4 creative ways to engage children in STEM over the summer: Tips to foster curiosity and problem-solving at home

As the Trump administration cuts research grants and eliminates learning opportunities for K-12 students, families and caregivers play a crucial role in supporting children’s STEM education over the summer.
Four creative ways to engage children in STEM over the summer include finding problems to solve, sparking curiosity through exploration, facilitating thinking by embracing uncertainties, and bringing STEM to life through everyday conversations.
By encouraging children to find and solve problems, families can foster their interest, confidence, and skills in STEM while applying science and math concepts that are often “hidden” in their actions.
Spontaneous learning moments sparked by curiosity can lead to deep engagement and learning of STEM concepts, making family STEM participation a valuable way for children to explore ideas beyond what they typically experience in school.
By turning ordinary moments into curious conversations, families can help children develop math skills, financial literacy, and a stronger understanding of STEM concepts, ultimately supporting their later success in STEM fields.

Families and caregivers can boost children's confidence and interest in science, technology, engineering and mathematics while school is out for summer. heshphoto/Getty Images

The Trump administration is reshaping the pursuit of science through federal cuts to research grants and the Department of Education. This will have real consequences for students interested in science, technology, engineering and mathematics, or STEM learning.

One of those consequences is the elimination of learning opportunities such as robotics camps and access to advanced math courses for K-12 students.

As a result, families and caregivers are more essential than ever in supporting children’s learning.

Based on my research, I offer four ways to support children’s summer learning in ways that feel playful and engaging but still foster their interest, confidence and skills in STEM.

1. Find a problem

Two children wearing blue shirts lay on the grass with magnifying glasses, exploring the environment. — To support STEM learning outside of school, encourage children to find and solve problems.
kali9/Getty Images

Look for “problems” in or around your home to engineer a solution for. Engineering a solution could include brainstorming ideas, drawing a sketch, creating a prototype or a first draft, testing and improving the prototype and communicating about the invention.

For example, one family in our research created an upside-down soap dispenser for the following problem: “the way it’s designed” − specifically, the straw − “it doesn’t even reach the bottom of the container. So there’s a lot of soap sitting at the bottom.”

To identify a problem and engage in the engineering design process, families are encouraged to use common materials. The materials may include cardboard boxes, cotton balls, construction paper, pine cones and rocks.

Our research found that when children engage in engineering in the home environment with caregivers, parents and siblings, they communicate about and apply science and math concepts that are often “hidden” in their actions.

For instance, when building a paper roller coaster for a marble, children think about how the height will affect the speed of the marble. In math, this relates to the relationship between two variables, or the idea that one thing, such as height, impacts another, the speed. In science, they are applying concepts of kinetic energy and potential energy. The higher the starting point, the more potential energy is converted into kinetic energy, which makes the marble move faster.

In addition, children are learning what it means to be an engineer through their actions and experience. Families and caregivers play a role in supporting their creative thinking and willingness to work through challenging problems.

2. Spark curiosity

Two girls wearing shorts use tweezers and a magnifying class to examine insects and tree bark. — Spontaneous learning moments can lead to deep engagement and learning of STEM concepts.
cglade/Getty Images

Open up a space for exploration around STEM concepts driven by their interests.

Currently, my research with STEM professionals who were homeschooled talk about the power of learning sparked by curiosity.

One participant stated, “At one time, I got really into ladybugs, well Asian Beatles I guess. It was when we had like hundreds in our house. I was like, what is happening? So, I wanted to figure out like why they were there, and then the difference between ladybugs and Asian beetles because people kept saying, these aren’t actually ladybugs.”

Researchers label this serendipitous science engagement, or even spontaneous math moments. The moments lead to deep engagement and learning of STEM concepts. This may also be a chance to learn things with your child.

3. Facilitate thinking

In my research, being uncertain about STEM concepts may lead to children exploring and considering different ideas. One concept in particular − playful uncertainties − is when parents and caregivers know the answer to a child’s uncertainties but act as if they do not know.

For example, suppose your child asks, “How can we measure the distance between St. Louis, Missouri, and Nashville, Tennessee, on this map?” You might respond, “I don’t know. What do you think?” This gives children the chance to share their ideas before a parent or caregiver guides them toward a response.

4. Bring STEM to life

With a piggy bank in the foreground, a man holding money talks to a young girl about finances. — Overhearing or participating in budget talks can help children develop math skills and financial literacy.
SeizaVisuals/Getty Images

Turn ordinary moments into curious conversations.

“This recipe is for four people, but we have 11 people coming to dinner. What should we do?”

In a recent interview, one participant described how much they learned from listening in on financial conversations, seeing how decisions got made about money, and watching how bills were handled. They were developing financial literacy and math skills.

As they noted, “By the time I got to high school, I had a very good basis on what I’m doing and how to do it and function as a person in society.”

Globally, individuals lack financial literacy, which can lead to negative outcomes in the future when it comes to topics such as retirement planning and debt.

Why is this important?

Research shows that talking with friends and family about STEM concepts supports how children see themselves as learners and their later success in STEM fields, even if they do not pursue a career in STEM.

My research also shows how family STEM participation gives children opportunities to explore STEM ideas in ways that go beyond what they typically experience in school.

In my view, these kinds of STEM experiences don’t compete with what children learn in school − they strengthen and support it.

Amber M. Simpson receives funding from the U.S. National Science Foundation.

link

Q. What is the impact of federal cuts to research grants and the Department of Education on students interested in science, technology, engineering, and mathematics (STEM)?

A. The elimination of learning opportunities such as robotics camps and access to advanced math courses for K-12 students will have real consequences for students interested in STEM.

Q. How can families and caregivers support children’s summer learning in ways that feel playful and engaging?

A. Families and caregivers can support children’s summer learning by encouraging them to find and solve problems, spark curiosity around STEM concepts driven by their interests, facilitate thinking, and bring STEM to life through ordinary moments.

Q. What is the engineering design process, and how does it help children learn science and math concepts?

A. The engineering design process involves brainstorming ideas, drawing a sketch, creating a prototype or first draft, testing and improving the prototype, and communicating about the invention. This process helps children apply science and math concepts that are often “hidden” in their actions.

Q. How can families encourage children to think creatively and work through challenging problems?

A. Families can encourage children to think creatively and work through challenging problems by supporting their creative thinking and willingness to explore different ideas, even if they don’t know the answer themselves.

Q. What is serendipitous science engagement, and how does it lead to deep engagement and learning of STEM concepts?

A. Serendipitous science engagement refers to spontaneous learning moments that can lead to deep engagement and learning of STEM concepts when children explore and consider different ideas driven by their interests.

Q. How can families facilitate thinking in children who are uncertain about STEM concepts?

A. Families can facilitate thinking in children who are uncertain about STEM concepts by acting as if they don’t know the answer themselves, giving children the chance to share their ideas before guiding them toward a response.

Q. Why is financial literacy important for individuals, particularly those interested in STEM fields?

A. Financial literacy is important because it can lead to negative outcomes in the future when it comes to topics such as retirement planning and debt. It also supports how children see themselves as learners and their later success in STEM fields.

Q. How does family STEM participation give children opportunities to explore STEM ideas beyond what they typically experience in school?

A. Family STEM participation gives children opportunities to explore STEM ideas in ways that go beyond what they typically experience in school, strengthening and supporting what they learn in school.

Q. What is the role of families and caregivers in supporting children’s STEM learning during the summer months?

A. Families and caregivers play a crucial role in supporting children’s STEM learning during the summer months by providing opportunities for exploration, creativity, and problem-solving that foster their interest, confidence, and skills in STEM.