Balloon Vibrations

 

Focus/Wonder Question for the lesson: How could you find out if there are vibrations in the air when we talk to each other?

Students exploring vibrations using balloons

   

Students wore labels to act as the speaker, air blobs, and a windshield, gently bumping each other in a chain reaction to model how sound vibrations travel through ai.

Exit Ticket

Engage

As I observed this Grade 4 science lesson, I could tell right away that students were drawn in by the opening question, “What would happen if you screamed in outer space?” Before any materials were introduced, students were already talking, guessing, and reacting to one another’s ideas. From where I was sitting, it felt like a low-pressure entry point where everyone could participate, even if they weren’t completely sure of their thinking. This opening set the tone for students to use language to make predictions and share ideas right away.

Explore
During the Explore phase, students worked in partner pairs using balloons to investigate how sound moves through the air. As I moved around the room, I heard students saying things like “Did you feel that?” and “It moved when I talked.” A lot of the sense-making happened through conversation. Students pointed, gestured, and tested ideas together before being asked to write anything down. This opportunity to talk and explore first seemed especially supportive for students who benefit from processing ideas out loud.

Explain
The Explain portion included the big activity of the lesson. A few students were chosen to participate in a whole-class model where they physically became the speaker, the air blobs, and the windshield. Each student held a printed label and sat in a line across the front of the room. When the “speaker” wobbled back and forth, that movement was passed from one “air blob” to the next until it reached the “windshield.”

Watching this model made the concept click, not only for the students, but for me as an observer as well. You could hear students saying things like “It’s bumping into each other” and see them connecting the movement to the idea of sound vibrations. The model helped explain something students couldn’t actually see by using people and motion to show how sound travels through the air. Sentence stems such as “Sound travels by…” and “Sound can make things move because…” supported students in explaining what the model was showing using both words and movement.

Elaborate
Students then applied this same model to a new context, outer space. I noticed students referring back to the human model and explaining that if there were no air blobs, the vibration would not be able to travel. Several students used hand motions to show where the sound would stop without air. This part of the lesson felt like real sense-making, as students were using the model to reason through a new situation rather than just repeating information.

Evaluate
To wrap up the lesson, students completed an exit ticket where they were asked to draw a model showing how sound traveled from a speaker to a windshield and explain their thinking using words. As I observed students working, many relied heavily on their drawings first, adding arrows, labels, and air blobs, and then used short written explanations to clarify their ideas. It was clear that modeling was not just a one-time activity, but something students carried into their independent work.

Reflection
Observing this lesson helped me better understand what disciplinary literacy looks like in a science classroom. Students used talk, movement, drawing, writing, and models to make sense of a complex idea. The human modeling activity, in particular, made learning visible and accessible. From what I observed, these strategies supported student understanding and gave all learners, especially multilingual students, multiple ways to engage with the content and explain their thinking.