Delta Math has incredible sets for seeing volume of cross-sections and solids of revolutions. If you instruct your students to click on “show solution“, they can pull a slider to see the region become a solid! For the cross-section set, it shows the shape (square, rectangle, or triangle) growing along the base. For the disks, it includes the radius with the 3D shape. The washer set shows the washer inside the 3D shape. There is also a matching set, where students can practice matching up the 2D region with a resulting 3D shape, and vice versa.

The five sets I use are in the image below. I have also included videos of the volumes being created when you drag the slider so you can see how cool it is! Delta Math is free for teachers!

My AP Calculus students had a tough time with volume last year. So this year I wanted an activity where they could actually see the cross sections. I have seen many awesome activities where students actually measure the base between curves, and then create cross sections using paper, like the ones from Bowman and Rebacka. Iwould love to do these with my students, but unfortunately we are very short on time this year because of our school schedule.

So, I decided to try it out using Play-Doh. I had students mold each type of cross section, and then let them slice it with either dental floss or a plastic knife. Once they cut their solid, I had them pull out cross sections so that we could develop the area and then volume formulas together.

First of all, kids loved playing with Play-Doh! It worked beautifully, and only took about 40 minutes to do the entire activity. Most of my students didn’t need to do all of the cross sections after the doing the first one. Doing the first one really helped them see and understand what was going on. So, if you are short on time, you could just do one cross section. However, my students really enjoyed trying to make the shapes for all four cross sections, and cutting them into the sections. And, again, they really enjoyed playing with the Play-Doh! They were so sad when I asked them to put away the Play-Doh for the quiz that I let them keep it out and play with it during the quiz. Sometimes I forget that high school students are still kids.

I pulled together a Desmos activity that I planned on using the same day. It is full of amazing graphs created by the amazing Suzanne von Oy. However we did not get to it as we ran out of time, and were just too excited about the Play-Doh! So I will share the Desmos with them when we do examples, and to remind them of what we did in class.

Procedure:

Class time: 45 minutes

Materials

Graph sheet and worksheet – I put the graph sheet into slip in sleeves, so I could reuse them for my classes. You could also use plastic page protectors or laminate the graph sheet.

Play-Doh – I used one 4oz. can per every two students.

Dental Floss (or plastic knives, but dental floss works better as it doesn’t squish the top of the shape).

Rulers (they don’t need them for this activity, but it helps them see why they shouldn’t measure with a ruler).

I let the kids just play with the Play-Doh first. Don’t skip this important first step, or you will never get their attention. lol!

I had two students work together on one mat.

While they are playing we talked about volume formulas. I found asking them how do you get the volume of a cylinder was especially helpful as they all knew it was the area of a circle time the height. I pushed them on this, and then they told me that you have lots of circles to get the volume of a cylinder.

I told them to use all of their Play-Doh to make a solid out of the area between f(x) and g(x). Then, I had them mold their shape into the different cross sections.

After molding, they sliced their solid, and took out two different sized cross sections, one from the middle and one towards the end. This was incredibly helpful as when I said, what is the base of the square? A couple of tables started measuring it with a ruler. (Rulers had been left on the table from the class before). This was accidental, but a great opportunity to talk about why measuring this is not the best method.

This led to a discussion about how to get the base measurement we needed. And moved to the worksheet to write down the area and the volume.

I did not give them the area of an equilateral triangle. We used our 30-60-90 knowledge to develop this.

Once we finished everything we compared the volume formulas on their worksheet. We talked about how they were different and how they were the same.

I planned on using the Desmos activity, but we ran out of time. So, I will use this the next day so they can see and manipulate the cross-sections of the examples we use in class.

When my students are excited about what they are doing in class, they are engaged. They will listen and best of all, learn. The kids were ecstatic when they saw the Play-doh. They couldn’t wait to get their hands on it! The benefits for learning were amazing. All I had to say was “Remember the Play-doh?” and they knew what to do for any volume problem.

Supplies per student:

One fun-sized Play-doh

Ruler

Plastic knife

Ruler

Instructions:
Many of my students had heard somewhere along the way that volume equaled length times width times height. So, I started by having them make a rectangular prism out of their Play-Doh.

Once it was made, I had them draw a picture of it in their Geometry Booklets. Then they measured and recorded the length, width, and height of their prism in centimeters. Next, I had them cut their prism into 1 centimeter lengths. They observed that the cross sections were squares. I had them find the area of this square. We talked about how many slices they had. So if their area was 6 centimeters squared and they had four slices how could they find the volume of the box? They quickly deduced that they needed to multiply the 6 by 4 to arrive at 24 cm cubed.

I repeated this for a cylinder and a triangular prism. We observed what the cross sections were, found the areas of our cross sections, and then found the volume. To sum it all up, we talked about how volume of a prism or cylinder is the area of the base (cross-section) times the height (number of slices).