their personal lives.

Due to its at times nebulous nature, teaching creative problem-solving in the classroom poses its own challenges. However, developing a culture of approaching problem-solving in a creative manner is possible.

In this article, we will take a look at a variety of strategies, tools, and activities that can help students improve their creative problem-solving skills.

The Underlying Principles of CPS

Before we take a look at a process for implementing creative problem solving, it is helpful to examine a few of the underlying principles of CPS. These core principles should be encouraged in the classroom. They are:

● Assume Nothing

Assumptions are the enemy of creativity and original thinking. If students assume they already have the answer, they will not be creative in their approach to solving a problem.

● Problems Are Opportunities

Rather than seeing problems as difficulties to endure, a shift in perspective can instead view problems as challenges that offer new opportunities. Encourage your students to shift their perspectives to see opportunities where they once saw problems.

● Suspend Judgment

Making immediate judgments closes down the creative response and the formation of new ideas. There is a time to make judgments, but making a judgment too early in the process can be very detrimental to finding a creative solution.

Cognitive Approaches: Convergent vs Divergent Thinking

“It is easier to tame a wild idea than it is to push a closer-in idea further out.”

— Alex Osborn

The terms divergent and convergent thinking, coined by psychologist J.P. Guilford in 1956, refer to two contrasting cognitive approaches to problem-solving.

Convergent Thinking can be thought of as linear and systematic in its approach. It attempts to find a solution to a problem by narrowing down multiple ideas into a single solution. If convergent thinking can be thought of as asking a single question, that question would be ‘ Why ?’

Divergent Thinking focuses more on the generation of multiple ideas and on the connections between those ideas. It sees problems as design opportunities and encourages the use of resources and materials in original ways. Divergent thinking encourages the taking of creative risks and is flexible rather than analytical in its approach. If it was a single question, it’d be ‘ Why not ?’

While it may appear that these two modes of thinking about a problem have an essentially competitive relationship, in CPS they can work together in a complementary manner.

When students have a problem to solve and they’re looking for innovative solutions, they can employ divergent thinking initially to generate multiple ideas, then convergent thinking to analyze and narrow down those ideas.

Students can repeat this process to continue to filter and refine their ideas and perspectives until they arrive at an innovative and satisfactory solution to the initial problem.

Let’s now take a closer look at the creative problem-solving process.

The Creative Problem-Solving Process

CPS helps students arrive at innovative and novel solutions to the problems that arise in life. Having a process to follow helps to keep students focused and to reach a point where action can be taken to implement creative ideas.

Originally developed by Alex Osborn and Sid Parnes, the CPS process has gone through a number of revisions over the last 50 or so years and, as a result, there are a number of variations of this model in existence.

The version described below is one of the more recent models and is well-suited to the classroom environment.

However, things can sometimes get a little complex for some of the younger students. So, in this case, it may be beneficial to teach the individual parts of the process in isolation first.

1. Clarify:

Before beginning to seek creative solutions to a problem, it is important to clarify the exact nature of that problem. To do this, students should do the following three things:

i. Identify the Problem

The first step in bringing creativity to problem-solving is to identify the problem, challenge, opportunity, or goal and clearly define it.

ii. Gather Data

Gather data and research information and background to ensure a clear understanding.

iii. Formulate Questions

Enhance awareness of the nature of the problem by creating questions that invite solutions.

Explore new ideas to answer the questions raised. It’s time to get creative here. The more ideas generated, the greater the chance of producing a novel and useful idea. At this stage in particular, students should be engaged in divergent thinking as described above.

The focus here shifts from ideas to solutions. Once multiple ideas have been generated, convergent thinking can be used to narrow these down to the most suitable solution. The best idea should be closely analyzed in all its aspects and further ideas generated to make subsequent improvements. This is the stage to refine the initial idea and make it into a really workable solution.

4. Implement

Create a plan to implement the chosen solution. Students need to identify the required resources for the successful implementation of the solution. They need to plan for the actions that need to be taken, when they need to be taken, and who needs to take them.

Summary of Creative Problem Solving Process

In each stage of the CPS Process, students should be encouraged to employ divergent and convergent thinking in turn. Divergent thinking should be used to generate multiple ideas with convergent thinking then used to narrow these ideas down to the most feasible options. We will discuss how students go about this, but let’s first take a quick look at the role of a group facilitator.

The Importance of Group Facilitator

CPS is best undertaken in groups and, for larger and more complex projects, it’s even more effective when a facilitator can be appointed for the group.

The facilitator performs a number of useful purposes and helps the group to:

Stay focused on the task at hand
Move through the various stages efficiently
Select appropriate tools and strategies

A good facilitator does not generate ideas themselves but instead keeps the group focused on each step of the process.

Facilitators should be objective and possess a good understanding of the process outlined above, as well as the other tools and strategies that we will look at below.

The Creative Problem-Solving Process: Tools and Strategies

There are several activities available to help students move through each stage. These will help students to stay on track, remove barriers and blocks, be creative, and reach a consensus as they progress through the CPS process.

The following tools and strategies can help provide groups with some structure and can be applied at various stages of the problem-solving process. For convenience, they have been categorized according to whether they make demands on divergent or convergent thinking as discussed earlier.

Divergent Thinking Tools:

● Brainstorming

Defined by Alex Osborn as “a group’s attempt to find a solution for a specific problem by amassing ideas ”, this is perhaps the best-known tool in the arsenal of the creative problem solver.

To promote a creative collaboration in a group setting, simply share the challenge with everyone and challenge them to come up with as many ideas as possible. Ideas should be concise and specific. For this reason, it may be worth setting a word limit for recording each idea e.g. express in headline form in no more than 5 words. Post-it notes are perfect for this.

You may also set a quota on the number of ideas to generate or introduce a time limit to further encourage focus. When completed, members of the group can share and compare all the ideas in search of the most suitable.

● 5 W’s and an H

The 5 W’s and an H are Who , What , Where , Why , and How . This strategy is useful to effectively gather data. Students brainstorm questions to ask that begin with each of the question words above in turn. They then seek to gather the necessary information to answer these questions through research and discussion.

● Reverse Assumptions

This activity is a great way to explore new ideas. Have the students begin by generating a list of up to 10 basic assumptions about the idea or concept. For each of these, students then explore the reverse of the assumption listing new insights and perspectives in the process.

The students can then use these insights and perspectives to generate fresh ideas. For example, an assumption about the concept of a restaurant might be that the food is cooked for you. The reverse of that assumption could be a restaurant where you cook the food yourself. So, how about a restaurant where patrons select their own recipes and cook their own food aided by a trained chef?

Convergent Thinking Tools

● How-How Diagram

This is the perfect activity to use when figuring out the steps required to implement a solution.

Students write the solution on the left-hand side of a page turned landscape. Working together, they identify the individual steps required to achieve this solution and write these to the right of the solution.

When they have written these steps, they go through each step one-by-one identifying in detail each stage of achieving that step. These are written branching to the right of each step.

Students repeat this process until they have exhausted the process and ended up with a comprehensive branch diagram detailing each step necessary for the implementation of the solution.

● The Evaluation Matrix

Making an evaluation matrix creates a systematic way of analyzing and comparing multiple solutions. It allows for a group to evaluate options against various criteria to help build consensus.

An evaluation matrix begins with the listing of criteria to evaluate potential solutions against. These can then be turned into the form of a positive question that allows for a Yes or No answer. For example, if the budget is the criteria, the evaluation question could be ‘ Is it within budget? ’

Make a matrix grid with a separate column for each of the key criteria. Write the positive question form of these criteria as headings for these columns. The different options can then be detailed and listed down the left-most column.

Students then work through each of the criteria for each option and record whether it fulfills, or doesn’t fulfill, each criteria. For more complex solutions, students could record their responses to each of the criteria on a scale from 0 to 5.

For example:

Using the example matrix above, it becomes very clear that Option 1 is the superior solution given that it completely fulfills all the criteria, whereas Option 2 and Option 3 fulfill only 2 out of the 3 criteria each.

● Pair & Share

This activity is suitable to help develop promising ideas. After making a list of possible solutions or questions to pursue, each individual student writes down their top 3 ideas.

Once each student has their list of their 3 best ideas, organize students into pairs. In their pairs, students discuss their combined 6 ideas to decide on the top 3 out of the 6. Once they have agreed on these, they write the new top 3 ideas on a piece of paper.

Now, direct the pairs of students to join up with another pair to make groups of 4. In these groups of 4, students discuss their collective 6 ideas to come up with a new list of the top 3 ideas.

Repeat this process until the whole class comes together as one big group to agree on the top 3 ideas overall.

Establish a Culture of Creative Problem Solving in the Classroom

Approaching problems creatively is about establishing a classroom culture that welcomes innovation and the trial and error that innovation demands. Too often our students are so focused on finding the ‘right‘ answer that they miss opportunities to explore new ideas.

It is up to us as teachers to help create a classroom culture that encourages experimentation and creative playfulness.

To do this we need to ensure our students understand the benefits of a creative approach to problem-solving.

We must ensure too that they are aware of the personal, social, and organizational benefits of CPS.

CPS should become an integral part of their approach to solving problems whether at school, work, or in their personal lives.

As teachers, it is up to us to help create a classroom culture that encourages experimentation and creative playfulness.

To do this, we must ensure our students understand the benefits of a creative approach to problem-solving.

CPS should become an integral part of their approach to solving problems, whether at school, work or in their personal lives.

Empowering Tomorrow’s Leaders: The Crucial Role of Computational and Systems Thinking in Education

the importance of systems thinking and computational thinking strategies for students cannot be overstated, as these skills are integral to navigating the complexities of our rapidly evolving digital landscape. Computational thinking, characterized by algorithmic problem-solving and logical reasoning, equips students with the ability to approach challenges systematically. In an era dominated by technology, these skills are not limited to coding but extend to critical thinking, enabling students to dissect problems, identify patterns, and devise efficient solutions. As our world becomes increasingly interconnected and data-driven, computational thinking provides a foundational framework for students to make sense of information, fostering a generation adept at leveraging technology for innovation.

Simultaneously, systems thinking is indispensable in comprehending the intricate web of relationships within various contexts. It encourages students to view issues holistically, understanding the interdependence of components and the ripple effects of decisions. In an era marked by global challenges, such as climate change and socio-economic disparities, systems thinking instills a proactive mindset. Students equipped with these skills are better prepared to analyze multifaceted problems, appreciate diverse perspectives, and collaborate on sustainable solutions.

Together, computational and systems thinking empower students to navigate an ever-changing world with confidence, adaptability, and a profound understanding of the interconnected systems that shape our future. These skills are not just academic; they are the building blocks of a resilient, innovative, and forward-thinking society.

be sure to check out our great video guides to teaching systems thinking and computational thinking below.

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How to Teach Kids Problem-Solving Skills

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Steps to Follow
Allow Consequences

Whether your child can't find their math homework or has forgotten their lunch, good problem-solving skills are the key to helping them manage their life.

A 2010 study published in Behaviour Research and Therapy found that kids who lack problem-solving skills may be at a higher risk of depression and suicidality. Additionally, the researchers found that teaching a child problem-solving skills can improve mental health .

You can begin teaching basic problem-solving skills during preschool and help your child sharpen their skills into high school and beyond.

Why Problem-Solving Skills Matter

Kids face a variety of problems every day, ranging from academic difficulties to problems on the sports field. Yet few of them have a formula for solving those problems.

Kids who lack problem-solving skills may avoid taking action when faced with a problem.

Rather than put their energy into solving the problem, they may invest their time in avoiding the issue. That's why many kids fall behind in school or struggle to maintain friendships .

Other kids who lack problem-solving skills spring into action without recognizing their choices. A child may hit a peer who cuts in front of them in line because they are not sure what else to do.

Or, they may walk out of class when they are being teased because they can't think of any other ways to make it stop. Those impulsive choices may create even bigger problems in the long run.

The 5 Steps of Problem-Solving

Kids who feel overwhelmed or hopeless often won't attempt to address a problem. But when you give them a clear formula for solving problems, they'll feel more confident in their ability to try. Here are the steps to problem-solving:

Identify the problem . Just stating the problem out loud can make a big difference for kids who are feeling stuck. Help your child state the problem, such as, "You don't have anyone to play with at recess," or "You aren't sure if you should take the advanced math class."
Develop at least five possible solutions . Brainstorm possible ways to solve the problem. Emphasize that all the solutions don't necessarily need to be good ideas (at least not at this point). Help your child develop solutions if they are struggling to come up with ideas. Even a silly answer or far-fetched idea is a possible solution. The key is to help them see that with a little creativity, they can find many different potential solutions.
Identify the pros and cons of each solution . Help your child identify potential positive and negative consequences for each potential solution they identified.
Pick a solution. Once your child has evaluated the possible positive and negative outcomes, encourage them to pick a solution.
Test it out . Tell them to try a solution and see what happens. If it doesn't work out, they can always try another solution from the list that they developed in step two.

Practice Solving Problems

When problems arise, don’t rush to solve your child’s problems for them. Instead, help them walk through the problem-solving steps. Offer guidance when they need assistance, but encourage them to solve problems on their own. If they are unable to come up with a solution, step in and help them think of some. But don't automatically tell them what to do.

When you encounter behavioral issues, use a problem-solving approach. Sit down together and say, "You've been having difficulty getting your homework done lately. Let's problem-solve this together." You might still need to offer a consequence for misbehavior, but make it clear that you're invested in looking for a solution so they can do better next time.

Use a problem-solving approach to help your child become more independent.

If they forgot to pack their soccer cleats for practice, ask, "What can we do to make sure this doesn't happen again?" Let them try to develop some solutions on their own.

Kids often develop creative solutions. So they might say, "I'll write a note and stick it on my door so I'll remember to pack them before I leave," or "I'll pack my bag the night before and I'll keep a checklist to remind me what needs to go in my bag."

Provide plenty of praise when your child practices their problem-solving skills.

Allow for Natural Consequences

Natural consequences may also teach problem-solving skills. So when it's appropriate, allow your child to face the natural consequences of their action. Just make sure it's safe to do so.

For example, let your teenager spend all of their money during the first 10 minutes you're at an amusement park if that's what they want. Then, let them go for the rest of the day without any spending money.

This can lead to a discussion about problem-solving to help them make a better choice next time. Consider these natural consequences as a teachable moment to help work together on problem-solving.

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Cheng SC, She HC, Huang LY. The impact of problem-solving instruction on middle school students’ physical science learning: Interplays of knowledge, reasoning, and problem solving . EJMSTE . 2018;14(3):731-743.

Vlachou A, Stavroussi P. Promoting social inclusion: A structured intervention for enhancing interpersonal problem‐solving skills in children with mild intellectual disabilities . Support Learn . 2016;31(1):27-45. doi:10.1111/1467-9604.12112

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By Amy Morin, LCSW Amy Morin, LCSW, is the Editor-in-Chief of Verywell Mind. She's also a psychotherapist, an international bestselling author of books on mental strength and host of The Verywell Mind Podcast. She delivered one of the most popular TEDx talks of all time.

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Project -Based Learning Approach in Teaching: Enhancing Problem Solving Skills of Senior High School Students

2022, Psychology and Education: A Multidisciplinary Journal

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Mathematics Anxiety and Problem-Solving Proficiency Among High School Students: Unraveling the Complex Interplay in the Knowledge Economy

Published: 15 April 2024

Cite this article

Yali Zhu 1 ,
Xinran Liu 1 ,
Yana Xiao 1 &
Stavros Sindakis ORCID: orcid.org/0000-0002-3542-364X 2

In the context of the knowledge-based economy, the intricate relationship between mathematics anxiety and problem-solving abilities among high school students in China is examined. This research uncovers the pervasive nature of mathematics anxiety, influenced primarily by external factors such as parental expectations, shedding light on the sources of anxiety. Additionally, it highlights the multifaceted nature of problem-solving skills among students, emphasizing their confidence in comprehending mathematical problems but challenges in applying effective problem-solving strategies. The study provides empirical evidence of a significant negative correlation between mathematics anxiety and problem-solving ability, underscoring the detrimental impact of anxiety on cognitive processes, including working memory and metacognition, essential for effective problem solving. Theoretical implications encompass a deeper understanding of the dynamics between mathematics anxiety and problem-solving skills, contributing to educational psychology and curriculum development. Policy implications call for immediate attention to address mathematics anxiety within educational reforms, advocating for comprehensive strategies that alleviate anxiety while enhancing problem-solving skills. Furthermore, this research highlights the importance of gender-inclusive approaches to anxiety in mathematics. This study enriches our theoretical understanding and underscores the urgency of holistic approaches to address mathematics anxiety and nurture problem-solving skills among high school students, empowering them to excel in the knowledge-based economy and shape a brighter future.

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This study was financially supported by the Research on the Evaluation Effect of Hybrid Training for Rural Teachers in China, 2019JSJYZD-010, and the 2021 Henan Province Teacher Education Curriculum Reform Project “Research on the Reform of Economics Curriculum for Ideological and Political Majors from the Perspective of Practical Transformation” (2021-JSJYZD-011).

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Zhu, Y., Liu, X., Xiao, Y. et al. Mathematics Anxiety and Problem-Solving Proficiency Among High School Students: Unraveling the Complex Interplay in the Knowledge Economy. J Knowl Econ (2024). https://doi.org/10.1007/s13132-023-01688-w

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Massac County High School Teacher Megan Musselman, center, helps students brainstorm ideas during EcoThink’s “Fast Fashion” sustainability challenge. Teams of students were asked to think of ways to reduce, reuse or recycle clothing, tackling an emerging environmental problem.

PADUCAH, Ky. – Local high school students from western Kentucky and southern Illinois put their problem solving skills to the test during the annual EcoThink project, challenging themselves to address environmental and sustainability issues through critical thinking exercises focused on teamwork and engineering concepts.

“The students really enjoyed this opportunity,” Paducah Tilghman High School Teacher Amy Clark said. “They liked seeing other students’ thought processes and ideas. One student said the word engineering frightened her but realized it wasn't as scary as she thought.”

This year’s project focused on a “Fast Fashion” challenge and the environmental impact of manufacturing cheap, limited-use clothing. Students were tasked with finding ways to reduce, reuse or recycle clothing by determining buying habits, back-to-school shopping needs and how to impact culture changes with their peers. Solutions presented by the teams included creating a phone application and distribution centers for renting clothes and designing clothing that can be modified depending on the season or style.

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EcoThink, which was featured at the 2024 Waste Management Symposia ’s STEMZone, is conducted through a partnership between Sprocket, Inc. and University of Kentucky College of Engineering and sponsored by FRNP.

“Each year, I am impressed with the ingenuity displayed by the students who participate in EcoThink,” FRNP Program Manager Myrna Redfield said. “We appreciate all the teachers and volunteers who come together to make this event possible and look forward to growing and improving the program in the future.”

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17 Fun Problem Solving Activities for Kids

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As a child, I would spend hours putting together puzzles… whether it was 3-D puzzles or figuring out a crossword. I also loved it when teachers would give the class an open-ended question and we had to work in groups to figure out the answer in our own way.

Even something as simple as playing checkers with my brothers gave me the chance to use strategy as a way to win the game. I honestly believe that it’s so important for kids to solve problems at a young age, as it helps them think critically and outside the box.

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So, Why Is It Important To Teach Kids Problem Solving?

I think these kinds of activities are so important for kids to do because it helps them learn how to think analytically and solve problems on their own. It's a great way to get kids to use their imaginations and be creative.

Rote memorization simply does not have the same effect. This type of learning is great for learning facts like historical dates, but it’s not going to help kids figure out how events in history happened and the results.

We take these problem-solving skills into college, the workforce, and travel . My ability to problem solve since childhood has certainly got me through many sticky situations while in a new city or country.

Additionally, problem-solving helps children learn how to find creative solutions to challenges they may face both in and out of the classroom . These activities can also be fun and used in cohesion with school or playtime.

17 Fun Problem-Solving Activities for Kids

1. marble mazes.

This activity was selected because it requires them to think spatially. Spatial learning will benefit kids when they start driving, riding a bike, playing sports,etc.

To do this activity in its simplest form, you will need a piece of paper, a pencil, and some marbles. First, draw a maze on a piece of paper using a pencil.

Make sure to create a start and finish point. Then, place the marbles at the start of the maze. The goal is to get the marbles from the start to the finish by tilting the paper and using gravity to guide the marbles through the maze.

Another example of a marble maze can involve using toilet paper rolls taped together to create a three-dimensional maze. The larger the maze, the harder you can make it.

Check Price on Amazon!

If you are not into the DIY method, you can always buy a toy maze on Amazon. A good 48 piece puzzle is the Melissa & Doug Underwater Ocean Floor puzzle.

2. The Tower Challenge

Building a tower gives kids the chance to think about gravity, structure, and balance.

To do this activity, you will need some building materials like legos, blocks, or even toilet paper rolls. The challenge is to see how high they can stack the materials without the tower toppling over.

This can be done individually or in teams. An activity like this is good for younger kids and is the building block to learning about harder topics like engineering.

3. The Egg Drop Challenge

The egg drop challenge helps kids learn how to engineer a solution that prevents something from breaking. It requires them to think critically about which materials will best protect something fragile like an egg when dropped from a height.

To do this activity, you will need some eggs and various materials such as straws, cotton balls, bubble wrap, etc. The goal is to construct a device that will protect an egg from breaking upon impact.

This can be done individually or in teams . Teams can even have a competition for the best egg drop device.

As children begin handling, shopping for, and cooking their own food, activities like this will help them understand how to handle breakable items like bottles, eggs, delicate fruit,.etc. Ideally, this is best for age groups 8 and up.

4. The Penny Drop Challenge

This activity was selected because it requires kids to think about physics and how different materials affect sound.

To do this activity, you will need a penny ( or another coin), a cup, and various materials such as paper towels, cotton balls, etc.

The goal is to drop the penny into the cup without making any noise. Begin by placing different materials into the cup and then drop the penny into it. The children should also drop the penny from different heights into the same material to see if/how the impact from a higher drop affects sound.

Group kids into teams or let them try it on their own.

Kids should make note of what type of sounds are made when the penny hits different materials. This is a great activity for kids who are interested in science and physics.

5. The Balloon Race Challenge

This activity was selected because it helps kids learn about aerodynamics and Bernoulli’s principle . It also requires them to think creatively about how to design a balloon-powered vehicle.

To do this activity, you will need balloons, straws, masking tape, and markers. The goal is to design a balloon-powered vehicle that can travel a distance of at least 10 feet. Kids can begin this activity by sketching out their designs on paper.

After they have a basic design, they can begin building their vehicle from various materials. Then kids can explain why they think the balloon traveled or did not travel as far as it did.

6. The Marshmallow Challenge

Marshmallows are not only delicious, but they are also soft and malleable. So kids can have fun using it for some construction projects.

This activity was selected because it requires kids to think creatively about how to build a structure using limited materials. It also helps them learn about engineering and work as a team.

To do this activity, you will need marshmallows and spaghetti noodles. The goal is to build the tallest free-standing structure possible using only marshmallows and spaghetti noodles. If you don't have spaghetti noodles, use something similar like pretzel sticks.

You may even want to establish certain rules like each team can only use a certain number of marshmallows or noodles. A time limit can also make it more fun and challenging.

For more fun activities, check out our post on problem solving exercises for team building .

7. The Balloon Pop Challenge

If you remember your childhood, you probably remember popping balloons for fun at times. But this activity is different because it requires kids to use strategy and critical thinking.

This activity was selected because it helps kids learn about patterns and problem-solving. It is also a lot of fun for kids who like popping balloons. The goal is to create a device that will allow them to pop a balloon without using their hands.

To do this activity, you will need balloons and various materials such as straws, string, paper clips, etc.

8. Picture Pieces Puzzle Game

As mentioned earlier, puzzles are a great pastime – especially in childhood. Kids must think critically about how to put the pieces together to create a certain picture. It also helps them learn about shapes, colors, and other concepts.

problem solving activities | how do you teach a child problem solving skills | are problem-solving games good for kids

You can take a medium to large picture and cut it into pieces. If you have younger kids, you may want to make the pieces larger. However, if you have kids closer to the 8-11 age range, you should be able to provide a challenge and make the pieces smaller.

9. Copy the Block Model

For this challenge, you can build a model out of blocks for the kids to copy. Put kids into groups and make sure each group has the same number of blocks you used for your model.

Make your model block as simple or complex as needed for your child's age group.

Set a time limit and make sure each group starts at the same time.

10. Team Scavenger Hunt

A scavenger hunt is great for kids because they have to search for items and use investigative skills. It is also a lot of fun and can be done both indoors and outdoors .

To do this activity, you will need to create a list of items for the kids to find. The items can be anything from common household items to things you would find outside.

These types of activities can also revolve around a theme like a holiday, movie, or book. For example, if the kids are fans of “Harry Potter” you can make a list of items to find that are related to the movie.

11. Obstacle Course

This activity requires kids to think creatively about how to get from one point to another while maneuvering around obstacles. If you have outdoor space, this can be done with common objects such as hula hoops, cones, etc.

If you don't have access to an outdoor space, you can use common household items to create an indoor obstacle course. For example, you can use chairs, blankets, pillows, etc.

Begin by setting up the course and then timing each child as they complete it. You can also have them race against each other to make it more fun.

Obstacle courses are also great because kids get to be physically active while they are thinking critically.

12. Reading Storybooks

There are many great benefits for kids that read storybooks. One of the excellent benefits is the ability to problem-solve. When they read the stories in the books, they see scenarios that cause them to be attached to the various characters they read about.

So, when they encounter a real-life problem, it is often productive to ask a child how their favorite character would solve that problem. Your kids can also be encouraged to come up with various options and possible outcomes for some of the situations they may encounter.

This not only helps kids solve various problems but become more independent as well.

13. Ask Them Open-Ended Questions

A good way to improve a child's ability to think critically and creatively and improve their ability to solve problems is by asking open-ended questions. It also helps them to develop healthy personalities .

There are no right or wrong answers to these questions. In addition, the solution requires more than a simple “yes” or “no” answer. Furthermore, it allows kids to put some extra thought into their responses.

Here are some examples of open-ended questions you may want to ask.

What did this experience teach you?
Was this easy? What was easy about it?
What this difficult? What is complicated about it?
What may happen next in this situation?
How did you come to this solution?
What, if anything, would you do differently next time?
What can we do to make things more fun next time?

14. Build Various Structures with Toys

Whether wooden blocks, LEGO blocks, or engineering blocks… giving your kid blocks to build whatever their minds can dream up is fun. In addition, it requires them to think about how they will make a structure, put the pieces together, and creatively ensure the building's function and design.

fun activities for kids | kids creative activities at home | fun activities for kids near me

You may also want to challenge them to build something more complicated and watch them use their brain power to make it happen.

15. Acting Out Skits

Impromptu activities like acting out skits help kids identify problems, develop solutions, and execute them. This process works with multiple kids being divided into teams.

First, you will want to write down different situations, such as resolving a disagreement between siblings or dealing with bullying on the playground on a piece of paper. Second, you will fold the paper and place it in a hat or bowl.

Third, each team will pick a scenario out of the hat. Finally, you can give the kids a few minutes to discuss their solution and act out.

16. Solving Moral Dilemmas

In this simple game, you will help your kids solve simple dilemmas they may find themselves in. You could write down a situation your child may find themselves in and help them learn the moral way to solve the problem.

For instance, “The cashier gave them an additional $5 change back on my purchase. What should they do?” Another scenario could be, “I saw my friend cheating on a test. Should I tell on them or let it go?” A third one could be, “I caught my friends stealing some gum from the store. What should I do?”

After writing down the dilemmas and placing them in a bowl, get each child to select one and read it aloud. Finally, you will help them devise morally correct solutions to the moral dilemma.

17. Animal Pairing Game

This is a fun and creative game to help your kids with focus, critical thinking, and team building skills . In addition, this activity requires an even number of players to participate (4, 6, 8, etc.)

Before starting the game, you will want to write the names of different animals twice, each on a separate slip of paper. Then pass out the slips of paper to each individual or team member, instructing them not to share with anyone the name of the animal they received.

Then the children will perform activities the animals might do without talking or making sounds. Some of these activities might include:

The way the animal cleans or grooms itself
The way the animal sleeps
The way the animal fights
The way the animal eats or drinks
The way the animal walks or runs

The goal is for each child to successfully pair up with the other child who has selected the same animal.

How Problem Solving in Childhood Helps in Adulthood

Children are not born with problem-solving skills. It is something that needs to be learned and developed over time .

From babies who learn how to communicate their needs to toddlers who figure out how to get what they want, to children who are starting to understand the consequences of their actions – problem-solving is a process that begins in childhood and continues into adulthood.

Some of the benefits of teaching problem-solving skills to children include:

Improved critical thinking skills
Better decision-making skills
Enhanced creativity
Improved communication and collaboration skills
Increased confidence

There are many ways to teach problem-solving skills to children. The activities mentioned above are just a few examples. It is important to find activities that are appropriate for the age and abilities of the child.

With practice, children will develop these skills and be better prepared to face challenges in both childhood and adulthood.

Final Thoughts About Fun Problem Solving Activities For Kids

These are just a few ideas to get you started on teaching your child crucial problem solving skills. Perhaps they’ve inspired to come with some of your own, or seek out others? The important thing is to make sure the activity is age-appropriate and challenging enough to engage the kids.

Problem-solving skills are important for kids to learn because they can be applied to various situations in life. These skills also promote critical thinking, which is an important life skill.

There are many other problem-solving activities for kids out there. In time, you’ll find the ones that work best for your child. And be sure not to forget about your own needs and self-improvement, both of which will make you a better parent and mentor. Here are some useful activities for adults to get your started.

Finally, if you want to level up your parenting skills, then check out this resource that will show you how to get your kids to listen WITHOUT yelling, nagging, or losing control .

problem solving activities for kids | problem solving activities for students | games that promote problem solving for kids

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12 Fascinating Forensic Science Activities For Kids

April 20, 2023 // by Lauren Du Plessis

Forensic science activities are an excellent way to engage students in learning while sparking their curiosity in various scientific fields. These hands-on activities foster critical thinking, problem-solving skills, and scientific curiosity- making learning enjoyable and interactive for students of all grade levels. In this article, we present a range of exciting forensic science activities that can be easily incorporated into your classroom; helping you foster an immersive, educational experience for your students.

Elementary School (Grades K-5)

Learning Objectives: Develop observation skills, understand basic forensic concepts, and cultivate scientific curiosity.

1. Fingerprint Fun

Ignite curiosity by showing students how to dust for fingerprints and then prompt them to marvel at their unique patterns. Dive into the fascinating world of fingerprint analysis and let young minds uncover the secrets of this essential forensic tool.

Modification: Use washable ink pads for younger students.

Learn More: Kcedventures

2. Mini Crime Scene Sleuths

Transform your classroom into an intriguing mock crime scene- urging young detectives to observe, document, and analyze the intricate details. Watch as they sharpen their critical thinking skills and learn the importance of careful observation in solving mysteries.

Modification: Simplify the crime scene for younger students or those with special needs.

Learn More: Poet Prints

3. Shoe Print Spies

Unravel hidden secrets in shoe print patterns at a simulated crime scene; letting students experience firsthand the value of this evidence in forensic investigations. Guide them through comparisons and pattern analysis whilst teaching them the significance of seemingly simple clues.

Modification: Use pre-made shoe print templates for students with limited motor skills.

Learn More: Teaching Displays

4. Mysterious Powder Mania

Embark on a captivating adventure with household powders as students transform into forensic chemists and identify mysterious substances. Teach them the basics of chemical analysis in forensics while fostering their scientific curiosity and problem-solving skills.

Safety Note: Ensure students wear gloves and goggles while handling substances.

Learn More: Teach Me Mommy

Middle School (Grades 6-8)

Learning Objectives: Enhance observation and analysis skills, explore various forensic techniques, and develop an understanding of forensic science applications.

5. Chromatography Detective

Delve into the vibrant world of chromatography as students separate ink colors in a mysterious note. Teach them the importance of ink analysis in solving cases while fostering an appreciation for the science behind everyday items.

Modification: Provide pre-cut filter paper strips for students with limited motor skills.

Learn More: Web Innate

6. Bone Identification Quest

Let students explore the captivating realm of forensic anthropology by examining and classifying various animal bones. Teach them to analyze skeletal features and understand the crucial role bones play in uncovering the past.

Modification: Provide labeled bone replicas for students who need additional guidance.

7. Document Examination Expedition

Equip your students with magnifying glasses and UV lights and send them on a thrilling mission to investigate altered or forged documents. Encourage them to analyze subtle differences and discover how keen observation can crack even the toughest cases.

Modification: Provide enlarged copies of documents for students with visual impairments.

8. Arson Investigation Adventure

Delve into the fascinating world of fire forensics by analyzing simulated fire patterns to determine the cause and origin of a fire. Teach students about the importance of this field in solving arson cases while emphasizing proper safety precautions.

Safety Note: Use images or videos of fire patterns rather than live demonstrations for safety purposes.

High School (Grades 9-12):

Learning Objectives: Develop advanced forensic analysis skills, understand the practical applications of forensic science, and explore various forensic career paths.

9. DNA Extraction Extravaganza

Captivate students with the wonders of DNA as they extract it from fruits or vegetables. Demonstrate the process used in forensic labs and show them the crucial role genetic evidence plays in solving crimes.

Safety Note: Ensure students wear gloves and goggles while handling chemicals and materials.

Learn More: Explore UT

10. Ballistics Gel Bonanza

Create ballistics gel and demonstrate the effect of projectiles on different materials; providing students with a hands-on understanding of the science behind ballistics and its impact on forensic investigations.

Modification: Use non-toxic, pre-made gelatin or silicone molds for students with allergies or sensitivities.

Learn More: Youtube

11. Fiber Forensics

Analyze various fabric fibers under a microscope to determine their origin; immersing students in the intricate world of fiber forensics. Encourage them to explore the significant role that fibers play in solving crimes- from clothing to carpet fibers, your students will explore them all!

Modification: Provide pre-mounted fiber slides for students with limited fine motor skills.

Learn More: Study

12. Handwriting Analysis Adventure

Examine different handwriting samples and challenge students to identify the author of a suspicious note. Teach them the importance of handwriting analysis in forensic investigations and how this skill can reveal hidden secrets.

Modification: Provide handwriting analysis worksheets for students who need additional guidance or practice.

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COMMENTS

Strengthening High School Students' Problem-Solving Skills
Finding, shaping, and solving problems puts high school students in charge of their learning and bolsters critical-thinking skills. As an educator for over 20 years, I've heard a lot about critical thinking, problem-solving, and inquiry and how they foster student engagement. However, I've also seen students draw a blank when they're ...
Why Every Educator Needs to Teach Problem-Solving Skills
Resolve Conflicts. In addition to increased social and emotional skills like self-efficacy and goal-setting, problem-solving skills teach students how to cooperate with others and work through disagreements and conflicts. Problem-solving promotes "thinking outside the box" and approaching a conflict by searching for different solutions.
Teaching problem solving: Let students get 'stuck' and 'unstuck'
Teaching problem solving: Let students get 'stuck' and 'unstuck'. This is the second in a six-part blog series on teaching 21st century skills, including problem solving , metacognition ...
Don't Just Tell Students to Solve Problems. Teach Them How
The UC San Diego problem-solving curriculum, Mjahed noted, is an opportunity for students to build the skills and the confidence to learn from their failures and to work outside their comfort zone. "And from there, they see pathways to real careers," he said. Jennifer Ogo, a teacher from Kearny High School, taught the problem-solving course ...
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Make students articulate their problem solving process . In a one-on-one tutoring session, ask the student to work his/her problem out loud. This slows down the thinking process, making it more accurate and allowing you to access understanding. When working with larger groups you can ask students to provide a written "two-column solution.".
Developing Problem-Solving Skills in High School Students: A
Problem-solving skills refer to the ability to identify, analyze, and solve problems effectively. These skills are not only valuable in academic settings but also in real-life situations and future careers. Developing problem-solving skills in high school students offers numerous benefits. Firstly, it enhances their critical thinking abilities ...
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Teach problem-solving skills in the context in which they will be used by students (e.g., mole fraction calculations in a chemistry course). Use real-life problems in explanations, examples, and exams. Do not teach problem solving as an independent, abstract skill. Help students understand the problem. In order to solve problems, students need ...
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Teaching problem-solving skills to high school students is an essential part of their education. It empowers them to handle various situations independently and with confidence. This skill plays a vital role in social-emotional learning, as it helps students understand the difference between big and small problems, and to determine when they ...
Critical Thinking Resources for High School Teachers
The site, which is part of the George Lucas Educational Foundation, is divided by grade level and has a special section focused on producing critical thinking high school students: Grades 9-12 High School. The site describes three fundamental skills it believes necessary for students to become lifelong learners in the 21 st Century:
Strategies for teaching metacognition in classrooms
Strategies for teaching metacognition in classrooms. This is the third piece in a six-part blog series on teaching 21st century skills, including problem solving , metacognition, critical thinking ...
Problem Solving Resources
Problem-solving is the ability to identify and solve problems by applying appropriate skills systematically. Problem-solving is a process—an ongoing activity in which we take what we know to discover what we don't know. It involves overcoming obstacles by generating hypo-theses, testing those predictions, and arriving at satisfactory solutions.
Practical Strategies for Teaching Social Problem-Solving in High School
Self-reflection and self-awareness are essential for effective social problem-solving. Here are two strategies to promote these skills: Encouraging students to identify their emotions and triggers: Teach students to recognize and label their emotions in various social situations. Help them identify triggers that may lead to emotional reactions ...
Improving 21st-century teaching skills: The key to effective 21st
The 21st-century skillset is generally understood to encompass a range of competencies, including critical thinking, problem solving, creativity, meta-cognition, communication, digital and technological literacy, civic responsibility, and global awareness (for a review of frameworks, see Dede, 2010).And nowhere is the development of such competencies more important than in developing country ...
Creative problem solving tools and skills for students and teachers
So, in this case, it may be beneficial to teach the individual parts of the process in isolation first. 1. Clarify: Before beginning to seek creative solutions to a problem, it is important to clarify the exact nature of that problem. To do this, students should do the following three things: i. Identify the Problem.
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of the public high school might develop further the problem solving skills of students. Thus, the purpose of the study was to determine the effectiveness of problem-based learning using a developed problem-based learning matrix in enhancing the level of problem solving skills of Grade 9 students in a public high school in Philippines. 2 ...
Problem-solving skills of high school chemistry students
The purpose for conducting this study was to determine the general problem-solving skills that students use in solving problems involving moles, stoichiometry, the gas laws, and molarity. The strategies were examined for success in problem solving for 266 students of varying proportional reasoning ability, using interviews incorporating the ...
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The impact of problem-solving instruction on middle school students' physical science learning: Interplays of knowledge, reasoning, and problem solving. EJMSTE . 2018;14(3):731-743. Vlachou A, Stavroussi P. Promoting social inclusion: A structured intervention for enhancing interpersonal problem‐solving skills in children with mild ...
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Moreover, from the students' responds of the questionnaire, it was found that an average of 73.86% of the students stated that they liked the teaching and learning processes. ... ISSN 2822-4353 Research Article Project - Based Learning Approach in Teaching: Enhancing Problem Solving Skills of Senior High School Students John Paul N. Cabotaje ...
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In the context of the knowledge-based economy, the intricate relationship between mathematics anxiety and problem-solving abilities among high school students in China is examined. This research uncovers the pervasive nature of mathematics anxiety, influenced primarily by external factors such as parental expectations, shedding light on the sources of anxiety. Additionally, it highlights the ...
Paducah Area Students Address 'Fast Fashion' at EcoThink Event
PADUCAH, Ky. - Local high school students from western Kentucky and southern Illinois put their problem solving skills to the test during the annual EcoThink project, challenging themselves to address environmental and sustainability issues through critical thinking exercises focused on teamwork and engineering concepts. "The students really enjoyed this opportunity," Paducah Tilghman ...
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Dr. Magnini recently hosted Buckingham County High School students, teaching them about business ownership options and practicing critical thinking by comparing franchise investment with independent restaurant ownership. High schoolers engage in business analysis with Dr. Magnini, fostering critical thinking and problem-solving skills
17 Fun Problem Solving Activities for Kids
4. The Penny Drop Challenge. This activity was selected because it requires kids to think about physics and how different materials affect sound. To do this activity, you will need a penny ( or another coin), a cup, and various materials such as paper towels, cotton balls, etc.
12 Fascinating Forensic Science Activities For Kids
Teach them the basics of chemical analysis in forensics while fostering their scientific curiosity and problem-solving skills. Safety Note: Ensure students wear gloves and goggles while handling substances. Learn More: Teach Me Mommy. Middle School (Grades 6-8) Learning Objectives: Enhance observation and analysis skills, explore various ...