The traditional way science has been taught has not been efficient or effective. By shifting to student centered learning, we can spark students’ curiosity and motivate them to figure out for themselves why things happen and how the world works. This is called student sensemaking. We set up the learning experience so that students engage in sensemaking and teachers are empowered with the tools to shift their instruction to support it.
We want to shift away from the traditional science lecture and examples approach to encouraging students to figure things out for themselves. For example, instead of telling students what Newton’s third law is, I might show the class a cannon being fired and ask if they noticed that as the cannonball goes flying off, the cannon itself shifts. Why is it that the cannon shifts? Why does it recoil? What’s going on here? I would try to get students to notice this, ask questions and wonder why the recoil happened.
As students investigate the cannonball/cannon example, they will eventually figure out that when the cannon pushes on the cannonball, the cannonball also pushes on the cannon, and that is Newton’s third law. So, by stimulating the student’s curiosity about the cannon’s recoil, I now have them interested in learning Newton’s third law. With student sensemaking, the teacher’s job is still to get students to learn things, but the job of the student is to observe and figure out phenomena like the one above.
As students make sense of phenomena—an observable fact or occurrence—they are actively engaged throughout the process. They are asking their own questions, deciding what they need to investigate, collecting and analyzing data. And more importantly, they actually go and think about the situation to develop a formal explanation and a model of what’s going on with the phenomenon or lesson.
If the pivot from learning about science ideas to figuring out phenomena is the first big shift, then engaging in practices is the second big shift, because the way that students figure out phenomena is by engaging in the following Science and Engineering Practices.
Scientists ask questions, develop models, carry out investigations, analyze data, and construct explanations, which is why the eight Science and Engineering Practices represent more accurate descriptions of the process. They provide more of an intellectual toolbox to pick and choose from as different situations present themselves.
For example, if we are presented with a new phenomenon:
In the past, we have rarely asked students to engage in all of these practices, particularly the three that are more foundational to student sensemaking: developing models, engaging in arguments through evidence, and constructing explanations and designing solutions. Those are three practices that are often lost in the mix.
Ted Willard is a nationally recognized science standards expert working with Discovery Education on developing curriculum that supports the NGSS and other standards based on the Framework of K-12 Science Education.