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Here is a method for quickly sketching a sphere:
Invite students to share their sketches. Ask students to share what the diameter would look like if they did not already draw one in. Remind students that sketches can be used to help visualize a problem where an image might not be provided. In today’s lesson, they will be working with activities that may or may not have images provided, and they should sketch images or label any images provided to use as a tool to help understand the problem thoroughly.
The purpose of this activity is for students to reason about the volume of a sphere with a specific radius using a cone and cylinder with matching dimensions.
In the Launch, students begin with an image of a sphere in a cylinder. The sphere and cylinder have the same radius, and the height of the cylinder is equal to the diameter of the sphere. Students reason about how the volumes of the two figures compare in order to get a closer estimate of the volume of the sphere.
Then students watch a video that shows a sphere inside a cylinder set up like the image. A cone with the same base and height as the cylinder is introduced, and its contents are poured into the cylinder, completely filling the empty space inside the cylinder not taken up by the sphere. Students are asked to record anything they notice and wonder as they watch the video, and a list is created as a class. They then consider what must be true about the relationship between the volumes of a cone, cylinder, and sphere without doing any calculations (MP1).
In the Task Statement, students consider a cone, sphere, and cylinder with matching dimensions. With a partner, they reason about the volume of the sphere using the volumes they calculate for the cone and cylinder along with what they learned from the video.
Monitor for students who discuss either method for calculating the volume of the sphere:
Arrange students in groups of 2. Display for all to see:
A sphere fits snugly into a cylinder so that its circumference touches the curved surface of the cylinder and the top and bottom touch the bases of the cylinder.
Ask, “In the previous lesson we thought about hemispheres in cylinders. Here is a sphere in a cylinder. Which is bigger, the volume of the cylinder or the volume of the sphere? Do you think the bigger one is twice as big, more than twice as big, or less than twice as big?” Then give students 1 minute of quiet think time. Invite students to share their responses, and keep their answers displayed for all to see throughout the lesson so that they can be referred to during the Lesson Synthesis.
Show the video (found at the end of this Launch), and tell students to write down anything they notice or wonder while watching. Ask students to share the things they noticed and wondered. Record and display their responses for all to see. If not mentioned by students, bring up the following points:
Tell students that the sphere inside the cylinder seen in the video is the same as the one in the picture shown previously. Ask students: “Does this give us any answers to the list of wonders?” (Yes, this tells us that the sphere and cylinder have the same radius.)
Tell students that the cone and cylinder have the same height and base area. Ask students:
Show the video one more time, and ask students to think about how we might calculate the volume of the sphere if we know the radius of the cone or cylinder. Give students 30 seconds of quiet think time followed by time for a partner discussion to share their ideas before beginning work on the questions.
Select work from students with different strategies, such as those described in the Activity Narrative, to share later.
A demonstration of how a volume of a sphere and cone equal the volume of a cylinder.
The goal of this discussion is to compare and contrast the different ways students calculated the volume of the sphere.
Display 2–3 approaches or representations from previously selected students for all to see. If time allows, invite students to briefly describe their approach, then use Compare and Connect to help students compare, contrast, and connect the different approaches. Here are some questions for discussion:
Display this expression for all to see:
Ask students: “What does this expression represent?” (the volume of the cylinder minus the volume of the cone)
Draw students’ attention back to the guesses they made at the start of the activity about how much bigger the cylinder’s volume is than the sphere. Ask students if we can answer that question now. (Note: If students do not explicitly make the connection that the sphere’s volume is the volume of the cylinder, they will have another chance to look at the relationship in the next activity.)
The purpose of this activity is to build from the concrete version in the previous activity to a generalized formula of a sphere with an unknown radius. The previous activity prepared students with strategies to work through this task in which they must manipulate the variables in the volume equations. Students first calculate the volumes of the cylinder and cone in the activity and use what they learned in the previous activity to calculate the volume of the sphere. Finally, they are asked about the relationship between the volumes of the cylinder and sphere, which connects back to the discussion of the previous activity.
As students rearrange the volume equations, they are making use of algebraic structure to reason about the formula for the volume of a sphere (MP7).
Select students who recognize that the volume of the sphere is the volume of the cylinder and use that to come up with the general formula for volume of a sphere, , or who use the subtraction method discussed in the previous activity to share later.
A cone, a sphere, and a cylinder that all have the same radius and height are shown here.
Let the radius of the cylinder be units. When necessary, express answers in terms of .
Use this discussion to help students see the different ways to reason about calculating the volume of a sphere.
Here is a summary of the two approaches.
The method:
Subtraction method:
Although either method works, there are reasons students may choose one over the other. The subtraction method is a bit more involved, as it requires the distributive property to combine like terms and the subtraction of from 2. It may make more sense to students, however, since it describes the video demonstrating that the volume of the sphere is the difference between the volumes of the cylinder and cone. The method is a bit simpler in terms of manipulating expressions, but students might not fully understand why the volume of the sphere is the volume of the cylinder.
Invite previously selected students to share their methods. Display for all to see the two different strategies side by side, and ask students:
If time allows, conclude the discussion by inviting students to explain to their partner why the method they didn't use worked.
Add the formula and a diagram of a sphere to your classroom display of the formulas being developed in this unit.
Think about a sphere with radius units that fits snugly inside a cylinder. The cylinder must then also have a radius of units and a height of units. Using what we have learned about volume, the cylinder has a volume of , which is equal to cubic units.
We know from an earlier lesson that the volume of a cone with the same base and height as a cylinder has of the volume. In this example, such a cone has a volume of , or cubic units.
If we filled the cone and sphere with water and then poured that water into the cylinder, the cylinder would be completely filled. That means the volume of the sphere and the volume of the cone add up to the volume of the cylinder. In other words, if is the volume of the sphere, then
This leads to the formula for the volume of the sphere,
Here are a cone, a sphere, and a cylinder that all have the same radii and heights.
The radius of the cylinder is 5 units. When necessary, express all answers in terms of .
If students struggle to keep track of all the dimensions of the different figures, consider asking: