problem solving skills for high school students

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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Home » Blog » General » Developing Social Skills: High School Scenarios for Problem Solving

Developing Social Skills: High School Scenarios for Problem Solving

Welcome to my blog! In today’s post, we will be discussing the importance of social skills in high school and exploring social problem-solving scenarios specifically designed for high school students. Developing strong social problem-solving skills can greatly benefit students in navigating various social situations and building positive relationships. So, let’s dive in!

Understanding Social Problem-Solving

Before we delve into the specific scenarios, let’s first understand what social problem-solving entails. Social problem-solving is the process of identifying, analyzing, and resolving social conflicts or challenges. It involves several key components, including active listening, empathy, generating multiple solutions, evaluating consequences, and implementing and reflecting on chosen solutions.

By developing social problem-solving skills, high school students can enhance their ability to communicate effectively, understand others’ perspectives, and make responsible decisions. These skills are essential for building healthy relationships, resolving conflicts, and navigating the complexities of the high school environment.

Common High School Social Scenarios

Now, let’s explore some common social scenarios that high school students often encounter. By examining these scenarios, we can better understand the challenges they face and the skills required to navigate them successfully.

Peer conflicts and disagreements

High school is a time when students are forming their identities and asserting their independence. As a result, conflicts and disagreements among peers are common. These situations require effective communication, active listening, and the ability to find mutually beneficial solutions.

Dealing with bullying or exclusion

Bullying and exclusion can have a significant impact on a student’s well-being and social development. High school students need to develop the skills to stand up against bullying, seek support from trusted adults, and foster a sense of inclusivity within their social circles.

Navigating group projects and teamwork

Group projects and teamwork are a regular part of high school academics. Students must learn to collaborate effectively, delegate tasks, and resolve conflicts that may arise within the group. These situations require strong communication, cooperation, and problem-solving skills.

Handling peer pressure and making responsible choices

Peer pressure is prevalent in high school, and students often face difficult decisions that can impact their well-being and future. Developing social problem-solving skills can empower students to make responsible choices, resist negative peer pressure, and prioritize their values and goals.

Resolving conflicts with teachers or authority figures

Conflicts with teachers or authority figures can be challenging for high school students. Resolving these conflicts requires effective communication, empathy, and the ability to find common ground. Developing these skills can help students advocate for themselves while maintaining respectful relationships.

Strategies for Developing Social Problem-Solving Skills

Now that we have explored common high school social scenarios, let’s discuss strategies for developing social problem-solving skills. These strategies can be practiced both in and outside of the classroom to enhance students’ ability to navigate social challenges effectively.

Active listening and empathy

Active listening involves fully engaging with others’ perspectives and emotions. By actively listening, students can better understand others’ needs and concerns, leading to more effective problem-solving. Empathy, on the other hand, allows students to put themselves in others’ shoes, fostering understanding and compassion.

Identifying emotions and perspectives

Understanding and identifying emotions, both in oneself and others, is crucial for effective social problem-solving. High school students should learn to recognize and manage their emotions while also considering the emotions and perspectives of those around them.

Generating multiple solutions

Encourage high school students to brainstorm multiple solutions to social problems. By considering various options, students can explore different perspectives and potential outcomes, leading to more informed decision-making.

Evaluating consequences and making informed decisions

Teach students to evaluate the potential consequences of each solution they generate. By considering the short-term and long-term effects, students can make more informed decisions that align with their values and goals.

Implementing and reflecting on chosen solutions

After selecting a solution, students should implement it and reflect on its effectiveness. This reflection allows students to learn from their experiences and make adjustments as needed. Encourage students to seek feedback from trusted adults or mentors to further enhance their problem-solving skills.

Tips for Practicing Social Problem-Solving

Now that we have discussed strategies for developing social problem-solving skills, let’s explore some practical tips for practicing these skills in real-life scenarios.

Role-playing and simulations

Role-playing and simulations provide opportunities for students to practice social problem-solving in a safe and controlled environment. Create scenarios that mirror real-life situations and encourage students to apply the strategies discussed earlier.

Collaborative problem-solving activities

Engage students in collaborative problem-solving activities that require teamwork and cooperation. These activities can be both academic and non-academic, such as group projects, community service initiatives, or team-building exercises.

Journaling and self-reflection exercises

Encourage students to keep a journal where they can reflect on their social interactions and problem-solving experiences. Journaling allows students to process their thoughts and emotions, identify areas for improvement, and track their progress over time.

Seeking guidance from trusted adults or mentors

Remind students that seeking guidance from trusted adults or mentors is a valuable resource. Encourage them to reach out to teachers, counselors, or speech-language pathologists who can provide support and guidance in developing social problem-solving skills.

Resources for Further Support

For ongoing support in developing social problem-solving skills, there are various resources available.

Books, websites, and apps for social problem-solving

There are several books, websites, and apps specifically designed to help high school students develop social problem-solving skills. These resources provide additional strategies, scenarios, and interactive activities to enhance students’ learning experience.

School-based programs and workshops

Many schools offer programs and workshops focused on social-emotional learning and problem-solving. These programs provide a structured environment for students to practice and develop their social skills alongside their peers.

Professional help from speech-language pathologists or counselors

If students are facing significant challenges in developing social problem-solving skills, seeking professional help from speech-language pathologists or counselors can be beneficial. These professionals can provide individualized support and interventions tailored to students’ specific needs.

Developing social problem-solving skills is crucial for high school students to navigate the complexities of social interactions and build positive relationships. By actively practicing and refining these skills, students can enhance their communication, empathy, and decision-making abilities. Remember, developing social problem-solving skills is an ongoing process, so be patient and persistent in your efforts. Start your EverydaySpeech Free trial today to access a wide range of resources and support for developing social problem-solving skills.

Thank you for reading, and I hope you found this post helpful! If you have any questions or would like to share your experiences, please leave a comment below. I look forward to hearing from you!

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March 29, 2023

Problem-Solving Activities for High School Students

Table of contents:.

Problem-solving activities are a great way to engage high school students in critical thinking. These activities can range from simple puzzles and games to complex group projects and challenges. They help students develop important skills such as communication, creativity, and decision-making. By participating in problem-solving activities, high school students can learn to approach problems in a structured and systematic way and to work effectively with others to find solutions.

The Importance of Problem-Solving Activities for High School Students

Problem-solving is a crucial skill for high school students to develop because it prepares them for the challenges they will face in their personal and professional lives. By engaging kids in problem-solving activities as early as possible, they learn to approach problems in a structured and systematic way and to work effectively with others to find solutions.

The benefits of problem-solving activities for high school students are numerous. These activities help students develop critical thinking skills , which are essential for making informed decisions and solving complex problems. Group problem-solving activities also promote engagement and collaboration, as students work together to find solutions to challenges. By participating in problem-solving activities, high school students can improve their decision-making abilities and become more confident and independent thinkers.

Ideas for Problem-Solving Activities

Here is a list of different types of problem-solving activities that teachers and schools can use to promote problem-solving, collaboration, creative and critical thinking, decision-making, and communication skills among students:

Escape room puzzle challenges: These challenges involve students working together to solve a series of puzzles in order to “escape” from a simulated scenario.
Brainstorming sessions: In these sessions, students work together to generate ideas and solutions to a given problem.
Debates: Debates involve students arguing for or against a given topic. This activity promotes communication and decision-making.
Role-play simulations: In these simulations, students take on different roles and work together to solve a simulated problem.
Creative problem-solving tasks: These tasks involve students using their creativity to find solutions to problems.
Collaborative project-based learning: In this approach, students work together on a project that involves solving a complex problem.

Another way to develop problem-solving skills is by using technology . However, it remains important to be aware of the negative influences of technology on child development. Therefore, it’s crucial to set some rules for technology at home . You can also use a parental control app like Safes to protect your child from online harm. With features like app monitoring and web filter, you can monitor their app and internet usage. You can download Safes for iOS , Android , Windows , and MacOS , and you can start with a free trial to explore its features.

Tips for Teachers and Schools

Here are some tips on how teachers and schools can use problem-solving activities effectively to promote high school students’ problem-solving skills:

Encourage teamwork: Problem-solving activities are most effective when students work together to find solutions. Teachers can encourage collaboration by assigning students to work in groups and by providing opportunities for students to share their ideas and solutions with one another.
Offer feedback and encouragement: Teachers can help students develop their problem-solving skills by providing feedback on their performance and by offering encouragement and support. This can help students feel more confident in their abilities and more motivated to continue improving.
Use real-world problems and scenarios: Problem-solving activities are most engaging when they involve real-world problems and scenarios that students can relate to. Teachers can incorporate current events, local issues, or other relevant topics into their problem-solving activities to make them more meaningful and engaging for students.
Incorporate a variety of activities to keep students engaged: To keep students engaged and motivated, teachers can incorporate a variety of different problem-solving activities into their lesson plans. This can include puzzles, games, debates, simulations, case studies, and more.

By following these tips, teachers and schools can use problem-solving activities effectively to promote high school students’ problem-solving skills.

students holding multiple scientific prototypes

In summary, problem-solving skills are crucial for high school students to develop as they prepare for academic and professional success. By engaging in problem-solving activities students can improve their critical thinking, decision-making, problem-solving, and collaboration skills. Teachers and schools can effectively promote problem-solving skills among their students by incorporating these activities into their curriculum. By doing so, they can help prepare their students for the challenges they will face in college and in the workforce.

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Problem-Solving

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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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40 Critical Thinking Questions for High School Students

How is electricity being produced from rainwater or do aliens exist if there are so many discoveries about them? High school students are certain to come across queries that question reality, everyday rules, general human existence, or anything out of nowhere!

Young minds are filled with an amazing potential to explore beyond their capabilities and hidden qualities. While high school students might question the existing realities of life, some students might not be aware of their imagination and thinking capacities. That is why it is important to nurture these growing minds with opportunities to question, understand, analyze, find evidence, and arrive at solutions.

In this case, critical thinking questions act as a helpful way to offer an opportunity to broaden their minds to unlimited knowledge and endless possibilities. When students are given a chance to think beyond the ordinary, they experience a sense of freedom in thinking and expressing their views.

Through critical thinking questions, they receive a wonderful chance to analyze, decode the information, and present their views without being right or wrong. Hence, the below-mentioned questions are drafted in a way to initiate abstract and informative conversations thereby boosting critical thinking.

Brain teasing critical thinking questions for high schoolers

Critical thinking skills are essential for measuring the imagination and creativity of students. High school students are likely to use the new age information and influence of others when processing their thoughts. Hence, the below-mentioned questions are a great way to channel their thoughts in a more positively empowered learning environment.

Do you think it is okay to give up your life if you had to save someone?
If you could go to your past, what would you change?
What is the joy of giving for you?
What is better – giving or receiving? Why?
If you can change some rules of the school, which ones would you change and why?
What if you know your future? What does it look like from your perspective?
What if you are dragged into a situation where you disagree with others?
What would you do if you are given a task against your willingness to complete it?
Would you like to do – go to your past or get to know your future? Why?
What would you choose, 1 million dollars or a lifetime free education? Why?
What is more important to you, knowledge or money?
How can you leverage the benefits of social media and how?
Do you think animals should be free or kept in a zoo?
What does life look like on the Earth 100 years from now?
Imagine a world without mobile phones. What would you do?
If you could choose any profession in the world, what would you choose? Why?
Would you rather devote your life to helping others through social activities or invest in building a business?
What is the most important matter of concern that the world needs to address?
Do you think the voting of high school students matters in Government concerns? Why?
Which aspect plays a major role in the success of individuals?
If you could change any one habit of your parents, what would it be?
If you could travel to any place in the world, where would you go? Why?
Imagine the world is facing a major power cut issue. What would you do and how would you face the situation?
What is more important, offering a home to the needy or offering food to the needy on an everyday basis?
How does the number 0 change life?
Should teenagers be allowed to make major life decisions?
Are friendships real in today’s world?
Does an influential person always influence others with actions and words?
If animals could talk to you, who would you choose to talk to?
What is the difference between happiness and achievements?
Do you think success is the same as happiness?
Imagine you have only 24 hours left on Earth. How would you spend it?
What if you are given the option to reside on another planet? What would you do and how?
Would you forgive your best friend if he/she commits a crime and is found guilty?
If your mother and best friend are sinking in two different boats and you have the opportunity to save anyone, who would you choose? Why?
Imagine you are stranded on an island and have access to 5 things. Which 5 things would you choose?
Which 3 elements make a stronger nation? Why?
What are the disadvantages of growing up? How would you tackle them?
Would you be blind or deaf? Why?
What if you could donate 50% of your wealth and have free food for life? What would you do?

Critical thinking in students: Why is it crucial?

High schoolers are on their way to exploring various subjects and acquiring knowledge from around the world. In such a phase, students must have the ability to think through things and make the right decision. Critical thinking empowers the brain to analyze and understand situations with complete evidence before concluding. Here’s how critical thinking shapes the life of high schoolers.

1. Develops Problem-Solving Skills

Students are sure to come across everyday problems and issues in their academic journey or personal life. While some students may develop stress, others might ignore it. However, the essence of critical thinking helps students solve these issues with intelligence. Whether it is figuring out about the project or solving an issue between friends, thinking and analyzing the possible solutions makes it easy to tackle situations.

2. Enhances Creativity

The advertisements you see every day often talk about the problem and how a product solves it. That’s exactly why you need to develop critical thinking skills. When you can identify the core issue and arrive at solutions only then can you think out of the box. Critical thinking helps students be creative with their solutions and find a way out amidst challenges.

3. Boosts Decision-Making Skills

With every project, assignment, or topic of your thesis , you need to take many decisions in the learning process. Here, critical thinking skills play a crucial role in helping you analyze, decode and disseminate information before making any decision.

4. Builds Open-mindedness

As growing individuals, it is important to be open-minded towards various problems and their suggestions. People who think critically are more likely to understand situations from different points of view. Hence, developing critical thinking skills helps you accept different perspectives and respect the opinions of others. The skill helps a long way when you need to work in a group on your projects. It is because you become capable of thinking from various perspectives.

5. Goal Setting

Success comes with proper planning and execution of tasks. However, you cannot study history if you are weak at math. Similarly, you cannot aim for a 60% growth in your academics if you have been growing at a pace of 30% in each examination. Critical thinking enables you to think practically and map your way out to reach your goals. When you think critically and practically, you can analyze your strengths and weaknesses thereby setting goals accurately.

Critical thinking indeed plays an essential role in shaping the mindset of students and exposing them to different skills simply by developing this one. As you take advantage of the critical thinking questions, know that it is important to keep questioning students to initiate conversations.

Whether it is reflective questions or would you rather-questions , these questions enable them to think beyond their imagination and dive into a world of possibilities. Apart from this, you may also involve students in interactive discussions that boost critical thinking skills.

Sananda Bhattacharya, Chief Editor of TheHighSchooler, is dedicated to enhancing operations and growth. With degrees in Literature and Asian Studies from Presidency University, Kolkata, she leverages her educational and innovative background to shape TheHighSchooler into a pivotal resource hub. Providing valuable insights, practical activities, and guidance on school life, graduation, scholarships, and more, Sananda’s leadership enriches the journey of high school students.

Explore a plethora of invaluable resources and insights tailored for high schoolers at TheHighSchooler, under the guidance of Sananda Bhattacharya’s expertise. You can follow her on Linkedin

Enhancing senior high school student engagement and academic performance using an inclusive and scalable inquiry-based program

Locke Davenport Huyer ORCID: orcid.org/0000-0003-1526-7122 1 , 2 na1 ,
Neal I. Callaghan ORCID: orcid.org/0000-0001-8214-3395 1 , 3 na1 ,
Sara Dicks 4 ,
Edward Scherer 4 ,
Andrey I. Shukalyuk 1 ,
Margaret Jou 4 &
Dawn M. Kilkenny ORCID: orcid.org/0000-0002-3899-9767 1 , 5

npj Science of Learning volume 5 , Article number: 17 ( 2020 ) Cite this article

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The multi-disciplinary nature of science, technology, engineering, and math (STEM) careers often renders difficulty for high school students navigating from classroom knowledge to post-secondary pursuits. Discrepancies between the knowledge-based high school learning approach and the experiential approach of future studies leaves some students disillusioned by STEM. We present Discovery , a term-long inquiry-focused learning model delivered by STEM graduate students in collaboration with high school teachers, in the context of biomedical engineering. Entire classes of high school STEM students representing diverse cultural and socioeconomic backgrounds engaged in iterative, problem-based learning designed to emphasize critical thinking concomitantly within the secondary school and university environments. Assessment of grades and survey data suggested positive impact of this learning model on students’ STEM interests and engagement, notably in under-performing cohorts, as well as repeating cohorts that engage in the program on more than one occasion. Discovery presents a scalable platform that stimulates persistence in STEM learning, providing valuable learning opportunities and capturing cohorts of students that might otherwise be under-engaged in STEM.

Subject integration and theme evolution of STEM education in K-12 and higher education research

Skill levels and gains in university STEM education in China, India, Russia and the United States

Exploring the impact of web-based inquiry on elementary school students’ science identity development in a STEM learning unit

Introduction.

High school students with diverse STEM interests often struggle to understand the STEM experience outside the classroom 1 . The multi-disciplinary nature of many career fields can foster a challenge for students in their decision to enroll in appropriate high school courses while maintaining persistence in study, particularly when these courses are not mandatory 2 . Furthermore, this challenge is amplified by the known discrepancy between the knowledge-based learning approach common in high schools and the experiential, mastery-based approaches afforded by the subsequent undergraduate model 3 . In the latter, focused classes, interdisciplinary concepts, and laboratory experiences allow for the application of accumulated knowledge, practice in problem solving, and development of both general and technical skills 4 . Such immersive cooperative learning environments are difficult to establish in the secondary school setting and high school teachers often struggle to implement within their classroom 5 . As such, high school students may become disillusioned before graduation and never experience an enriched learning environment, despite their inherent interests in STEM 6 .

It cannot be argued that early introduction to varied math and science disciplines throughout high school is vital if students are to pursue STEM fields, especially within engineering 7 . However, the majority of literature focused on student interest and retention in STEM highlights outcomes in US high school learning environments, where the sciences are often subject-specific from the onset of enrollment 8 . In contrast, students in the Ontario (Canada) high school system are required to complete Level 1 and 2 core courses in science and math during Grades 9 and 10; these courses are offered as ‘applied’ or ‘academic’ versions and present broad topics of content 9 . It is not until Levels 3 and 4 (generally Grades 11 and 12, respectively) that STEM classes become subject-specific (i.e., Biology, Chemistry, and/or Physics) and are offered as “university”, “college”, or “mixed” versions, designed to best prepare students for their desired post-secondary pursuits 9 . Given that Levels 3 and 4 science courses are not mandatory for graduation, enrollment identifies an innate student interest in continued learning. Furthermore, engagement in these post-secondary preparatory courses is also dependent upon achieving successful grades in preceding courses, but as curriculum becomes more subject-specific, students often yield lower degrees of success in achieving course credit 2 . Therefore, it is imperative that learning supports are best focused on ensuring that those students with an innate interest are able to achieve success in learning.

When given opportunity and focused support, high school students are capable of successfully completing rigorous programs at STEM-focused schools 10 . Specialized STEM schools have existed in the US for over 100 years; generally, students are admitted after their sophomore year of high school experience (equivalent to Grade 10) based on standardized test scores, essays, portfolios, references, and/or interviews 11 . Common elements to this learning framework include a diverse array of advanced STEM courses, paired with opportunities to engage in and disseminate cutting-edge research 12 . Therein, said research experience is inherently based in the processes of critical thinking, problem solving, and collaboration. This learning framework supports translation of core curricular concepts to practice and is fundamental in allowing students to develop better understanding and appreciation of STEM career fields.

Despite the described positive attributes, many students do not have the ability or resources to engage within STEM-focused schools, particularly given that they are not prevalent across Canada, and other countries across the world. Consequently, many public institutions support the idea that post-secondary led engineering education programs are effective ways to expose high school students to engineering education and relevant career options, and also increase engineering awareness 13 . Although singular class field trips are used extensively to accomplish such programs, these may not allow immersive experiences for application of knowledge and practice of skills that are proven to impact long-term learning and influence career choices 14 , 15 . Longer-term immersive research experiences, such as after-school programs or summer camps, have shown successful at recruiting students into STEM degree programs and careers, where longevity of experience helps foster self-determination and interest-led, inquiry-based projects 4 , 16 , 17 , 18 , 19 .

Such activities convey the elements that are suggested to make a post-secondary led high school education programs successful: hands-on experience, self-motivated learning, real-life application, immediate feedback, and problem-based projects 20 , 21 . In combination with immersion in university teaching facilities, learning is authentic and relevant, similar to the STEM school-focused framework, and consequently representative of an experience found in actual STEM practice 22 . These outcomes may further be a consequence of student engagement and attitude: Brown et al. studied the relationships between STEM curriculum and student attitudes, and found the latter played a more important role in intention to persist in STEM when compared to self-efficacy 23 . This is interesting given that student self-efficacy has been identified to influence ‘motivation, persistence, and determination’ in overcoming challenges in a career pathway 24 . Taken together, this suggests that creation and delivery of modern, exciting curriculum that supports positive student attitudes is fundamental to engage and retain students in STEM programs.

Supported by the outcomes of identified effective learning strategies, University of Toronto (U of T) graduate trainees created a novel high school education program Discovery , to develop a comfortable yet stimulating environment of inquiry-focused iterative learning for senior high school students (Grades 11 & 12; Levels 3 & 4) at non-specialized schools. Built in strong collaboration with science teachers from George Harvey Collegiate Institute (Toronto District School Board), Discovery stimulates application of STEM concepts within a unique term-long applied curriculum delivered iteratively within both U of T undergraduate teaching facilities and collaborating high school classrooms 25 . Based on the volume of medically-themed news and entertainment that is communicated to the population at large, the rapidly-growing and diverse field of biomedical engineering (BME) were considered an ideal program context 26 . In its definition, BME necessitates cross-disciplinary STEM knowledge focused on the betterment of human health, wherein Discovery facilitates broadening student perspective through engaging inquiry-based projects. Importantly, Discovery allows all students within a class cohort to work together with their classroom teacher, stimulating continued development of a relevant learning community that is deemed essential for meaningful context and important for transforming student perspectives and understandings 27 , 28 . Multiple studies support the concept that relevant learning communities improve student attitudes towards learning, significantly increasing student motivation in STEM courses, and consequently improving the overall learning experience 29 . Learning communities, such as that provided by Discovery , also promote the formation of self-supporting groups, greater active involvement in class, and higher persistence rates for participating students 30 .

The objective of Discovery , through structure and dissemination, is to engage senior high school science students in challenging, inquiry-based practical BME activities as a mechanism to stimulate comprehension of STEM curriculum application to real-world concepts. Consequent focus is placed on critical thinking skill development through an atmosphere of perseverance in ambiguity, something not common in a secondary school knowledge-focused delivery but highly relevant in post-secondary STEM education strategies. Herein, we describe the observed impact of the differential project-based learning environment of Discovery on student performance and engagement. We identify the value of an inquiry-focused learning model that is tangible for students who struggle in a knowledge-focused delivery structure, where engagement in conceptual critical thinking in the relevant subject area stimulates student interest, attitudes, and resulting academic performance. Assessment of study outcomes suggests that when provided with a differential learning opportunity, student performance and interest in STEM increased. Consequently, Discovery provides an effective teaching and learning framework within a non-specialized school that motivates students, provides opportunity for critical thinking and problem-solving practice, and better prepares them for persistence in future STEM programs.

Program delivery

The outcomes of the current study result from execution of Discovery over five independent academic terms as a collaboration between Institute of Biomedical Engineering (graduate students, faculty, and support staff) and George Harvey Collegiate Institute (science teachers and administration) stakeholders. Each term, the program allowed senior secondary STEM students (Grades 11 and 12) opportunity to engage in a novel project-based learning environment. The program structure uses the problem-based engineering capstone framework as a tool of inquiry-focused learning objectives, motivated by a central BME global research topic, with research questions that are inter-related but specific to the curriculum of each STEM course subject (Fig. 1 ). Over each 12-week term, students worked in teams (3–4 students) within their class cohorts to execute projects with the guidance of U of T trainees ( Discovery instructors) and their own high school teacher(s). Student experimental work was conducted in U of T teaching facilities relevant to the research study of interest (i.e., Biology and Chemistry-based projects executed within Undergraduate Teaching Laboratories; Physics projects executed within Undergraduate Design Studios). Students were introduced to relevant techniques and safety procedures in advance of iterative experimentation. Importantly, this experience served as a course term project for students, who were assessed at several points throughout the program for performance in an inquiry-focused environment as well as within the regular classroom (Fig. 1 ). To instill the atmosphere of STEM, student teams delivered their outcomes in research poster format at a final symposium, sharing their results and recommendations with other post-secondary students, faculty, and community in an open environment.

The general program concept (blue background; top left ) highlights a global research topic examined through student dissemination of subject-specific research questions, yielding multifaceted student outcomes (orange background; top right ). Each program term (term workflow, yellow background; bottom panel ), students work on program deliverables in class (blue), iterate experimental outcomes within university facilities (orange), and are assessed accordingly at numerous deliverables in an inquiry-focused learning model.

Over the course of five terms there were 268 instances of tracked student participation, representing 170 individual students. Specifically, 94 students participated during only one term of programming, 57 students participated in two terms, 16 students participated in three terms, and 3 students participated in four terms. Multiple instances of participation represent students that enrol in more than one STEM class during their senior years of high school, or who participated in Grade 11 and subsequently Grade 12. Students were surveyed before and after each term to assess program effects on STEM interest and engagement. All grade-based assessments were performed by high school teachers for their respective STEM class cohorts using consistent grading rubrics and assignment structure. Here, we discuss the outcomes of student involvement in this experiential curriculum model.

Student performance and engagement

Student grades were assigned, collected, and anonymized by teachers for each Discovery deliverable (background essay, client meeting, proposal, progress report, poster, and final presentation). Teachers anonymized collective Discovery grades, the component deliverable grades thereof, final course grades, attendance in class and during programming, as well as incomplete classroom assignments, for comparative study purposes. Students performed significantly higher in their cumulative Discovery grade than in their cumulative classroom grade (final course grade less the Discovery contribution; p < 0.0001). Nevertheless, there was a highly significant correlation ( p < 0.0001) observed between the grade representing combined Discovery deliverables and the final course grade (Fig. 2a ). Further examination of the full dataset revealed two student cohorts of interest: the “Exceeds Expectations” (EE) subset (defined as those students who achieved ≥1 SD [18.0%] grade differential in Discovery over their final course grade; N = 99 instances), and the “Multiple Term” (MT) subset (defined as those students who participated in Discovery more than once; 76 individual students that collectively accounted for 174 single terms of assessment out of the 268 total student-terms delivered) (Fig. 2b, c ). These subsets were not unrelated; 46 individual students who had multiple experiences (60.5% of total MTs) exhibited at least one occasion in achieving a ≥18.0% grade differential. As students participated in group work, there was concern that lower-performing students might negatively influence the Discovery grade of higher-performing students (or vice versa). However, students were observed to self-organize into groups where all individuals received similar final overall course grades (Fig. 2d ), thereby alleviating these concerns.

a Linear regression of student grades reveals a significant correlation ( p = 0.0009) between Discovery performance and final course grade less the Discovery contribution to grade, as assessed by teachers. The dashed red line and intervals represent the theoretical 1:1 correlation between Discovery and course grades and standard deviation of the Discovery -course grade differential, respectively. b , c Identification of subgroups of interest, Exceeds Expectations (EE; N = 99, orange ) who were ≥+1 SD in Discovery -course grade differential and Multi-Term (MT; N = 174, teal ), of which N = 65 students were present in both subgroups. d Students tended to self-assemble in working groups according to their final course performance; data presented as mean ± SEM. e For MT students participating at least 3 terms in Discovery , there was no significant correlation between course grade and time, while ( f ) there was a significant correlation between Discovery grade and cumulative terms in the program. Histograms of total absences per student in ( g ) Discovery and ( h ) class (binned by 4 days to be equivalent in time to a single Discovery absence).

The benefits experienced by MT students seemed progressive; MT students that participated in 3 or 4 terms ( N = 16 and 3, respectively ) showed no significant increase by linear regression in their course grade over time ( p = 0.15, Fig. 2e ), but did show a significant increase in their Discovery grades ( p = 0.0011, Fig. 2f ). Finally, students demonstrated excellent Discovery attendance; at least 91% of participants attended all Discovery sessions in a given term (Fig. 2g ). In contrast, class attendance rates reveal a much wider distribution where 60.8% (163 out of 268 students) missed more than 4 classes (equivalent in learning time to one Discovery session) and 14.6% (39 out of 268 students) missed 16 or more classes (equivalent in learning time to an entire program of Discovery ) in a term (Fig. 2h ).

Discovery EE students (Fig. 3 ), roughly by definition, obtained lower course grades ( p < 0.0001, Fig. 3a ) and higher final Discovery grades ( p = 0.0004, Fig. 3b ) than non-EE students. This cohort of students exhibited program grades higher than classmates (Fig. 3c–h ); these differences were significant in every category with the exception of essays, where they outperformed to a significantly lesser degree ( p = 0.097; Fig. 3c ). There was no statistically significant difference in EE vs. non-EE student classroom attendance ( p = 0.85; Fig. 3i, j ). There were only four single day absences in Discovery within the EE subset; however, this difference was not statistically significant ( p = 0.074).

The “Exceeds Expectations” (EE) subset of students (defined as those who received a combined Discovery grade ≥1 SD (18.0%) higher than their final course grade) performed ( a ) lower on their final course grade and ( b ) higher in the Discovery program as a whole when compared to their classmates. d – h EE students received significantly higher grades on each Discovery deliverable than their classmates, except for their ( c ) introductory essays and ( h ) final presentations. The EE subset also tended ( i ) to have a higher relative rate of attendance during Discovery sessions but no difference in ( j ) classroom attendance. N = 99 EE students and 169 non-EE students (268 total). Grade data expressed as mean ± SEM.

Discovery MT students (Fig. 4 ), although not receiving significantly higher grades in class than students participating in the program only one time ( p = 0.29, Fig. 4a ), were observed to obtain higher final Discovery grades than single-term students ( p = 0.0067, Fig. 4b ). Although trends were less pronounced for individual MT student deliverables (Fig. 4c–h ), this student group performed significantly better on the progress report ( p = 0.0021; Fig. 4f ). Trends of higher performance were observed for initial proposals and final presentations ( p = 0.081 and 0.056, respectively; Fig. 4e, h ); all other deliverables were not significantly different between MT and non-MT students (Fig. 4c, d, g ). Attendance in Discovery ( p = 0.22) was also not significantly different between MT and non-MT students, although MT students did miss significantly less class time ( p = 0.010) (Fig. 4i, j ). Longitudinal assessment of individual deliverables for MT students that participated in three or more Discovery terms (Fig. 5 ) further highlights trend in improvement (Fig. 2f ). Greater performance over terms of participation was observed for essay ( p = 0.0295, Fig. 5a ), client meeting ( p = 0.0003, Fig. 5b ), proposal ( p = 0.0004, Fig. 5c ), progress report ( p = 0.16, Fig. 5d ), poster ( p = 0.0005, Fig. 5e ), and presentation ( p = 0.0295, Fig. 5f ) deliverable grades; these trends were all significant with the exception of the progress report ( p = 0.16, Fig. 5d ) owing to strong performance in this deliverable in all terms.

The “multi-term” (MT) subset of students (defined as having attended more than one term of Discovery ) demonstrated favorable performance in Discovery , ( a ) showing no difference in course grade compared to single-term students, but ( b outperforming them in final Discovery grade. Independent of the number of times participating in Discovery , MT students did not score significantly differently on their ( c ) essay, ( d ) client meeting, or ( g ) poster. They tended to outperform their single-term classmates on the ( e ) proposal and ( h ) final presentation and scored significantly higher on their ( f ) progress report. MT students showed no statistical difference in ( i ) Discovery attendance but did show ( j ) higher rates of classroom attendance than single-term students. N = 174 MT instances of student participation (76 individual students) and 94 single-term students. Grade data expressed as mean ± SEM.

Longitudinal assessment of a subset of MT student participants that participated in three ( N = 16) or four ( N = 3) terms presents a significant trend of improvement in their ( a ) essay, ( b ) client meeting, ( c ) proposal, ( e ) poster, and ( f ) presentation grade. d Progress report grades present a trend in improvement but demonstrate strong performance in all terms, limiting potential for student improvement. Grade data are presented as individual student performance; each student is represented by one color; data is fitted with a linear trendline (black).

Finally, the expansion of Discovery to a second school of lower LOI (i.e., nominally higher aggregate SES) allowed for the assessment of program impact in a new population over 2 terms of programming. A significant ( p = 0.040) divergence in Discovery vs. course grade distribution from the theoretical 1:1 relationship was found in the new cohort (S 1 Appendix , Fig. S 1 ), in keeping with the pattern established in this study.

Teacher perceptions

Qualitative observation in the classroom by high school teachers emphasized the value students independently placed on program participation and deliverables. Throughout the term, students often prioritized Discovery group assignments over other tasks for their STEM courses, regardless of academic weight and/or due date. Comparing within this student population, teachers spoke of difficulties with late and incomplete assignments in the regular curriculum but found very few such instances with respect to Discovery -associated deliverables. Further, teachers speculated on the good behavior and focus of students in Discovery programming in contrast to attentiveness and behavior issues in their school classrooms. Multiple anecdotal examples were shared of renewed perception of student potential; students that exhibited poor academic performance in the classroom often engaged with high performance in this inquiry-focused atmosphere. Students appeared to take a sense of ownership, excitement, and pride in the setting of group projects oriented around scientific inquiry, discovery, and dissemination.

Student perceptions

Students were asked to consider and rank the academic difficulty (scale of 1–5, with 1 = not challenging and 5 = highly challenging) of the work they conducted within the Discovery learning model. Considering individual Discovery terms, at least 91% of students felt the curriculum to be sufficiently challenging with a 3/5 or higher ranking (Term 1: 87.5%, Term 2: 93.4%, Term 3: 85%, Term 4: 93.3%, Term 5: 100%), and a minimum of 58% of students indicating a 4/5 or higher ranking (Term 1: 58.3%, Term 2: 70.5%, Term 3: 67.5%, Term 4: 69.1%, Term 5: 86.4%) (Fig. 6a ).

a Histogram of relative frequency of perceived Discovery programming academic difficulty ranked from not challenging (1) to highly challenging (5) for each session demonstrated the consistently perceived high degree of difficulty for Discovery programming (total responses: 223). b Program participation increased student comfort (94.6%) with navigating lab work in a university or college setting (total responses: 220). c Considering participation in Discovery programming, students indicated their increased (72.4%) or decreased (10.1%) likelihood to pursue future experiences in STEM as a measure of program impact (total responses: 217). d Large majority of participating students (84.9%) indicated their interest for future participation in Discovery (total responses: 212). Students were given the opportunity to opt out of individual survey questions, partially completed surveys were included in totals.

The majority of students (94.6%) indicated they felt more comfortable with the idea of performing future work in a university STEM laboratory environment given exposure to university teaching facilities throughout the program (Fig. 6b ). Students were also queried whether they were (i) more likely, (ii) less likely, or (iii) not impacted by their experience in the pursuit of STEM in the future. The majority of participants (>82%) perceived impact on STEM interests, with 72.4% indicating they were more likely to pursue these interests in the future (Fig. 6c ). When surveyed at the end of term, 84.9% of students indicated they would participate in the program again (Fig. 6d ).

We have described an inquiry-based framework for implementing experiential STEM education in a BME setting. Using this model, we engaged 268 instances of student participation (170 individual students who participated 1–4 times) over five terms in project-based learning wherein students worked in peer-based teams under the mentorship of U of T trainees to design and execute the scientific method in answering a relevant research question. Collaboration between high school teachers and Discovery instructors allowed for high school student exposure to cutting-edge BME research topics, participation in facilitated inquiry, and acquisition of knowledge through scientific discovery. All assessments were conducted by high school teachers and constituted a fraction (10–15%) of the overall course grade, instilling academic value for participating students. As such, students exhibited excitement to learn as well as commitment to their studies in the program.

Through our observations and analysis, we suggest there is value in differential learning environments for students that struggle in a knowledge acquisition-focused classroom setting. In general, we observed a high level of academic performance in Discovery programming (Fig. 2a ), which was highlighted exceptionally in EE students who exhibited greater academic performance in Discovery deliverables compared to normal coursework (>18% grade improvement in relevant deliverables). We initially considered whether this was the result of strong students influencing weaker students; however, group organization within each course suggests this is not the case (Fig. 2d ). With the exception of one class in one term (24 participants assigned by their teacher), students were allowed to self-organize into working groups and they chose to work with other students of relatively similar academic performance (as indicated by course grade), a trend observed in other studies 31 , 32 . Remarkably, EE students not only excelled during Discovery when compared to their own performance in class, but this cohort also achieved significantly higher average grades in each of the deliverables throughout the program when compared to the remaining Discovery cohort (Fig. 3 ). This data demonstrates the value of an inquiry-based learning environment compared to knowledge-focused delivery in the classroom in allowing students to excel. We expect that part of this engagement was resultant of student excitement with a novel learning opportunity. It is however a well-supported concept that students who struggle in traditional settings tend to demonstrate improved interest and motivation in STEM when given opportunity to interact in a hands-on fashion, which supports our outcomes 4 , 33 . Furthermore, these outcomes clearly represent variable student learning styles, where some students benefit from a greater exchange of information, knowledge and skills in a cooperative learning environment 34 . The performance of the EE group may not be by itself surprising, as the identification of the subset by definition required high performers in Discovery who did not have exceptionally high course grades; in addition, the final Discovery grade is dependent on the component assignment grades. However, the discrepancies between EE and non-EE groups attendance suggests that students were engaged by Discovery in a way that they were not by regular classroom curriculum.

In addition to quantified engagement in Discovery observed in academic performance, we believe remarkable attendance rates are indicative of the value students place in the differential learning structure. Given the differences in number of Discovery days and implications of missing one day of regular class compared to this immersive program, we acknowledge it is challenging to directly compare attendance data and therefore approximate this comparison with consideration of learning time equivalence. When combined with other subjective data including student focus, requests to work on Discovery during class time, and lack of discipline/behavior issues, the attendance data importantly suggests that students were especially engaged by the Discovery model. Further, we believe the increased commute time to the university campus (students are responsible for independent transit to campus, a much longer endeavour than the normal school commute), early program start time, and students’ lack of familiarity with the location are non-trivial considerations when determining the propensity of students to participate enthusiastically in Discovery . We feel this suggests the students place value on this team-focused learning and find it to be more applicable and meaningful to their interests.

Given post-secondary admission requirements for STEM programs, it would be prudent to think that students participating in multiple STEM classes across terms are the ones with the most inherent interest in post-secondary STEM programs. The MT subset, representing students who participated in Discovery for more than one term, averaged significantly higher final Discovery grades. The increase in the final Discovery grade was observed to result from a general confluence of improved performance over multiple deliverables and a continuous effort to improve in a STEM curriculum. This was reflected in longitudinal tracking of Discovery performance, where we observed a significant trend of improved performance. Interestingly, the high number of MT students who were included in the EE group suggests that students who had a keen interest in science enrolled in more than one course and in general responded well to the inquiry-based teaching method of Discovery , where scientific method was put into action. It stands to reason that students interested in science will continue to take STEM courses and will respond favorably to opportunities to put classroom theory to practical application.

The true value of an inquiry-based program such as Discovery may not be based in inspiring students to perform at a higher standard in STEM within the high school setting, as skills in critical thinking do not necessarily translate to knowledge-based assessment. Notably, students found the programming equally challenging throughout each of the sequential sessions, perhaps somewhat surprising considering the increasing number of repeat attendees in successive sessions (Fig. 6a ). Regardless of sub-discipline, there was an emphasis of perceived value demonstrated through student surveys where we observed indicated interest in STEM and comfort with laboratory work environments, and desire to engage in future iterations given the opportunity. Although non-quantitative, we perceive this as an indicator of significant student engagement, even though some participants did not yield academic success in the program and found it highly challenging given its ambiguity.

Although we observed that students become more certain of their direction in STEM, further longitudinal study is warranted to make claim of this outcome. Additionally, at this point in our assessment we cannot effectively assess the practical outcomes of participation, understanding that the immediate effects observed are subject to a number of factors associated with performance in the high school learning environment. Future studies that track graduates from this program will be prudent, in conjunction with an ever-growing dataset of assessment as well as surveys designed to better elucidate underlying perceptions and attitudes, to continue to understand the expected benefits of this inquiry-focused and partnered approach. Altogether, a multifaceted assessment of our early outcomes suggests significant value of an immersive and iterative interaction with STEM as part of the high school experience. A well-defined divergence from knowledge-based learning, focused on engagement in critical thinking development framed in the cutting-edge of STEM, may be an important step to broadening student perspectives.

In this study, we describe the short-term effects of an inquiry-based STEM educational experience on a cohort of secondary students attending a non-specialized school, and suggest that the framework can be widely applied across virtually all subjects where inquiry-driven and mentored projects can be undertaken. Although we have demonstrated replication in a second cohort of nominally higher SES (S 1 Appendix , Supplementary Fig. 1 ), a larger collection period with more students will be necessary to conclusively determine impact independent of both SES and specific cohort effects. Teachers may also find this framework difficult to implement depending on resources and/or institutional investment and support, particularly if post-secondary collaboration is inaccessible. Offerings to a specific subject (e.g., physics) where experiments yielding empirical data are logistically or financially simpler to perform may be valid routes of adoption as opposed to the current study where all subject cohorts were included.

As we consider Discovery in a bigger picture context, expansion and implementation of this model is translatable. Execution of the scientific method is an important aspect of citizen science, as the concepts of critical thing become ever-more important in a landscape of changing technological landscapes. Giving students critical thinking and problem-solving skills in their primary and secondary education provides value in the context of any career path. Further, we feel that this model is scalable across disciplines, STEM or otherwise, as a means of building the tools of inquiry. We have observed here the value of differential inclusive student engagement and critical thinking through an inquiry-focused model for a subset of students, but further to this an engagement, interest, and excitement across the body of student participants. As we educate the leaders of tomorrow, we suggest that use of an inquiry-focused model such as Discovery could facilitate growth of a data-driven critical thinking framework.

In conclusion, we have presented a model of inquiry-based STEM education for secondary students that emphasizes inclusion, quantitative analysis, and critical thinking. Student grades suggest significant performance benefits, and engagement data suggests positive student attitude despite the perceived challenges of the program. We also note a particular performance benefit to students who repeatedly engage in the program. This framework may carry benefits in a wide variety of settings and disciplines for enhancing student engagement and performance, particularly in non-specialized school environments.

Study design and implementation

Participants in Discovery include all students enrolled in university-stream Grade 11 or 12 biology, chemistry, or physics at the participating school over five consecutive terms (cohort summary shown in Table 1 ). Although student participation in educational content was mandatory, student grades and survey responses (administered by high school teachers) were collected from only those students with parent or guardian consent. Teachers replaced each student name with a unique coded identifier to preserve anonymity but enable individual student tracking over multiple terms. All data collected were analyzed without any exclusions save for missing survey responses; no power analysis was performed prior to data collection.

Ethics statement

This study was approved by the University of Toronto Health Sciences Research Ethics Board (Protocol # 34825) and the Toronto District School Board External Research Review Committee (Protocol # 2017-2018-20). Written informed consent was collected from parents or guardians of participating students prior to the acquisition of student data (both post-hoc academic data and survey administration). Data were anonymized by high school teachers for maintenance of academic confidentiality of individual students prior to release to U of T researchers.

Educational program overview

Students enrolled in university-preparatory STEM classes at the participating school completed a term-long project under the guidance of graduate student instructors and undergraduate student mentors as a mandatory component of their respective course. Project curriculum developed collaboratively between graduate students and participating high school teachers was delivered within U of T Faculty of Applied Science & Engineering (FASE) teaching facilities. Participation allows high school students to garner a better understanding as to how undergraduate learning and career workflows in STEM vary from traditional high school classroom learning, meanwhile reinforcing the benefits of problem solving, perseverance, teamwork, and creative thinking competencies. Given that Discovery was a mandatory component of course curriculum, students participated as class cohorts and addressed questions specific to their course subject knowledge base but related to the defined global health research topic (Fig. 1 ). Assessment of program deliverables was collectively assigned to represent 10–15% of the final course grade for each subject at the discretion of the respective STEM teacher.

The Discovery program framework was developed, prior to initiation of student assessment, in collaboration with one high school selected from the local public school board over a 1.5 year period of time. This partner school consistently scores highly (top decile) in the school board’s Learning Opportunities Index (LOI). The LOI ranks each school based on measures of external challenges affecting its student population therefore schools with the greatest level of external challenge receive a higher ranking 35 . A high LOI ranking is inversely correlated with socioeconomic status (SES); therefore, participating students are identified as having a significant number of external challenges that may affect their academic success. The mandatory nature of program participation was established to reach highly capable students who may be reluctant to engage on their own initiative, as a means of enhancing the inclusivity and impact of the program. The selected school partner is located within a reasonable geographical radius of our campus (i.e., ~40 min transit time from school to campus). This is relevant as participating students are required to independently commute to campus for Discovery hands-on experiences.

Each program term of Discovery corresponds with a five-month high school term. Lead university trainee instructors (3–6 each term) engaged with high school teachers 1–2 months in advance of high school student engagement to discern a relevant overarching global healthcare theme. Each theme was selected with consideration of (a) topics that university faculty identify as cutting-edge biomedical research, (b) expertise that Discovery instructors provide, and (c) capacity to showcase the diversity of BME. Each theme was sub-divided into STEM subject-specific research questions aligning with provincial Ministry of Education curriculum concepts for university-preparatory Biology, Chemistry, and Physics 9 that students worked to address, both on-campus and in-class, during a term-long project. The Discovery framework therefore provides students a problem-based learning experience reflective of an engineering capstone design project, including a motivating scientific problem (i.e., global topic), subject-specific research question, and systematic determination of a professional recommendation addressing the needs of the presented problem.

Discovery instructors were volunteers recruited primarily from graduate and undergraduate BME programs in the FASE. Instructors were organized into subject-specific instructional teams based on laboratory skills, teaching experience, and research expertise. The lead instructors of each subject (the identified 1–2 trainees that built curriculum with high school teachers) were responsible to organize the remaining team members as mentors for specific student groups over the course of the program term (~1:8 mentor to student ratio).

All Discovery instructors were familiarized with program expectations and trained in relevant workspace safety, in addition to engagement at a teaching workshop delivered by the Faculty Advisor (a Teaching Stream faculty member) at the onset of term. This workshop was designed to provide practical information on teaching and was co-developed with high school teachers based on their extensive training and experience in fundamental teaching methods. In addition, group mentors received hands-on training and guidance from lead instructors regarding the specific activities outlined for their respective subject programming (an exemplary term of student programming is available in S 2 Appendix) .

Discovery instructors were responsible for introducing relevant STEM skills and mentoring high school students for the duration of their projects, with support and mentorship from the Faculty Mentor. Each instructor worked exclusively throughout the term with the student groups to which they had been assigned, ensuring consistent mentorship across all disciplinary components of the project. In addition to further supporting university trainees in on-campus mentorship, high school teachers were responsible for academic assessment of all student program deliverables (Fig. 1 ; the standardized grade distribution available in S 3 Appendix ). Importantly, trainees never engaged in deliverable assessment; for continuity of overall course assessment, this remained the responsibility of the relevant teacher for each student cohort.

Throughout each term, students engaged within the university facilities four times. The first three sessions included hands-on lab sessions while the fourth visit included a culminating symposium for students to present their scientific findings (Fig. 1 ). On average, there were 4–5 groups of students per subject (3–4 students per group; ~20 students/class). Discovery instructors worked exclusively with 1–2 groups each term in the capacity of mentor to monitor and guide student progress in all project deliverables.

After introducing the selected global research topic in class, teachers led students in completion of background research essays. Students subsequently engaged in a subject-relevant skill-building protocol during their first visit to university teaching laboratory facilities, allowing opportunity to understand analysis techniques and equipment relevant for their assessment projects. At completion of this session, student groups were presented with a subject-specific research question as well as the relevant laboratory inventory available for use during their projects. Armed with this information, student groups continued to work in their classroom setting to develop group-specific experimental plans. Teachers and Discovery instructors provided written and oral feedback, respectively , allowing students an opportunity to revise their plans in class prior to on-campus experimental execution.

Once at the relevant laboratory environment, student groups executed their protocols in an effort to collect experimental data. Data analysis was performed in the classroom and students learned by trial & error to optimize their protocols before returning to the university lab for a second opportunity of data collection. All methods and data were re-analyzed in class in order for students to create a scientific poster for the purpose of study/experience dissemination. During a final visit to campus, all groups presented their findings at a research symposium, allowing students to verbally defend their process, analyses, interpretations, and design recommendations to a diverse audience including peers, STEM teachers, undergraduate and graduate university students, postdoctoral fellows and U of T faculty.

Data collection

Teachers evaluated their students on the following associated deliverables: (i) global theme background research essay; (ii) experimental plan; (iii) progress report; (iv) final poster content and presentation; and (v) attendance. For research purposes, these grades were examined individually and also as a collective Discovery program grade for each student. For students consenting to participation in the research study, all Discovery grades were anonymized by the classroom teacher before being shared with study authors. Each student was assigned a code by the teacher for direct comparison of deliverable outcomes and survey responses. All instances of “Final course grade” represent the prorated course grade without the Discovery component, to prevent confounding of quantitative analyses.

Survey instruments were used to gain insight into student attitudes and perceptions of STEM and post-secondary study, as well as Discovery program experience and impact (S 4 Appendix ). High school teachers administered surveys in the classroom only to students supported by parental permission. Pre-program surveys were completed at minimum 1 week prior to program initiation each term and exit surveys were completed at maximum 2 weeks post- Discovery term completion. Surveys results were validated using a principal component analysis (S 1 Appendix , Supplementary Fig. 2 ).

Identification and comparison of population subsets

From initial analysis, we identified two student subpopulations of particular interest: students who performed ≥1 SD [18.0%] or greater in the collective Discovery components of the course compared to their final course grade (“EE”), and students who participated in Discovery more than once (“MT”). These groups were compared individually against the rest of the respective Discovery population (“non-EE” and “non-MT”, respectively ). Additionally, MT students who participated in three or four (the maximum observed) terms of Discovery were assessed for longitudinal changes to performance in their course and Discovery grades. Comparisons were made for all Discovery deliverables (introductory essay, client meeting, proposal, progress report, poster, and presentation), final Discovery grade, final course grade, Discovery attendance, and overall attendance.

Statistical analysis

Student course grades were analyzed in all instances without the Discovery contribution (calculated from all deliverable component grades and ranging from 10 to 15% of final course grade depending on class and year) to prevent correlation. Aggregate course grades and Discovery grades were first compared by paired t-test, matching each student’s course grade to their Discovery grade for the term. Student performance in Discovery ( N = 268 instances of student participation, comprising 170 individual students that participated 1–4 times) was initially assessed in a linear regression of Discovery grade vs. final course grade. Trends in course and Discovery performance over time for students participating 3 or 4 terms ( N = 16 and 3 individuals, respectively ) were also assessed by linear regression. For subpopulation analysis (EE and MT, N = 99 instances from 81 individuals and 174 instances from 76 individuals, respectively ), each dataset was tested for normality using the D’Agostino and Pearson omnibus normality test. All subgroup comparisons vs. the remaining population were performed by Mann–Whitney U -test. Data are plotted as individual points with mean ± SEM overlaid (grades), or in histogram bins of 1 and 4 days, respectively , for Discovery and class attendance. Significance was set at α ≤ 0.05.

Reporting summary

Further information on research design is available in the Nature Research Reporting Summary linked to this article.

Data availability

The data that support the findings of this study are available upon reasonable request from the corresponding author DMK. These data are not publicly available due to privacy concerns of personal data according to the ethical research agreements supporting this study.

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Acknowledgements

This study has been possible due to the support of many University of Toronto trainee volunteers, including Genevieve Conant, Sherif Ramadan, Daniel Smieja, Rami Saab, Andrew Effat, Serena Mandla, Cindy Bui, Janice Wong, Dawn Bannerman, Allison Clement, Shouka Parvin Nejad, Nicolas Ivanov, Jose Cardenas, Huntley Chang, Romario Regeenes, Dr. Henrik Persson, Ali Mojdeh, Nhien Tran-Nguyen, Ileana Co, and Jonathan Rubianto. We further acknowledge the staff and administration of George Harvey Collegiate Institute and the Institute of Biomedical Engineering (IBME), as well as Benjamin Rocheleau and Madeleine Rocheleau for contributions to data collation. Discovery has grown with continued support of Dean Christopher Yip (Faculty of Applied Science and Engineering, U of T), and the financial support of the IBME and the National Science and Engineering Research Council (NSERC) PromoScience program (PROSC 515876-2017; IBME “Igniting Youth Curiosity in STEM” initiative co-directed by DMK and Dr. Penney Gilbert). LDH and NIC were supported by Vanier Canada graduate scholarships from the Canadian Institutes of Health Research and NSERC, respectively . DMK holds a Dean’s Emerging Innovation in Teaching Professorship in the Faculty of Engineering & Applied Science, U of T.

Author information

These authors contributed equally: Locke Davenport Huyer, Neal I. Callaghan.

Authors and Affiliations

Institute of Biomedical Engineering, University of Toronto, Toronto, ON, Canada

Locke Davenport Huyer, Neal I. Callaghan, Andrey I. Shukalyuk & Dawn M. Kilkenny

Chemical Engineering and Applied Chemistry, University of Toronto, Toronto, ON, Canada

Locke Davenport Huyer

Translational Biology and Engineering Program, Ted Rogers Centre for Heart Research, University of Toronto, Toronto, ON, Canada

Neal I. Callaghan

George Harvey Collegiate Institute, Toronto District School Board, Toronto, ON, Canada

Sara Dicks, Edward Scherer & Margaret Jou

Institute for Studies in Transdisciplinary Engineering Education & Practice, University of Toronto, Toronto, ON, Canada

Dawn M. Kilkenny

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Contributions

LDH, NIC and DMK conceived the program structure, designed the study, and interpreted the data. LDH and NIC ideated programming, coordinated execution, and performed all data analysis. SD, ES, and MJ designed and assessed student deliverables, collected data, and anonymized data for assessment. SD assisted in data interpretation. AIS assisted in programming ideation and design. All authors provided feedback and approved the manuscript that was written by LDH, NIC and DMK.

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Correspondence to Dawn M. Kilkenny .

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Davenport Huyer, L., Callaghan, N.I., Dicks, S. et al. Enhancing senior high school student engagement and academic performance using an inclusive and scalable inquiry-based program. npj Sci. Learn. 5 , 17 (2020). https://doi.org/10.1038/s41539-020-00076-2

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Communication, Critical Thinking, Problem Solving: A Suggested Course for All High School Students in the 21st Century

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The skills of communication, critical thinking, and problem solving are essential to thriving as a citizen in the 21st century. These skills are required in order to contribute as a member of society, operate effectively in post-secondary institutions, and be competitive in the global market. Unfortunately they are not always intuitive or simple in nature. Instead these skills require both effort and time be devoted to identifying, learning, exploring, synthesizing, and applying them to different contexts and problems. This article argues that current high school students are hindered in their learning of communication, critical thinking, and problem solving by three factors: the structure of the current western education system, the complexity of the skills themselves, and the competence of the teachers to teach these skills in conjunction with their course material. The article will further advocate that all current high school students need the opportunity to develop these skills. Finally, it will posit that a course be offered to explicitly teach students these skills within a slightly modified western model of education.

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Course Syllabus and Outline

Title: Communication, Critical Thinking, and Problem Solving (an introduction)

Course Components

No exclusionary, discriminatory, or derogatory material will be taught in this course, nor will the content in this course be deemed controversial in any way.

Philosophy and Rationale

Much of our thinking, left to itself, is biased, distorted, partial, uniformed or down-right prejudiced. Yet the quality of our life and that of what we produce, make, or build depends precisely on the quality of our thought. Shoddy thinking is costly, both in money and in quality of life. Excellence in thought, however, must be systematically cultivated (Paul and Elder 2008 , p. 2).

The skills required of today’s youth are more pronounced than that of the past. Students are required to have basic knowledge of content in areas of Science, Math, and English; as well as technological skills, problem solving skills, critical thinking skills, and the ability to communicate (Sahlberg 2006 ). However, with the time constraints placed on teachers, knowledge outcomes taking priority on learning due to the high stakes standardized achievement tests, and an understanding that the particular skills of communication, critical thinking, and problem solving require explicit instruction (Rosefsky and Opfer 2012 ); students are not mastering these skills to an acceptable standard.

In order for students to acquire and master the skills necessary to compete and be successful in the work force, post secondary education, and life; students must have the opportunity to engage by learning these skills through practice, application, and devoted explicit attention. Furthermore, students must explore these skills without fear of failure but rather with hope that they can improve and move forward from the learning experience. In this way, learning these skills as a secondary item within the context of another content based course will not do the students justice.

Historically, the skills of sewing, cooking, woodworking, and mechanics where offered in high school as application based courses that required hands on and explorative learning with teacher guidance. More recently computer courses, and digital citizenship are taking hold in schools to teach students these skills. There is no reason why the skills of communication, critical thinking, and problem solving should be treated any differently.

Without the structure and organization of education making drastic changes to mandate these skills be made more of a priority in the classroom, it is feared that the teaching and learning of these skills will remain an oversight. It is unfortunate that the students; citizens, economic and market contributors of our future, will be underserved. It is with these reasons that this course offering takes place; such that an opportunity within the current educational structure can provide students the opportunity to guard themselves with new foundational skills for the future.

General Learner Expectations

By the end of this course, it is expected learners will have developed and ascertained explicit knowledge of communication, critical thinking and problem solving. More importantly, students will have acquired the skills of communication, critical thinking, and problem solving through application, exploration, and trial and error, such that they can utilize these skills in different contexts of their lives in preparation for the work force or post-secondary education.

Specific Learner Expectations

The following is a list of specific learner expectations for the course. Please note that the units identified for this course are titled ‘Skill-sets’ for a reason as they are not discrete topics to be taught in isolation, but rather guides toward the encompassing theme of acquiring these skills. This course is in no way designed as a check the outcome box course, nor is it organized in order by skill or outcome number. Rather, the outcomes and skill-sets must be taught in conjunction with each other through the duration of the course with trust being given to the fact that through student exploration and leadership; along side teacher guidance and facilitation, students will improve on their existing skill-set for these skills.

Skill Set A: Critical Thinking Skills Footnote 6

Knowledge Outcomes: (Students will be able to)

A.K.1 Define the difference between fact and inference.

A.K.2 Derive criteria for which to judge a problem or predicament.

A.K.3 List the elements of thought associated with critical thinking as per one critical thinking model (Paul and Elder, Rusten and Schuman).

A.K.4 Identify inherent and hidden bias in an argument.

A.K.5 Identify faults in thinking due to oversimplifying or over generalizing issues or problems.

A.K.6 Identify and state the purpose of thinking.

Skill Outcomes: (Students will be able to)

A.S.1 Utilize background knowledge to solve a problem or predicament.

A.S.2 Apply evidence to solve a problem or predicament.

A.S.3 Express an argument that is logical, clear, and concise.

A.S.4 Derive and model a process by which to critically analyze, think, and solve a problem or predicament that involves a reasonable, logical, and relevant thinking strategy.

A.S.5 Explore alternative options and methods before drawing a conclusion.

A.S.6 Illustrate and explore the consequences and implications following the solution of a problem or issue.

A.S.7 Model, display, or perform the ability to think critically through verbal, written, and physical means.

Attitudes Outcomes: (Students will)

A.A.1 Believe that it is possible for themselves to solve problems with a reasonable level of confidence.

A.A.2 Have confidence that they are able to ascertain information needed to help themselves think critically about a problem or issue.

A.A.3 Respect the diverse nature of thinking and problem solving that allows for others’ opinions and arguments to be taken into account without discrimination.

Skill Set B: Problem Solving Skills

B.K.1 Define convergent and divergent thinking.

B.K.2 State that for any given problem there is more than one problem solving strategy.

B.K.3 List possible problem solving strategies that exist.

B.K.4 State that problem solving strategies are used in context and explore the types of contexts that might exist.

B.K.5 Identify that for any problem solving strategy there must be an evaluative component and an ability to modify the strategy to fit a new context or problem.

B.S.1 Derive and model, illustrate, or describe a problem solving strategy that is context specific.

B.S.2 Derive and model a personal problem solving strategy to solve a personal problem.

B.S.3 Solve problems using mathematical reasoning.

B.S.4 Solve problems using technological means or supports.

B.S.5 Solve problems by modeling existing economic structures.

B.S.6 Solve problems by modeling existing political structures.

B.A.1 Have improved self-confidence in attempting to solve problems in a number of different contexts.

B.A.2 Be proud of the problem solving ability they have acquired.

B.A.3 Feel empowered to attempt new problem solving methods that are logical and relevant without fear of failure.

Skill Set C: Decision Making Skills

C.K.1 Identify that decision making is a process toward problem solving.

C.K.2 Identify personal bias in an argument.

C.K.3 State the difference between dialectic and rhetorical arguments.

C.K.4 Illustrate the types of decisions expected in personal, professional, and civic lives.

C.K.5 Describe the difference between rational and emotional expressions.

C.K.6 State and explain the difference between normative and naturalistic decision making.

C.K.7 Define the term dilemma.

C.K.8 State that the primary purpose of decision making is to decide on the best option, or provide maximum utility.

C.K.9 State that decision making can be made based on what is most consistent with personal beliefs or past experiences.

C.K.10 Identify that there is uncertainty and risk associated with every decision.

C.S.1 Construct a decision making process that includes identification, evidence, evaluation and modification of a problem.

C.S.2 Construct and apply a method of decision making to solve personal problems.

C.S.3 Construct and apply a method of decision making to solve professional problems.

C.S.4 Construct and apply a method of decision making to solve civic problems.

C.S.5 Examine positive and negative methods of modifying and changing decisions after they have been made.

C.S.6 Examine circumstances by which to modify, change, or renegotiate a decision.

Attitude Outcomes: (Students will)

C.A.1 Acknowledge that a commitment needs to be made upon making a decision.

C.A.2 Take ownership of decisions made using the decision making skills.

C.A.3 Understand that decisions require a course of action that is intended to yield results that are satisfying for special individuals.

C.A.4 Reflect on decisions made in their life and decide if they were appropriate or not.

Skill Set D: Communication Skills

Knowledge outcomes: (students will be able to).

D.K.1 Identify factors affecting communication.

D.K.2 State that communication involves more than one person.

D.K.3 Identify and explore the roles of speaker and listener in any conversation.

D.K.4 List and explore different environments involving communication (i.e.; formal language vs. slang, workplace vs. home life).

D.K.5 Describe the difference between teamwork and collaboration.

D.K.6 Describe what effective and ineffective communication looks, sounds, and feels like.

D.K.7 Explain the role of respect, honesty, fairness, and reason in any communication interaction.

D.S.1 Model and illustrate different conflict resolution strategies.

D.S.2 Identify and illustrate factors affecting teamwork.

D.S.3 Communicate effectively with peers while working collaboratively as a team.

D.S.4 Communicate effectively with teachers and parents regarding conflicts and successes.

D.S.5 Communicate clearly, logically, and precisely in verbal and written modes.

D.S.6 Ask and accept help in communicating when needed.

D.A.1 Feel empowered to communicate with peers.

D.A.2 Have confidence in the skill of communicating to discuss difficult issues with parents, teachers, and employers.

D.A.3 Feel empowered to ask and accept help by communicating in an appropriate fashion without fear of rejection or judgment.

Course Assessment

The assessment for this course is by way of individual student improvement in conjunction with final skill aptitude of the above stated skill sets by course end. This improvement and aptitude can be measured through a number of different means and will depend on the structure of the course as arranged and organized by the teacher. Outlined below are some classroom activities and possible assessments that might be of benefit to teachers planning this course.

Activities:

A pre and post written statement of the intention for being in the course and the problems and skills a student would like to solve and understand.

Assessed formatively (both pre and post) for critical thinking skills such as clarity of work, logic, reasoning, and evidence provided.

Pre and post formative assessments then evaluated for level of improvement.

Debate as a form of argument, decision making, communication and problem solving.

Following and respecting debate rules and roles of speaker/listener.

Utilizing rubrics for argument, decision making, communication and problem solving.

Market modeling—modeling the course as a competitive market with students given roles based on an application from them on their expertise and motivation toward the given problem. The roles would dictate a level of income for the student as well as a level of responsibility and leadership for them.

Assessed by way of improvement and movement ‘up the market ladder’—i.e.—what by way of promotion, what conflict resolution strategies or problems needed to be overcome, how long did it take to resolve or solve the problem?

Take into account rationale for why students have chosen their particular role (provided this rationale is given in a clear, appropriate, relevant, and significant manner)—i.e. standard of living, other priorities at the time etc.

Socratic Seminar on issue at hand to interpret and illustrate improvement in speaking and communicating an argument.

Assessed by way of quality and strength of participation and argument.

Resume of students skills ascertained and improved on through the course.

Cross curricular problems and projects modeling real life i.e. effects of globalization, and marketization on students by multinational companies. Projects to be displayed and presented to the class.

Assessed by way of rubrics (teacher and peer).

Likert scale survey for teacher and student on level of improvement of outcomes throughout the course.

Utilization of pre-existing rubrics i.e. Decision Making (Jonassen 2012 ).

Cornell CT Test level X for critical thinking as a pre and post test? (a quantitative assessment ordered from http://www.criticalthinking.com/getProductDetails.do?code=c&id=05501 ) (Ennis and Millman 1985 ).

Assessment strategies as well as possible outcomes for skill-sets can be found in Greenstein’s ( 2012 ), Assessing 21st Century Skills: A guide to evaluating mastery and authentic learning .

It is expected that all students will learn skill-set outcomes through the duration of the course. The question is how much will be learned? The answer depends on the individual student as well as their incoming skill level in each given area. In this case equal does not mean equitable and the goal of assessment for this course is to ascertain what improvement as well as final level of understanding an individual student has.

It should be stated that the nature of the course is student-centered and driven by the student. The teacher, however, is responsible for setting up the course and providing students an opportunity to explore this learning. Therefore, the teacher must come up with valid, rich, open activities for students to work within while at the same time ideally allowing the students to come up with the problems, scenarios, and arguments with which to discuss and solve. Explicit instruction may be necessary but should be severely limited allowing students ample opportunity for application and practice.

It is highly recommended that students work the duration of this course in groups (and differing groups) as it is here that communication, collaboration, and teamwork skills will be developed. It is further recommended that students be a part of the assessment process in deciding on the nature of the assessments, the criteria for the assessment, and in self and peer assessment. Allowing students to direct and lead requires trust and openness on the part of the teacher but is in fact part of the learning process.

Learning Resources

Since the premise of this course is for the teacher to be a ‘guide on the side’ and not a ‘sage on the stage’, there are no required learning resources for this course. However, it is recommended that teachers undertake professional development in the skill-set areas to ensure they have developed the necessary skills to pass on. Books such as: Becoming a Critically Reflective Teacher by Brookfield, Learning to Solve Problems: A Handbook for Designing Problem - Solving Learning Environments by Jonassen, 7 Habits of Highly Effective People , Crucial Conversations, and The 5 Elements of Effective Thinking would be an introduction. Journal articles and professional publications regarding 21st century skills and the development of these would be helpful. Finally, professional development seminars or sessions by leading experts such as Richard Paul from The Foundation for Critical Thinking would be almost necessary.

From this learning, the teacher will need to develop a tool kit of resources at their disposal in which to best help their students. The nature of the course being student-centered will require a teacher to be flexible in the work that is undertaken. The teacher will also have to be reactive to issues, problems, and learning scenarios that take place in the classroom. However, as this is a course in allowing the students to ascertain skills in problem solving, critical thinking, and communication, it must be mentioned that it is the students who are doing the brunt of the work and actually doing the problem solving and critical thinking themselves. For instance, it would not be sufficient for a question to be: What book should we read to learn critical thinking? And have the answer to the problem be: go ask the teacher and he/she will tell us. Rather the answer should be: let us go to the library or use the internet and find out which book is the best book. What options are available? What type of critical thinking are we looking at? What is critical thinking? Who are the leading experts in the field? What bias do they have? Where can I actually find or order these books? What cost and what is my budget? In the end, a seemingly simple question—is wrought with learning experiences by the student provided the teacher take a backburner to the work and allow the student to take the reins.

Course Evaluation

The open nature of this course allows for a teacher at any time to make changes to the structure, organization, and assessment of the course due to evaluation and reflection. The evaluation and reflection of this course should therefore be ongoing by the student and teacher immersed in the learning environment. The teacher is responsible for periodically seeking feedback from students regarding the nature of the course, as well as professionally reflecting themselves on the presentation of the course to their students.

The teacher is also responsible for keeping records of the course, as well as feedback collected that identifies the (a) strengths and weaknesses of the course as it is being facilitated, (b) activities and assessments being implemented in the course, and (c) improvements to the course for a later date. The teacher should ideally create a long range plan (or running calendar) that becomes more descriptive as the course proceeds, about the level of difficulty, quality of problems, activities, resources, feedback, and assessments being utilized in the course to reference at a later date. Finally, the teacher should be able to provide evidence to the local school authority at any time in order for the authority to monitor, evaluate, and report progress should it be required.

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Carlgren, T. Communication, Critical Thinking, Problem Solving: A Suggested Course for All High School Students in the 21st Century. Interchange 44 , 63–81 (2013). https://doi.org/10.1007/s10780-013-9197-8

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Published : 05 December 2013

Issue Date : December 2013

DOI : https://doi.org/10.1007/s10780-013-9197-8

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Helping Students Hone Their Critical Thinking Skills

Used consistently, these strategies can help middle and high school teachers guide students to improve much-needed skills.

Middle school students involved in a classroom discussion

Critical thinking skills are important in every discipline, at and beyond school. From managing money to choosing which candidates to vote for in elections to making difficult career choices, students need to be prepared to take in, synthesize, and act on new information in a world that is constantly changing.

While critical thinking might seem like an abstract idea that is tough to directly instruct, there are many engaging ways to help students strengthen these skills through active learning.

Make Time for Metacognitive Reflection

Create space for students to both reflect on their ideas and discuss the power of doing so. Show students how they can push back on their own thinking to analyze and question their assumptions. Students might ask themselves, “Why is this the best answer? What information supports my answer? What might someone with a counterargument say?”

Through this reflection, students and teachers (who can model reflecting on their own thinking) gain deeper understandings of their ideas and do a better job articulating their beliefs. In a world that is go-go-go, it is important to help students understand that it is OK to take a breath and think about their ideas before putting them out into the world. And taking time for reflection helps us more thoughtfully consider others’ ideas, too.

Teach Reasoning Skills

Reasoning skills are another key component of critical thinking, involving the abilities to think logically, evaluate evidence, identify assumptions, and analyze arguments. Students who learn how to use reasoning skills will be better equipped to make informed decisions, form and defend opinions, and solve problems.

One way to teach reasoning is to use problem-solving activities that require students to apply their skills to practical contexts. For example, give students a real problem to solve, and ask them to use reasoning skills to develop a solution. They can then present their solution and defend their reasoning to the class and engage in discussion about whether and how their thinking changed when listening to peers’ perspectives.

A great example I have seen involved students identifying an underutilized part of their school and creating a presentation about one way to redesign it. This project allowed students to feel a sense of connection to the problem and come up with creative solutions that could help others at school. For more examples, you might visit PBS’s Design Squad , a resource that brings to life real-world problem-solving.

Ask Open-Ended Questions

Moving beyond the repetition of facts, critical thinking requires students to take positions and explain their beliefs through research, evidence, and explanations of credibility.

When we pose open-ended questions, we create space for classroom discourse inclusive of diverse, perhaps opposing, ideas—grounds for rich exchanges that support deep thinking and analysis.

For example, “How would you approach the problem?” and “Where might you look to find resources to address this issue?” are two open-ended questions that position students to think less about the “right” answer and more about the variety of solutions that might already exist.

Journaling, whether digitally or physically in a notebook, is another great way to have students answer these open-ended prompts—giving them time to think and organize their thoughts before contributing to a conversation, which can ensure that more voices are heard.

Once students process in their journal, small group or whole class conversations help bring their ideas to life. Discovering similarities between answers helps reveal to students that they are not alone, which can encourage future participation in constructive civil discourse.

Teach Information Literacy

Education has moved far past the idea of “Be careful of what is on Wikipedia, because it might not be true.” With AI innovations making their way into classrooms, teachers know that informed readers must question everything.

Understanding what is and is not a reliable source and knowing how to vet information are important skills for students to build and utilize when making informed decisions. You might start by introducing the idea of bias: Articles, ads, memes, videos, and every other form of media can push an agenda that students may not see on the surface. Discuss credibility, subjectivity, and objectivity, and look at examples and nonexamples of trusted information to prepare students to be well-informed members of a democracy.

One of my favorite lessons is about the Pacific Northwest tree octopus . This project asks students to explore what appears to be a very real website that provides information on this supposedly endangered animal. It is a wonderful, albeit over-the-top, example of how something might look official even when untrue, revealing that we need critical thinking to break down “facts” and determine the validity of the information we consume.

A fun extension is to have students come up with their own website or newsletter about something going on in school that is untrue. Perhaps a change in dress code that requires everyone to wear their clothes inside out or a change to the lunch menu that will require students to eat brussels sprouts every day.

Giving students the ability to create their own falsified information can help them better identify it in other contexts. Understanding that information can be “too good to be true” can help them identify future falsehoods.

Provide Diverse Perspectives

Consider how to keep the classroom from becoming an echo chamber. If students come from the same community, they may have similar perspectives. And those who have differing perspectives may not feel comfortable sharing them in the face of an opposing majority.

To support varying viewpoints, bring diverse voices into the classroom as much as possible, especially when discussing current events. Use primary sources: videos from YouTube, essays and articles written by people who experienced current events firsthand, documentaries that dive deeply into topics that require some nuance, and any other resources that provide a varied look at topics.

I like to use the Smithsonian “OurStory” page , which shares a wide variety of stories from people in the United States. The page on Japanese American internment camps is very powerful because of its first-person perspectives.

Practice Makes Perfect

To make the above strategies and thinking routines a consistent part of your classroom, spread them out—and build upon them—over the course of the school year. You might challenge students with information and/or examples that require them to use their critical thinking skills; work these skills explicitly into lessons, projects, rubrics, and self-assessments; or have students practice identifying misinformation or unsupported arguments.

Critical thinking is not learned in isolation. It needs to be explored in English language arts, social studies, science, physical education, math. Every discipline requires students to take a careful look at something and find the best solution. Often, these skills are taken for granted, viewed as a by-product of a good education, but true critical thinking doesn’t just happen. It requires consistency and commitment.

In a moment when information and misinformation abound, and students must parse reams of information, it is imperative that we support and model critical thinking in the classroom to support the development of well-informed citizens.

Engaging Problem Solving Activities For High School Students

In today’s world, strong problem solving skills are more important than ever before. Employers highly value candidates who can think critically and creatively to overcome challenges. If you’re looking for ways to sharpen your high school student’s problem solving abilities, you’ve come to the right place.

Here’s a quick overview of the top problem solving activities we’ll cover in this guide: group challenges like escape rooms, individual logic puzzles and riddles, project-based learning through coding and engineering tasks, and conversational problem solving through Socratic seminars.

Group Challenges and Escape Rooms

Engaging high school students in problem-solving activities is crucial for their cognitive development and critical thinking skills. One popular and effective approach is through group challenges and escape rooms.

These activities not only promote teamwork and collaboration but also provide an exciting and immersive learning experience.

What Are Escape Rooms and Why Are They Effective?

Escape rooms are physical adventure games where participants are “locked” in a room and must solve puzzles and find clues to escape within a set time limit. These rooms are designed to challenge participants’ problem-solving abilities, logical thinking, and decision-making skills.

View this post on Instagram A post shared by NoWayOut Premium Escape Rooms (@nowayout_dubai)

The immersive nature of escape rooms creates an exciting and high-stakes environment that motivates students to think creatively and work together as a team.

Research has shown that escape rooms are highly effective in improving students’ problem-solving and critical-thinking skills.

According to a study from BMC Medical Education , escape rooms improve student engagement and learning. This activity can increase motivation and enhance teamwork skills.

The challenging and interactive nature of escape rooms makes them a valuable tool for engaging high school students in problem-solving activities.

Tips for Creating Your Own Escape Room

If you want to create your own escape room for high school students, here are some tips to make it a memorable and effective experience:

Theme and Storyline: Choose an engaging theme or storyline that will capture the students’ interest and make the experience more immersive.
Puzzles and Challenges: Design a variety of puzzles and challenges that require critical thinking, problem-solving, and teamwork to solve.
Time Limit: Set a reasonable time limit to create a sense of urgency and keep the students engaged throughout the activity.
Feedback and Reflection: Provide feedback and encourage students to reflect on their problem-solving strategies and teamwork skills after completing the escape room.

Individual Logic Puzzles and Riddles

Benefits of logic puzzles.

Logic puzzles are a great way to engage high school students in problem-solving activities. These puzzles require students to think critically, analyze information, and use deductive reasoning to find solutions.

They help develop cognitive skills such as logical thinking, attention to detail, and problem-solving abilities. By solving these puzzles individually, students also learn to work independently and trust their own reasoning abilities.

According to Psychology Today , logic puzzles can improve memory, enhance problem-solving skills, and boost overall brain health. They provide mental stimulation and challenge students to think outside the box.

Moreover, logic puzzles are a fun and engaging way to learn, making the learning process enjoyable and captivating for high school students.

Examples of Engaging Logic Puzzles

There are various types of logic puzzles and riddles that high school students can enjoy. Here are a few examples:

Grid-based puzzles: These puzzles require students to fill in a grid by using clues to determine the correct arrangement of elements. Sudoku is a popular example of a grid-based logic puzzle.
Number series puzzles: In these puzzles, students need to find the missing number or the pattern in a given series of numbers. This helps develop numerical reasoning and pattern recognition skills.
Mystery riddles: These riddles present a scenario or a problem that students need to solve by using logic and deduction. They often involve a crime or a mysterious situation that requires careful analysis to find the solution.

These examples are just a starting point, and there are countless logic puzzles and riddles available online or in puzzle books that can keep high school students engaged and challenged.

Tips for Using Riddles and Brain Teasers

When using riddles and brain teasers as problem-solving activities, it’s important to keep a few things in mind:

Start with easier puzzles: Begin with puzzles that are relatively easy to solve, and gradually increase the difficulty level. This allows students to build confidence and develop their problem-solving skills.
Encourage collaboration: While individual puzzles are beneficial, group activities can foster teamwork and collaboration. Consider incorporating group discussions or competitions to promote collaboration and peer learning.
Provide hints and guidance: If students get stuck, offer hints or guidance to help them move forward. This prevents frustration and keeps the learning process enjoyable.
Reflect on the solution: After solving a puzzle, encourage students to reflect on the problem-solving process. Discuss the strategies they used, the challenges they faced, and the lessons they learned. This promotes metacognition and helps students improve their problem-solving skills.

By incorporating individual logic puzzles and riddles into problem-solving activities, high school students can have a great time while developing essential cognitive skills and enhancing their ability to think critically and analytically.

Project-Based Learning Through STEM

Project-Based Learning (PBL) is an effective teaching method that encourages students to actively engage in real-world problem-solving . When combined with the subjects of Science, Technology, Engineering, and Mathematics (STEM), it creates a powerful learning experience for high school students.

PBL through STEM not only helps students develop critical thinking and problem-solving skills, but also fosters creativity, collaboration, and communication abilities.

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Coding Challenges

Coding challenges are an excellent way to introduce high school students to the world of computer programming. These challenges allow students to apply their logical thinking and problem-solving skills to create programs or solve coding problems.

Online platforms like Codecademy provide a wide range of coding challenges and tutorials for students to enhance their coding abilities. These challenges can be related to creating games, building websites, or developing mobile applications.

By engaging in coding challenges, students not only learn coding languages but also gain an understanding of the importance of computational thinking in today’s technology-driven world.

Engineering and Design Thinking Projects

Engineering and design thinking projects involve hands-on activities that allow high school students to apply their knowledge of engineering principles and design concepts. These projects can range from building simple structures using everyday materials to constructing complex machines and systems.

Websites like TeachEngineering provide a plethora of project ideas and resources for educators and students. By engaging in these projects, students learn to think critically, analyze problems, and develop innovative solutions.

They also develop essential skills such as teamwork, communication, and time management.

Science Investigation and Experiments

Science investigation and experiments are fundamental to STEM education as they enable high school students to explore scientific concepts through hands-on experiences. These activities involve formulating hypotheses, conducting experiments, collecting data, and analyzing results.

Websites like Science Buddies offer a vast collection of science project ideas and resources for students of all ages. By engaging in scientific investigations and experiments, students not only deepen their understanding of scientific concepts but also develop skills such as observation, data analysis, and critical thinking .

Socratic Seminars

Socratic Seminars are a valuable tool for engaging high school students in problem-solving activities. Originating from the Socratic method of teaching, these seminars encourage students to think critically and engage in thoughtful discussions.

The goal of a Socratic Seminar is to delve deeper into a particular topic or text by asking open-ended questions and encouraging students to analyze and evaluate different perspectives. This method promotes active listening, respectful dialogue, and the development of critical thinking skills.

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One of the key aspects of a successful Socratic Seminar is the preparation of thought-provoking discussion questions. These questions should be open-ended and encourage students to think deeply about the topic being discussed.

A well-prepared question can spark lively and insightful conversations, allowing students to explore different viewpoints and develop their own ideas. It is important for the facilitator or teacher to carefully select questions that will challenge the students and promote critical thinking.

When preparing discussion questions for a Socratic Seminar, it can be helpful to consider the following:

What are the main themes or concepts that you want students to explore?
How can you frame questions that will encourage students to analyze and evaluate different perspectives?
Are there any current events or real-life examples that can be incorporated into the discussion?

During a Socratic Seminar, the facilitator plays a crucial role in guiding the conversation and ensuring that all students have the opportunity to participate. The facilitator should create a safe and inclusive environment where students feel comfortable sharing their thoughts and opinions.

It is important to establish ground rules for respectful dialogue, such as using evidence to support arguments and actively listening to others.

The facilitator can also help steer the conversation by asking follow-up questions, summarizing key points, and encouraging students to elaborate on their ideas. By actively listening and responding to student contributions, the facilitator can foster a dynamic and engaging discussion that encourages problem-solving and critical thinking.

Socratic Seminars are a powerful tool for engaging high school students in problem-solving activities. By promoting critical thinking, active listening, and respectful dialogue, these seminars provide an opportunity for students to develop their analytical skills and engage in meaningful conversations.

Whether discussing a literary text or a current event, Socratic Seminars offer a platform for students to explore complex issues and find innovative solutions.

Problem solving abilities will serve students well both in academics and in life after school. The activities discussed give teens a chance to flex their critical thinking muscles in a hands-on, engaging way.

Group challenges teach teamwork and collaboration skills, while individual puzzles help sharpen logic and reasoning. Real-world projects allow students to creatively apply STEM concepts, and seminars provide conversational problem solving practice.

The next time your high schooler seems bored or disengaged, try one of these stimulating problem solving activities! With consistent practice, teens will develop stronger skills to overcome obstacles and achieve success.

Maria Sanchez is the founder of the Save Our Schools March blog. As a former teacher and parent, she is passionate about equitable access to quality public education. Maria created the blog to build awareness around education issues and solutions after organizing a local march for public schools.

With a Master's in Education, Maria taught high school English before leaving her career to raise a family. As a parent, she became concerned about underfunded schools and over-testing. These experiences drove Maria to become an education advocate.

On the blog, Maria provides resources and policy insights from the dual perspective of an informed parent and former teacher. She aims to inspire others to join the movement for quality, equitable public education. Maria lives with her family in [city, state].

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17 Non-Corny Team Building Activities for High Schoolers

by Chad Davis | Team Building Tips

17 Non-Corny Team Building Activities for High Schoolers

Team-building activities for high school students can often feel corny or forced, especially when they don’t consider the dynamics of young people. But finding the right balance between fun and meaningful interaction can transform an awkward situation into a great opportunity for students to bond and build essential communication skills.

Whether it’s for sports teams, small groups, or large groups, the best way to engage students is through activities that focus on creativity, teamwork, and problem-solving skills. These activities encourage high schoolers to step out of their comfort zone while working toward a common goal. Plus, they’re a great way to build leadership skills, strengthen team spirit, and enhance critical thinking without feeling like forced participation.

In this list, you’ll discover a breath of fresh air in the world of team-building exercises—fun team-building activities that don’t just get the entire group moving but also offer a creative, engaging, and non-corny approach for all. From physical activities like obstacle courses to creative group activities such as escape rooms, this collection of team-building games is designed for high school students of all ages. Let’s dive in!

Section 1: Creative Collaboration Activities

Sometimes, the best way to get high school students working together is by offering a team-building activity that encourages creative thinking. These activities allow small teams to collaborate in a fun way while enhancing communication skills and problem-solving abilities.

1. Escape Room Challenge

Escape rooms have become one of the favorite team-building activities for young people because they require critical thinking, quick decision-making, and teamwork. In this fun game, small groups are “locked” in a room (or classroom) and must solve a series of puzzles and challenges to “escape” within a set time limit. This activity not only strengthens communication between group members but also encourages them to step outside their comfort zone.

Great opportunity to enhance problem-solving skills
Fun way to foster collaboration and creativity
Can be done virtually for remote teams

2. Team Art Project

Another great activity for building collaboration is a team art project. Divide students into smaller groups and give each group a large piece of paper or canvas to work on. Whether they’re creating a mural or a collage, each group member brings their unique ideas to the table. This activity is perfect for developing teamwork and encouraging students to express themselves while working toward a common goal.

Promotes creative thinking and teamwork
Works well for both small teams and larger groups
A great thing for students who enjoy artistic expression

3. Improv Acting Games

Improv acting games are a fun activity for high school students that allow them to think on their feet while working with others. Games like “Yes, And…” or “Scenes from a Hat” encourage students to listen closely, respond quickly, and trust their team members. These activities are a great way to boost confidence, improve verbal communication, and bring students out of their shells.

Ideal for small groups looking to improve social and communication skills
Encourages quick thinking and creativity
Helps build trust among group members

Section 2: Physical and Active Team Games

Physical activity is an excellent way to bring energy into any team-building event. High school students, especially, benefit from activities that get them moving while promoting teamwork and communication. These games help develop problem-solving skills and leadership abilities in a fun and engaging way.

4. Capture the Flag with a Twist

Capture the Flag is a classic game that’s been enjoyed for years, but adding a unique twist can make it even more engaging for today’s students. Divide students into two equal teams and give each team additional challenges—such as completing a puzzle or a quick-thinking obstacle course—before capturing the flag. This team-building exercise encourages both physical activity and strategic thinking while keeping students engaged.

Encourages group dynamics and teamwork
Great for both large groups and small teams
Helps develop leadership and problem-solving skills

5. Ultimate Relay Race

In this team-building activity, students compete in small groups to complete a series of relay-style challenges. Each section of the race requires different skills, from physical challenges like a sack race to brainy challenges like solving a puzzle or building a tower. The first team to cross the finish line wins, making it a fun way to incorporate both mental and physical tasks.

Perfect for enhancing teamwork and quick thinking
Encourages collaboration across the entire team
Can be tailored to fit different group sizes

6. Human Knot

The Human Knot is a classic team-building game that’s perfect for improving communication skills and group problem solving. In this game, group members stand in a circle, grab the hands of two other students (who aren’t next to them), and must work together to untangle themselves without letting go of anyone’s hand. It’s a fun way to develop trust, teamwork, and creative thinking.

A great team-building activity for small groups or larger teams
Helps develop verbal communication and trust
Encourages patience and collaboration

Section 3: Problem-Solving and Strategy-Based Activities

For high school students who enjoy a mental challenge, problem-solving and strategy-based games are a great way to engage their critical thinking and teamwork skills. These activities encourage students to work together toward a common goal, requiring creative thinking and planning.

7. The Amazing Race

Inspired by the popular TV show, this team-building activity combines elements of a scavenger hunt and an obstacle course. Divide students into small teams and set up various stations around the school or another location. At each station, teams must complete a challenge or solve a puzzle before moving on to the next. The first team to finish the course wins. This fun team-building activity helps students practice quick thinking and decision-making.

Encourages teamwork and critical thinking
A great way to improve problem-solving under a time limit
Works well with any group size

8. Build a Boat

In this activity, students are divided into teams and given limited building materials to construct a small boat that can hold weight without sinking. The challenge lies in designing a boat that’s both functional and efficient using items like cardboard, tape, and plastic. It’s a great opportunity to enhance teamwork and problem-solving skills while encouraging creativity.

Promotes collaboration and creative thinking
Ideal for small groups working toward a common goal
Can be a great mix of mental and physical activity

9. Egg Drop Challenge

The Egg Drop Challenge is a classic game that never gets old. Teams are tasked with building a structure using basic supplies (like straws, tape, and newspaper) to protect a raw egg from cracking when dropped from a height. This team-building exercise enhances problem-solving and innovation as students try to find the best solution within a set time limit.

Focuses on teamwork, problem-solving , and creativity
Encourages group members to share ideas and strategies
Fun for both large groups and small teams

Section 4: Icebreaker Games that Don’t Feel Awkward

Icebreaker games are often dreaded by high school students, but with the right approach, they can be a fun way to help students feel more comfortable while building connections within the group. These games focus on getting students to know each other without feeling forced or uncomfortable.

10. Two Truths and a Lie with a Twist

This classic game involves each student sharing three statements about themselves: two true and one false. The twist? You can introduce specific themes like “favorite movie” or “craziest thing you’ve done.” Group members take turns guessing which statement is the lie. It’s a fun team-building game that helps students practice verbal communication and get to know their peers in a low-pressure environment.

Great for small groups and larger teams
Encourages verbal communication and creative storytelling
A fun activity to break the ice and bond over shared experiences

11. Speed Puzzling

Divide students into smaller groups and give each group a simple puzzle or a brain teaser to solve within a time limit. This game challenges students to think quickly while working together as a team. The first team to complete the puzzle wins. It’s a great way to combine competition and teamwork in a non-intimidating way.

Encourages quick thinking and problem-solving skills
A fun way to build team spirit and camaraderie

12. Charades with Categories

Instead of generic charades, introduce categories that high school students can relate to, such as popular trends, favorite movies, or sports teams. Teams take turns acting out clues while their group members try to guess the correct answer. This is a perfect icebreaker for getting students out of their comfort zone and working together without feeling awkward.

A great activity for small teams or large groups
Fosters teamwork, communication, and quick thinking
Helps create a relaxed and fun atmosphere for the entire group

Section 5: Virtual or Hybrid Activities for Remote Teams

With the rise of online learning and remote setups, it’s essential to have team-building activities that work for students who aren’t physically in the same location. These virtual or hybrid activities help foster teamwork and communication, whether students are in the classroom or working remotely.

13. Online Escape Room

Just like in-person escape rooms, the virtual version requires students to work together in small groups to solve puzzles and unlock challenges. Using platforms designed for online games, students can collaborate in real time to solve clues and “escape” within a set time limit. This is a great way to engage students who are part of remote teams while improving their problem-solving skills.

Perfect for remote teams or hybrid environments
Encourages communication skills and teamwork across distances
A fun game that challenges students to think critically

14. Virtual Trivia Competition

Host a trivia competition where students are divided into teams and answer questions on various topics. This team-building activity can be tailored to match students’ interests, such as sports teams, favorite movies, or pop culture. It’s a great way to promote teamwork and friendly competition while staying connected in a virtual space.

Works well for small groups and larger teams
Encourages quick thinking and verbal communication
A fun activity for building team spirit in a virtual setting

15. Kahoot or Quizizz Challenge

These popular online quiz platforms are an engaging way to bring a whole group of students together, whether they’re in the classroom or working remotely. Divide students into teams and have them compete in a series of quizzes. This activity promotes collaboration and friendly competition in a digital space, making it ideal for hybrid learning.

Great for promoting teamwork and healthy competition
Works for students of all ages and diverse group sizes
Encourages creative thinking and problem-solving skills

Section 6: Service-Based Team Building

Service-based activities allow students to work together while giving back to the community. These types of team-building exercises are a great way to foster teamwork, leadership, and a sense of responsibility, while also helping students connect with a common goal. It’s a fun way to build team spirit while making a positive impact.

16. Community Clean-Up Challenge

In this team-building activity, students are divided into small teams and tasked with cleaning up a specific area, such as a park, school grounds, or local neighborhood. The team that collects the most trash or finishes cleaning up their designated space first wins bonus points or a prize. This activity encourages collaboration and problem-solving while doing something meaningful for the community.

Perfect for small groups or large groups
Encourages teamwork, leadership skills , and responsibility
A great way to foster team spirit while serving the community

17. Charity Build Projects

Incorporating charitable activities into team-building events is an excellent way to combine fun, teamwork, and a sense of responsibility. A popular option is the Build-A-Bike® team-building event , where students work together to assemble bicycles for children in need. This activity is a great way for high schoolers to learn the value of teamwork, problem-solving, and giving back to their community. Build-A-Bike® is a well-known charity event that’s perfect for high school students looking to make a positive impact.

Inspired by corporate social responsibility (CSR) programs, these types of projects allow students to focus on a shared goal while developing essential communication and leadership skills. Whether in a virtual or in-person setting, charity build projects offer a unique blend of fun and service that leaves everyone feeling like a winner.

Encourages teamwork, creativity, and problem-solving skills
Great for both small teams and larger groups
Helps students work toward a common goal while giving back to the community

The Perfect Team Building Activities for High School Students are the Ones that Get Everyone Working Together

Team-building activities for high school students don’t have to be corny or forced. Whether you’re working with small groups or larger teams, the key is to create activities that engage students in a fun way while promoting important skills like communication, problem-solving, and creative thinking. From physical activities like obstacle courses and human knot to mental challenges like escape rooms and scavenger hunts, there are endless ways to get the entire group working toward a common goal.

Throughout the school year, incorporating team-building exercises can help students develop leadership skills, build stronger relationships, and step outside their comfort zone. These activities are perfect for fostering a positive group dynamic, whether it’s in-person or virtual, and can make a huge difference in how students collaborate and interact.

With the right activities, your high school students will gain valuable experiences and memories, all while growing as a team. So, whether you’re looking for icebreakers, outdoor team-building activities, or something to bring your remote teams together, there are various ways to make it happen. Remember, the goal is to make team-building fun, engaging, and, most importantly, non-corny!

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