Editor鈥檚 Note: Kevin Bushweller is the Executive Editor of EdWeek Market Brief. This analysis is part of a special report exploring pressing trends in education. Read the full report: 10 Big Ideas in Education.
The most meaningful learning happens outside school.
Take a moment to think about that statement.
It does not mean that meaningful learning is not happening inside schools. Or that all learning that occurs outside schools is meaningful.
But there is a growing argument that the most powerful, relevant learning for today鈥檚 students is happening when they connect with the rapidly changing world beyond the school walls to solve problems, explore ideas, rally for a cause, or learn a new technical skill.
Is asking better questions the key to nurturing student curiosity? Scroll down for a Q&A with Andrew P. Minigan.
I have been covering K-12 education for more than 30 years. During that time, I have watched my three sons go through the public schools, enter college, and join the workforce; my daughter is now making her way through high school. They had wonderful teachers and attended very good schools, for the most part.
What was largely missing, though, was a feeling that they were being prepared for the technological and economic changes ahead or how to make a difference in the world. They were not solving real problems and exploring new ideas鈥攔ather, they were turning in assignments and getting grades. And for all four of them, the most meaningful learning often happened when they weren鈥檛 in school.
That is also a theme that is emerging in our 澳门跑狗论坛 series, Faces of the Future, which tells stories about ambitious, creative young people who are pushing well beyond the boundaries of school, finding new ways to learn advanced computer science, tackle big challenges, map an uncha]rted future, and sometimes get in trouble.
Consider the case of Emma Yang, a teenager who 澳门跑狗论坛 reporter Benjamin Herold profiled last fall as part of this series. She is the youngest student to ever take part in a mentorship program to build 鈥渃omputational thinking鈥 at Wolfram Research, a private company that creates computational technologies.
Initially, Emma worked on a project for Wolfram analyzing police-department data to identify patterns that might explain where, when, and why cars crash in New York City. Then she used machine-learning techniques to teach computers to recognize road signs, a vital feature for self-driving cars. She followed that up by using those same techniques to detect cancerous tumors in human lungs.
鈥淪ometimes, when I鈥檓 curious to learn more, people will say, 鈥榊ou won鈥檛 understand 鈥榯il later,鈥欌 she told 澳门跑狗论坛. 鈥淏ut at my mentorship program, they give me all the information I want, and I can go as deep into it as I want. I really appreciate that.鈥
Emma鈥檚 curiosity and enthusiasm to dive deeply into a topic reminded me of when I took my then-elementary-school-age daughter to visit my older brother鈥檚 University of Virginia biochemistry lab. My daughter was fascinated by the dry ice bubbling up in water, the multi-colored protein solutions in beakers, and computers seemingly everywhere. She was one of those little kids who liked to take various liquids and solids in the house and mix them up to see what would happen鈥攕o when she got to see the real thing, her eyes were bulging with excitement. And it became even more meaningful when she learned her uncle was doing research to develop new treatments for cancer.
But back at school, inside the classroom, it was a different story. There were few, if any, lab experiments and eventually science became boring and irrelevant to her. It was no longer about exploring ideas and solving problems. It was about memorizing facts and figures and preparing for quizzes and tests.
Few schools have figured out how to connect meaningful learning outside of school to recognition inside it. I saw that firsthand with one of my sons, who was in a video editing and production specialty program in high school.
As a junior, he took the initiative to teach himself the ins and outs of iMovie to produce a highlight video of him playing lacrosse that he could send to college coaches. All the learning took place outside school on his own time.
He had to learn how to take a bunch of DVDs with hours of lacrosse footage and load them into iMovie. Then he had to edit the footage down to the best highlights, organize the clips into a video narrative that flowed naturally, strip the unnecessary audio, and produce a video that was less than five minutes long. Then he had to write emails to coaches promoting the video and often follow up with phone calls.
He was learning writing skills, video editing skills, and how to market himself. To this day, he says it was the most meaningful learning experience he had during high school.
But when he asked the school if he could spend time in class working on the project or get extra credit for it, the answer was no. He was told the school did not have the flexibility to allow that because it was not part of the official curriculum.
A perceived lack of opportunity to pursue what interests them inside school can lead some kids down a mischievous path.
That was the case for Jeremy Currier and Seth Stephens, who hacked into their Rochester Hills, Mich., school district network and got access to logins, passwords, phone numbers, locker combinations, lunch balances, and the grades of all 15,000 students in the school system, according to a story by Herold that triggered a lively debate on edweek.org about student discipline and the future of work.
Now the incident and the district鈥檚 decision to expel the boys, Herold writes, are raising a big question: How can schools develop the potential of kids with advanced computing skills and a tendency for probing boundaries鈥攂efore things go in the wrong direction?
The answer might be by connecting those kids with meaningful learning opportunities outside of school.
PERSPECTIVE
Q&A: How to Champion Student Curiosity
For educators seeking to nurture rather than stifle students鈥 natural curiosity and meaningfully connect classroom learning to the outside world, the process may start with something as simple as encouraging them to ask more questions. Andrew P. Minigan, the director of strategy for the education program at the education nonprofit Right Question Institute, has some ideas on what that looks like.
How can teachers encourage students to ask more and deeper questions in school? And why does it matter?
Educators can teach students how to ask their own questions by deliberately facilitating learning experiences during which students formulate, work with, improve upon, and use their own questions throughout the learning process. Question formulation, much like other skills, is not honed simply through osmosis鈥攕tudents need opportunities to ask their own questions and co-construct inquiry with their fellow learners.
What kinds of questions should students and educators be asking each other?
Educators who provide students the opportunity to ask their own questions report that students ask the same questions that they were planning to pose. By practicing the skill, students can become more sophisticated question-askers and more effectively inquire. That does not always mean asking higher order questions; a question, whether closed-ended or open-ended, is only as good as the information it aims to elicit. Students who develop their question-formulation skills are able to use different types of questions for different purposes and improve their questions when necessary to guide their own learning in new, exciting ways.
And what about the art of the follow-up question? How can schools teach that skill?
Even the youngest learners can be thoughtful follow-up questioners. A study [published decades ago in the Journal of Child Psychology and Psychiatry] on children鈥檚 question-formulation behaviors, 鈥淐hildren鈥檚 Questions and Adults鈥 Answers,鈥 highlights an example of an almost 4-year-old girl who asks, 鈥淢ummy, is our roof a sloping roof?鈥 After the mother affirms that their roof slopes, the child asks 鈥淲hy?鈥 The mother replies that most people have sloping roofs to allow the rain to run off. Otherwise, the rain would start coming through. The child asks one more follow-up question: 鈥淒oes the rain just sit there on my school鈥檚 flat roof?鈥
This conversation shows how logical and calculated learners can be in making observations, posing questions, making connections, and asking follow-up questions to address gaps between their question, the answer, and their knowledge or understanding. When questioning is encouraged in the classroom, students can be extremely artful yet precise in their inquiry.
This interview was edited for length and clarity.