Deck 19: Flux Integrals and Divergence

What is the flux of the vector field through a circle in the xy-plane of radius 2 oriented upward with center at the origin?

$\int_{S} \vec{F} \cdot d \bar{A}$ is a vector.

A circular disk, S, of radius 2 and centered on an axis, is perpendicular to the y-axis at y = -6 with normal in the direction of decreasing y. Consider the vector field $\vec { F } = x \vec { i } + y \vec { j } + ( z + x ) \vec { k }$ .Is the flux integral $\int_{S} \vec{F} \cdot \overrightarrow{d A}$ positive, negative or zero?

Suppose S is a disk of radius 2 in the plane x + z = 0 centered at (0, 0, 0)oriented "upward".
Calculate the flux of through S.

Let be the constant vector field .
Find a condition on a, b and c such that for any surface S lying on the plane -5x + 3y - 2z = 1.

Compute the flux integral of the vector field through the square in the yz-plane, oriented so that the normal vector points in the direction of the x-axis.

Calculate the flux of through a surface of area 3 lying in the plane 2x + 5y + 5z = 10, oriented away from the origin.

Let S be the sphere of radius 3 centered at the origin, oriented outward.
Suppose is normal to at every point of S.Find the flux of out of S.

Explain why it is impossible to give the Möbius strip a continuous orientation.

Compute the flux of the vector field through the surface S, where S is the part of the plane z = x + 2y above the rectangle oriented upward.

Let S be the sphere of radius 6 centered at the origin, oriented outward.
Let be a vector field such that at every point of S.Find the flux of out of S.

Suppose S is a disk of radius 2 in the plane x + z = 0 centered at (0, 0, 0)oriented "upward".Write down an area vector for the surface S.

If the surface area of surface S₁ is larger than the surface area of surface S₂, then $\int _ { S _ { 1 } } \vec { F } \cdot d \vec { A } \geq \int _ { S _ { 2 } } \vec { F } \cdot d \vec { A }$ .

Suppose S is a disk of radius 4 in the plane x + z = 0 centered at (0, 0, 0)oriented "upward".Calculate the flux of through S.

Let S be an oriented surface with surface area 6.Suppose $\vec{F}=a \vec{i}+b \vec{j}+c \vec{k}$ is a constant vector field with magnitude 3.If the angle between $\vec{F}$ and $\vec { n }$ is $\pi$ /6 at each point of the surface S, determine the value of the flux integral $\int_{S} \vec{F} \cdot \overrightarrow{d A}$ .

Let S be the sphere of radius 4 centered at the origin, oriented outward. Find $\vec { n }$ , the unit normal vector to S in the direction of orientation.

Let , and let S₁ be a horizontal rectangle with corners at (0,0,1), (0,2,1), (3,0,1)and (3,2,1), oriented upward; S₂ a rectangle parallel to the xz-plane, with corners at (1,3,1), (2,3,1), (1,3,5)and (2,3,5), oriented in the positive y-direction, and S₃ a rectangle parallel to the yz-plane, with corners at (1,2,1), (1,4,1), (1,2,5)and (1,4,5), oriented in the negative x-direction.
Arrange , and in ascending order.

Let $\vec { n }$ be the unit normal vector of S.If the angle between $\vec{F}$ and $\vec { n }$ is less than $\pi$ /2 at each point of the surface, then $\int _ { S } \vec { F } \cdot \overrightarrow { d A } \geq 0$

If $\int_{S} \vec{F} \cdot \overrightarrow{d A}=0$ , then $\vec{F}$ is perpendicular to the surface S at every point.

(a)Compute the flux of the vector field through S_a, the sphere of radius a, , oriented outward.
(b)Find .

Suppose the surface S is the part of the surface x = g(y, z), for points (y, z)belonging to a region R in the yz-plane.If S is oriented in the positive x-direction, what will be the formula for computing the flux of through S?

Let ${ \vec { F } } = x \vec { i } + y \vec { j }$ .Write down an iterated integral that computes the flux of $\vec { F }$ through S, where S is the part of the surface $z = x ^ { 2 } + y ^ { 2 }$ below the plane z = 16, oriented downward.

Compute the flux of through the cylindrical surface oriented away from the z-axis.

Evaluate $\int _ { S } \vec { F } \cdot \vec { d A }$ , where ${ \vec { F } } = x \vec { i } + 6 y \vec { j }$ and S is the part of the cylinder $x ^ { 2 } + y ^ { 2 } = 4$ with x $\ge$ 0, y $\le$ 0, 0 $\ge$ z $\le$ 2, oriented toward the z-axis.

Compute the flux of the vector field through the surface S that is the part of the surface above the disk , oriented in the positive z-direction.

Find the flux of through the disk of radius 5 in the xz-plane, centered at the origin, and oriented upward.Give an exact answer.

Let S be the spherical region of radius R with $\pi$ /3 $\le$ $\varphi$ $\le$ 2 $\pi$ /3 and $\pi$ /3 $\le$$\theta$ $\le$ 2 $\pi$ /3.Find the value of R so that $\int _ { S } \vec { r } \cdot \vec { d A } = 40 \pi$ Give your answer to two decimal places.

Let ${ \vec { F } } = y \vec { i } + x \vec { j }$ .Write down an iterated integral that computes the flux of $\vec { F }$ through S, where S is the part of the cylinder $x ^ { 2 } + y ^ { 2 } = 9$ with x $\ge$ 0, y $\ge$ 0, 0 $\le$ z $\le$ 4, bounded between the planes y = 0 and y = x, oriented outward.

A greenhouse is in the shape of the graph with the floor at z = 0.Suppose the temperature around the greenhouse is given by .Let be the heat flux density field.
Calculate the total heat flux outward across the boundary wall of the greenhouse.

If $\vec { F }$ is a constant vector field and S₁ and S₂ are oriented rectangles with areas 1 and 2 respectively, then $\int _ { S _ { 2 } } \vec { F } \cdot \vec { d A } = 2 \int _ { S _ { 1 } } \vec { F } \cdot \vec { d A }$ .

Let S be the part of the sphere $x ^ { 2 } + y ^ { 2 } + z ^ { 2 } = 25$ with x $\ge$ 0, y $\ge$ 0, z $\ge$ 0, oriented outward.Evaluate $\int _ { S } ( x z \vec { i } + 4 y z \vec { j } ) \cdot \vec { d A }$ .

Let .Calculate the flux of through the surface oriented upward and given by z = f(x, y)= xy, over the region in the xy-plane bounded by the curves and between the origin and the point (1, 1).

Compute the flux of the vector field through the surface S, where S is the part of the plane z = x + 2y above the rectangle oriented upward.
What is the answer if the plane is oriented downward?

Let C be the portion of the cylinder $x ^ { 2 } + y ^ { 2 } = R ^ { 2 }$ of fixed radius R with $\pi$ /3 $\le$ $\theta$ $\le$ 2 $\pi$ /3 and -a $\le$ z $\le$ a oriented outward for some positive number a.Let S be the portion of the sphere $x ^ { 2 } + y ^ { 2 } + z ^ { 2 } = R ^ { 2 }$ with $\pi$ /3 $\le$$\theta$$\le$ 2 $\pi$ /3 and $\pi$ /3 $\le$ $\varphi$ $\le$ 2 $\pi$ /3 oriented outward.Determine the value of a for which the flux of $\vec { r }$ through each of these surfaces is equal in magnitude but opposite in sign for any choice of R.

If $\vec{F}=-4 \vec{G}$ and S is an oriented surface, then $\int _ { S } \vec { F } \cdot \vec { d A } = - 4 \int _ { S } \vec { G } \cdot \vec { d A }$ .

Compute the flux of the vector field through the surface S, where S is the part of the plane z = x + 2y above the rectangle oriented downward.

Let be a constant vector field and S be an oriented surface.
Show that

Calculate $\int _ { C } ( 5 x \vec { i } + 3 y \vec { j } ) \cdot \vec { d A }$ where C is a cylinder of radius R with 0 $\le$ z $\le$ 1.

If $\vec { F}$ is a constant vector field and S₁ and S₂ are oriented rectangles with areas 3 and 15 respectively, both orientated with the vector $\overrightarrow { { i } } ,$ is it true that $\int _ { S _ { 2 } } \vec { F } \cdot \vec { d A } = 5 \oint _ { S _ { 1 } } \vec { F } \cdot \vec { d A }$ ?

Calculate the flux of through the disk on the plane , oriented in the positive y-direction.

Calculate the flux of $\vec { F} = \left( x ^ { 2 } + z ^ { 2 } \right) y \vec { i }$ , through the plane rectangle z = 3, 0 $\le$ x $\le$ 2, 0 $\le$ y $\le$ 5, oriented in the positive z-direction.

Let S be the cylinder .Find Q if .

Calculate the flux of ${ \vec { F } } = 5 \vec { i } + 2 \vec { j } - 2 x \vec { k }$ through the plane rectangle z= 1, 0 $\le$ x $\le$ 5, 0 $\le$ y $\le$ 2, oriented downward.

Calculate the flux of through a disk of radius 5 in the plane x = 3, oriented away from the origin.

Let be a constant vector field with , where a, b, c are constants satisfying the condition .Let S be a surface lying on the plane x + 4y - 5z = 10 oriented upward.
If the surface area of S is 10, what is the smallest possible value of , and what are the corresponding values of a, b, c?

Suppose that S is the surface which is a portion of the graph of a smooth function over a region R in the xy-plane, oriented upward.Consider the vector field .
Find so that .

Suppose T is the triangle with vertices and oriented upward.Calculate the flux of through T exactly, and then give an answer rounded to 3 decimal places.

Find the flux of ${ \vec { F } } = x \vec { i } + y \vec { j } + 8 z \vec { k }$ over the sphere S_a, $x ^ { 2 } + y ^ { 2 } + z ^ { 2 } = a ^ { 2 }$ , oriented outward, with a > 0.

Let $\vec { F } = \frac { x \vec { i } + y \vec { j } } { \left( x ^ { 2 } + y ^ { 2 } \right) ^ { 3 / 2 } }$ .
True or False: The flux of $\vec { F }$ through any cylinder C (with $x ^ { 2 } + y ^ { 2 } = R ^ { 2 } , 0 \leq z \leq 1$ )does not depend on the radius R.

Calculate the flux of ${ \vec { F } } = \left( x ^ { 2 } + z ^ { 2 } \right) y \vec { j }$ , through the plane rectangle y = 4, 0 $\le$ x $\le$ 4, 0 $\le$ z $\le$ 5, oriented in the positive y-direction.

Calculate the flux of $\vec { F } = 5 \vec { i } + 5 \vec { j } - 2 x \vec { k }$ through the plane rectangle y = 1, 0 $\le$ x $\le$ 1, 0 $\le$ z $\le$ 3, oriented in the negative y-direction.