The formula for the volume of the region revolved around the x-axis on the interval  is given as

where .

As such,

 .

And by the corollary of the First Fundamental Theorem of Calculus

 .

As such, the volume is

 cubic units.

To approach this problem, treat the function  as the radius of a disc, with infintesimal thickness dx (which has the x-axis going through its center).

This infinitesismal volume of this disc is:

Now the volume of the solid rotated around the x-axis is the sum of these discs. In other word, it is the integral:

Note that the derivative of  is , so from this we can infer that the integral of  is :

In stating the bounds, the question is asking that we use those values of x where the function intercepts the x-axis:

Now, treat the function  as the radius of a disc with infinitesimal thickness . The volume of this disc is thus

And the volume can found via integration:

We're given that

Since the indefinite integral is with respect to , we can move the surface area function in front of the integral since we are told that  is not a function of . 

Using the power rule, 

, where  is a constant. 

In our problem 

Therefore, volume can be given as

The formula for volume is given as

where .

As such,

 .

When taking the integral, we will use the inverse power rule which states

 .

Applying this rule term by term we get 

And by the corollary of the first Fundamental Theorem of Calculus,

As such, the volume is

 units cubed.

The formula for volume is given as

where .

As such,

 .

When taking the integral, we will use the inverse power rule which states

 .

Applying this rule term by term we get 

 .

And by the corollary of the first Fundamental Theorem of Calculus,

.

As such, the volume is

 units cubed.

For this problem, we will use the shell method.  Write the formula for the shell method.

The thickness of the shell is .

The radius of the shell is the distance from the y-axis to the vertical rectangles, .

The height of the shell is the top curve subtract the bottom curve.  The top curve is  and the bottom curve is .  The height is:  .

Determine the bounds by setting the top and bottom equations equal to each other.

Solve for  roots.

The roots are  and will be the bounds to the integral.  Write the integral.

To approach this problem, begin by picturing how the sphere might be projected onto the two-dimensional Cartesian plane:

In its two-dimensional projection, we notice the outline of a circle. The formula for a circle of radius  in the Cartesian coordinate system is given as:

Which can be rewritten in terms of  as 

Now note the disk method of volume creation wherein we rotate a function around an axis (for instance, the x-axis):

The new function in the integral is akin to the formula of the volume of a cylinder:

 where  and 

The integral sums up these thin cylinders to give the volume of the shape.

Treating  as our , this integral can be written as:

Consider the points where circle contacts the x-axis, the greatest and smallest possible values of  on the circle:

This is how the volume of a sphere can be derived, and similary, this is how we can derive the area of our segment:

To approach this problem, begin by picturing how the sphere might be projected onto the two-dimensional Cartesian plane:

In its two-dimensional projection, we notice the outline of a circle. The formula for a circle of radius  in the Cartesian coordinate system is given as:

Which can be rewritten in terms of  as 

Now note the disk method of volume creation wherein we rotate a function around an axis (for instance, the x-axis):

The new function in the integral is akin to the formula of the volume of a cylinder:

 where  and 

The integral sums up these thin cylinders to give the volume of the shape.

Treating  as our , this integral can be written as:

Consider the points where circle contacts the x-axis, the greatest and smallest possible values of  on the circle:

This is how the volume of a sphere can be derived, and similary, this is how we can derive the area of our segment:

To approach this problem, begin by picturing how the sphere might be projected onto the two-dimensional Cartesian plane:

In its two-dimensional projection, we notice the outline of a circle. The formula for a circle of radius  in the Cartesian coordinate system is given as:

Which can be rewritten in terms of  as 

Now note the disk method of volume creation wherein we rotate a function around an axis (for instance, the x-axis):

The new function in the integral is akin to the formula of the volume of a cylinder:

 where  and 

The integral sums up these thin cylinders to give the volume of the shape.

Treating  as our , this integral can be written as:

Consider the points where circle contacts the x-axis, the greatest and smallest possible values of  on the circle:

This is how the volume of a sphere can be derived, and similary, this is how we can derive the area of our segment: