#AP Physics C: E&M - Flux and Gauss's Law Study Guide

Hey there, future physics master! Let's dive into the world of flux and Gauss's Law. This guide is designed to be your go-to resource as you prep for the exam. We'll break down the concepts, highlight key points, and tackle some practice problems together. Let's get started!

#Electric Flux: What's Flowing Through?

#What is Flux?

Flux, in simple terms, describes how much of something (like an electric field) passes through a given area. Think of it like counting how many raindrops hit a window. In the context of electric fields, it's about the number of electric field lines piercing through a surface.

Visualizing Flux: Imagine an area on a charged object. The electric flux is the measure of how many electric field lines pass through this area. If the area is parallel to the electric field, the math is straightforward. If not, we use the dot product.
Calculating Flux:
- When the electric field ( $E$ ) is uniform and perpendicular to the area ( $A$ ), the flux ( $\Phi$ ) is simply: $\Phi = EA$
- When the field is at an angle $\theta$ to the area, we use the dot product: $\Phi = \vec{E} \cdot \vec{A} = EA \cos(\theta)$

#

Key Concept

Flux Through Closed Surfaces

Sign Convention: Field lines entering a closed surface = negative flux. Field lines exiting a closed surface = positive flux. It's all about direction!
Net Flux: If there isn't a source or sink of charge inside the area, the net flux is zero. This means the total number of lines entering equals the total number of lines exiting.
- In the image above, there are 11 lines entering and 11 lines exiting. The net flux is zero.

#Gauss's Law: Connecting Flux and Charge

#The Core Idea

Gauss's Law is a powerful tool that relates the electric flux through a closed surface to the amount of charge enclosed by that surface. It's like saying, "Hey, the total number of field lines coming out of a surface tells you how much charge is inside!"

The Formula:

$\Phi_E = \oint \vec{E} \cdot d\vec{A} = \frac{Q_{enc}}{\epsilon_0}$

Where:
- $\Phi_E$ is the electric flux
- $\oint \vec{E} \cdot d\vec{A}$ is the surface integral of the electric field over a closed surface
- $Q_{enc}$ is the total charge enclosed by the surface
- $\epsilon_0$ is the permittivity of free space (a constant)

#Breaking Down the Formula

Left Side: The integral of the electric field over a closed surface. This is the total electric flux through the surface.
Right Side: The total charge enclosed by the surface divided by the permittivity of free space. This tells us the source of the flux.
Gaussian Surface: An imaginary closed surface we choose to apply Gauss's Law. The key is to choose a surface where the electric field is either constant or zero, simplifying the integral.

#Applying Gauss's Law: Spherical Symmetry

For a spherical charge distribution, we choose a spherical Gaussian surface. The electric field is radial and constant over the surface.
The surface area of a sphere is $A = 4\pi r^2$ . Therefore, the flux simplifies to: $\Phi = E(4\pi r^2)$
Key Insight: Gauss's Law states that the sum of charge sources within a closed surface is equal to the total electric flux through the surface. The size of the Gaussian surface is independent of the flux, but it must enclose all the charge you are considering.

Exam Tip

FRQ Tip: Always choose a 3D Gaussian surface (sphere, cylinder, pillbox) and not a 2D shape (circle). This is a common point deduction!

#

Key Concept

Charge Density and Gauss's Law

Uniform Charge Density: If the charge is evenly distributed, the enclosed charge ( $q_{enc}$ ) is proportional to the volume enclosed by your Gaussian surface. For example, half the volume encloses half the charge.
Non-uniform Charge Density: If the charge density ( $\rho$ ) varies with radius, you'll need to integrate to find the enclosed charge: $q_{enc} = \int \rho(r) dV$ . This is a common challenge in FRQs, so practice these!

Memory Aid

Memory Aid: Think of Gauss's Law as a 'charge detector.' The flux tells you how much charge is inside the Gaussian surface. The Gaussian surface is like a net, and the charge is the fish it catches.

#

Practice Question

Practice Problems

Let's test your understanding with a few practice problems!

#Multiple Choice Questions

Cube and Electric Flux:

What is the electric flux through the cube shown above?
- (A) Positive
- (B) Negative
- (C) Zero
- (D) Cannot be determined
Answer: (C) Zero. There is no enclosed charge, so the net flux is zero.
Concentric Cylinders:

The inner cylinder has a charge of +Q. What is the charge on the outer cylinder?
- (A) +Q
- (B) -Q
- (C) -2Q
- (D) -3Q
Answer: (D) -3Q. The net charge enclosed by the larger cylinder is -2Q, so the outer cylinder must have a charge of -3Q.
Sphere with Uniform Charge Density:

A sphere of radius R has a total charge Q uniformly distributed throughout its volume. What is the electric field inside the sphere at a distance r < R from the center?
- (A) $E = \frac{Q}{4\pi\epsilon_0 r^2}$
- (B) $E = \frac{Qr}{4\pi\epsilon_0 R^3}$
- (C) $E = \frac{Qr^2}{4\pi\epsilon_0 R^3}$
- (D) $E = \frac{Qr}{4\pi\epsilon_0 R^2}$
Answer: (D). Using Gauss's Law, $E(4\pi r^2) = \frac{q_{enc}}{\epsilon_0}$ , where $q_{enc} = Q\frac{r^3}{R^3}$ . Thus, $E = \frac{Qr}{4\pi\epsilon_0 R^3}$ .
Conducting Sphere:

A conducting sphere of radius R has a charge +Q at its center. What is the electric field inside the sphere?
- (A) $E = \frac{Q}{4\pi\epsilon_0 r^2}$
- (B) $E = \frac{Qr}{4\pi\epsilon_0 R^3}$
- (C) $E = 0$
- (D) $E = \frac{Qr}{4\pi\epsilon_0 R^2}$
Answer: (C) 0. The electric field inside a conductor is always zero.

#Free Response Question (FRQ)

Let's tackle a full FRQ similar to what you might see on the exam. This one involves a non-uniform charge density, so pay close attention!

(From the 2003 AP Physics C: E&M Exam)

A spherical cloud of charge of radius R contains a total charge +Q with a non-uniform volume charge density that varies according to the equation:

$\rho(r) = \rho_0 \frac{r}{R}$

where r is the distance from the center of the cloud. Express all algebraic answers in terms of Q, R, and fundamental constants.

(a) Determine the following as a function of r for r > R:

(i) The magnitude E of the electric field
(ii) The electric potential V

(b) A proton is placed at point P shown above and released. Describe its motion for a long time after its release.

(c) An electron of charge magnitude e is now placed at point P, which is a distance r from the center of the sphere, and released. Determine the kinetic energy of the electron as a function of r as it strikes the cloud.

(d) Derive an expression for $\rho_0$ (rho naught).

(e) Determine the magnitude E of the electric field as a function of r for r <= R.

#FRQ Answer and Scoring Breakdown

(a) (i) Electric Field for r > R

Concept: Use Gauss's Law with a spherical Gaussian surface of radius r > R. The enclosed charge is Q.
Calculation: $\oint \vec{E} \cdot d\vec{A} = \frac{Q_{enc}}{\epsilon_0}$ $E(4\pi r^2) = \frac{Q}{\epsilon_0}$ $E = \frac{Q}{4\pi \epsilon_0 r^2}$
Scoring: 2 points
- 1 point for using Gauss's law correctly
- 1 point for the correct answer

(a) (ii) Electric Potential for r > R

Concept: Integrate the electric field from infinity to r.
Calculation: $V(r) = - \int_{\infty}^{r} \vec{E} \cdot d\vec{r} = - \int_{\infty}^{r} \frac{Q}{4\pi \epsilon_0 r^2} dr$ $V(r) = \frac{Q}{4\pi \epsilon_0 r}$
Scoring: 2 points
- 1 point for the correct integral setup
- 1 point for the correct answer

(b) Motion of the Proton

Concept: The proton will be repelled by the positive charge and move away from the sphere towards infinity.
Description: The proton will accelerate away from the sphere, its speed decreasing as it moves further away due to the decreasing electric field.
Scoring: 1 point

(c) Kinetic Energy of the Electron

Concept: Use conservation of energy. The change in potential energy equals the kinetic energy gained.
Calculation: $\Delta KE = - \Delta PE = e[V(r) - V(R)] = e\left( \frac{Q}{4\pi \epsilon_0 r} - \frac{Q}{4\pi \epsilon_0 R} \right)$ $KE = \frac{eQ}{4\pi \epsilon_0} \left( \frac{1}{r} - \frac{1}{R} \right)$
Scoring: 3 points
- 1 point for using conservation of energy
- 1 point for correct potential difference
- 1 point for the correct answer

(d) Deriving $\rho_0$

Concept: Integrate the charge density over the volume of the sphere and set it equal to the total charge Q.
Calculation: $Q = \int \rho(r) dV = \int_{0}^{R} \rho_0 \frac{r}{R} 4\pi r^2 dr$ $Q = \frac{4\pi \rho_0}{R} \int_{0}^{R} r^3 dr = \frac{4\pi \rho_0}{R} \frac{R^4}{4}$ $Q = \pi \rho_0 R^3$ $\rho_0 = \frac{Q}{\pi R^3}$
Scoring: 3 points
- 1 point for the correct integral setup
- 1 point for the correct integration
- 1 point for the correct answer

(e) Electric Field for r <= R

Concept: Use Gauss's Law with a spherical Gaussian surface of radius r <= R. The enclosed charge is found by integrating the charge density up to r.
Calculation: $q_{enc} = \int_{0}^{r} \rho(r) 4\pi r^2 dr = \int_{0}^{r} \frac{Q}{\pi R^3} \frac{r}{R} 4\pi r^2 dr$ $q_{enc} = \frac{4Q}{R^4} \int_{0}^{r} r^3 dr = \frac{4Q}{R^4} \frac{r^4}{4} = \frac{Qr^4}{R^4}$ $E(4\pi r^2) = \frac{Qr^4}{\epsilon_0 R^4}$ $E = \frac{Qr^2}{4\pi \epsilon_0 R^4}$
Scoring: 4 points
- 1 point for using Gauss's law correctly
- 1 point for correct enclosed charge integral
- 1 point for correct integration
- 1 point for the correct answer

Exam Tip

Time Management: On FRQs, quickly jot down the key concepts and formulas before diving into calculations. This helps organize your thoughts and saves time.

#Final Exam Focus

Alright, you've made it to the home stretch! Here's a quick recap of the highest-priority topics and some final tips:

High-Value Topics:
- Gauss's Law: Understanding how to apply it to different charge distributions (spheres, cylinders, planes) is crucial.
- Electric Flux: Know the definition, how to calculate it, and its relationship to enclosed charge.
- Charge Density: Be comfortable with both uniform and non-uniform charge distributions and how to find the enclosed charge.
Common Question Types:
- FRQs: Expect at least one FRQ that requires you to apply Gauss's Law to find the electric field and potential for a given charge distribution. Be ready to integrate charge density.
- MCQs: Look for questions that test your understanding of flux, enclosed charge, and the behavior of conductors and insulators.
Last-Minute Tips:
- Practice, Practice, Practice: The more problems you solve, the more comfortable you'll be on exam day.
- Show Your Work: On FRQs, clearly show each step of your calculations. Partial credit is your friend!
- Units: Always include units in your final answers.
- Stay Calm: Take a deep breath, read each question carefully, and trust your preparation. You've got this!

Common Mistake

Common Mistake: Forgetting to use a 3D Gaussian surface on FRQs. Always use a sphere, cylinder, or pillbox, not a circle!

Quick Fact

Quick Fact: The electric field inside a conductor is always zero. This can save you time on MCQs!

Memory Aid

Memory Aid: Remember the relationship: Flux is like the 'flow' of electric field lines, and Gauss's Law connects that flow to the 'source' of the field (the charge).

Good luck on your exam! You've got the knowledge and the skills to ace it. Go get 'em!

#AP Physics C: E&M - Flux and Gauss's Law Study Guide

#Electric Flux: What's Flowing Through?

#What is Flux?

Visualizing Flux: Imagine an area on a charged object. The electric flux is the measure of how many electric field lines pass through this area. If the area is parallel to the electric field, the math is straightforward. If not, we use the dot product.
Calculating Flux:
- When the electric field ( $E$ ) is uniform and perpendicular to the area ( $A$ ), the flux ( $\Phi$ ) is simply: $\Phi = EA$
- When the field is at an angle $\theta$ to the area, we use the dot product: $\Phi = \vec{E} \cdot \vec{A} = EA \cos(\theta)$

#

Key Concept

Flux Through Closed Surfaces

Sign Convention: Field lines entering a closed surface = negative flux. Field lines exiting a closed surface = positive flux. It's all about direction!
Net Flux: If there isn't a source or sink of charge inside the area, the net flux is zero. This means the total number of lines entering equals the total number of lines exiting.
- In the image above, there are 11 lines entering and 11 lines exiting. The net flux is zero.

#Gauss's Law: Connecting Flux and Charge

#The Core Idea

The Formula:

$\Phi_E = \oint \vec{E} \cdot d\vec{A} = \frac{Q_{enc}}{\epsilon_0}$

Where:
- $\Phi_E$ is the electric flux
- $\oint \vec{E} \cdot d\vec{A}$ is the surface integral of the electric field over a closed surface
- $Q_{enc}$ is the total charge enclosed by the surface
- $\epsilon_0$ is the permittivity of free space (a constant)

#Breaking Down the Formula

Left Side: The integral of the electric field over a closed surface. This is the total electric flux through the surface.
Right Side: The total charge enclosed by the surface divided by the permittivity of free space. This tells us the source of the flux.
Gaussian Surface: An imaginary closed surface we choose to apply Gauss's Law. The key is to choose a surface where the electric field is either constant or zero, simplifying the integral.

#Applying Gauss's Law: Spherical Symmetry

For a spherical charge distribution, we choose a spherical Gaussian surface. The electric field is radial and constant over the surface.
The surface area of a sphere is $A = 4\pi r^2$ . Therefore, the flux simplifies to: $\Phi = E(4\pi r^2)$
Key Insight: Gauss's Law states that the sum of charge sources within a closed surface is equal to the total electric flux through the surface. The size of the Gaussian surface is independent of the flux, but it must enclose all the charge you are considering.

Exam Tip

FRQ Tip: Always choose a 3D Gaussian surface (sphere, cylinder, pillbox) and not a 2D shape (circle). This is a common point deduction!

#

Key Concept

Charge Density and Gauss's Law

Uniform Charge Density: If the charge is evenly distributed, the enclosed charge ( $q_{enc}$ ) is proportional to the volume enclosed by your Gaussian surface. For example, half the volume encloses half the charge.
Non-uniform Charge Density: If the charge density ( $\rho$ ) varies with radius, you'll need to integrate to find the enclosed charge: $q_{enc} = \int \rho(r) dV$ . This is a common challenge in FRQs, so practice these!

Memory Aid

#

Practice Question

Practice Problems

Let's test your understanding with a few practice problems!

#Multiple Choice Questions

Cube and Electric Flux:

What is the electric flux through the cube shown above?
- (A) Positive
- (B) Negative
- (C) Zero
- (D) Cannot be determined
Answer: (C) Zero. There is no enclosed charge, so the net flux is zero.
Concentric Cylinders:

The inner cylinder has a charge of +Q. What is the charge on the outer cylinder?
- (A) +Q
- (B) -Q
- (C) -2Q
- (D) -3Q
Answer: (D) -3Q. The net charge enclosed by the larger cylinder is -2Q, so the outer cylinder must have a charge of -3Q.
Sphere with Uniform Charge Density:

A sphere of radius R has a total charge Q uniformly distributed throughout its volume. What is the electric field inside the sphere at a distance r < R from the center?
- (A) $E = \frac{Q}{4\pi\epsilon_0 r^2}$
- (B) $E = \frac{Qr}{4\pi\epsilon_0 R^3}$
- (C) $E = \frac{Qr^2}{4\pi\epsilon_0 R^3}$
- (D) $E = \frac{Qr}{4\pi\epsilon_0 R^2}$
Answer: (D). Using Gauss's Law, $E(4\pi r^2) = \frac{q_{enc}}{\epsilon_0}$ , where $q_{enc} = Q\frac{r^3}{R^3}$ . Thus, $E = \frac{Qr}{4\pi\epsilon_0 R^3}$ .
Conducting Sphere:

A conducting sphere of radius R has a charge +Q at its center. What is the electric field inside the sphere?
- (A) $E = \frac{Q}{4\pi\epsilon_0 r^2}$
- (B) $E = \frac{Qr}{4\pi\epsilon_0 R^3}$
- (C) $E = 0$
- (D) $E = \frac{Qr}{4\pi\epsilon_0 R^2}$
Answer: (C) 0. The electric field inside a conductor is always zero.

#Free Response Question (FRQ)

Let's tackle a full FRQ similar to what you might see on the exam. This one involves a non-uniform charge density, so pay close attention!

(From the 2003 AP Physics C: E&M Exam)

A spherical cloud of charge of radius R contains a total charge +Q with a non-uniform volume charge density that varies according to the equation:

$\rho(r) = \rho_0 \frac{r}{R}$

where r is the distance from the center of the cloud. Express all algebraic answers in terms of Q, R, and fundamental constants.

(a) Determine the following as a function of r for r > R:

(i) The magnitude E of the electric field
(ii) The electric potential V

(b) A proton is placed at point P shown above and released. Describe its motion for a long time after its release.

(d) Derive an expression for $\rho_0$ (rho naught).

(e) Determine the magnitude E of the electric field as a function of r for r <= R.

#FRQ Answer and Scoring Breakdown

(a) (i) Electric Field for r > R

Concept: Use Gauss's Law with a spherical Gaussian surface of radius r > R. The enclosed charge is Q.
Calculation: $\oint \vec{E} \cdot d\vec{A} = \frac{Q_{enc}}{\epsilon_0}$ $E(4\pi r^2) = \frac{Q}{\epsilon_0}$ $E = \frac{Q}{4\pi \epsilon_0 r^2}$
Scoring: 2 points
- 1 point for using Gauss's law correctly
- 1 point for the correct answer

(a) (ii) Electric Potential for r > R

Concept: Integrate the electric field from infinity to r.
Calculation: $V(r) = - \int_{\infty}^{r} \vec{E} \cdot d\vec{r} = - \int_{\infty}^{r} \frac{Q}{4\pi \epsilon_0 r^2} dr$ $V(r) = \frac{Q}{4\pi \epsilon_0 r}$
Scoring: 2 points
- 1 point for the correct integral setup
- 1 point for the correct answer

(b) Motion of the Proton

Concept: The proton will be repelled by the positive charge and move away from the sphere towards infinity.
Description: The proton will accelerate away from the sphere, its speed decreasing as it moves further away due to the decreasing electric field.
Scoring: 1 point

(c) Kinetic Energy of the Electron

Concept: Use conservation of energy. The change in potential energy equals the kinetic energy gained.
Calculation: $\Delta KE = - \Delta PE = e[V(r) - V(R)] = e\left( \frac{Q}{4\pi \epsilon_0 r} - \frac{Q}{4\pi \epsilon_0 R} \right)$ $KE = \frac{eQ}{4\pi \epsilon_0} \left( \frac{1}{r} - \frac{1}{R} \right)$
Scoring: 3 points
- 1 point for using conservation of energy
- 1 point for correct potential difference
- 1 point for the correct answer

(d) Deriving $\rho_0$

Concept: Integrate the charge density over the volume of the sphere and set it equal to the total charge Q.
Calculation: $Q = \int \rho(r) dV = \int_{0}^{R} \rho_0 \frac{r}{R} 4\pi r^2 dr$ $Q = \frac{4\pi \rho_0}{R} \int_{0}^{R} r^3 dr = \frac{4\pi \rho_0}{R} \frac{R^4}{4}$ $Q = \pi \rho_0 R^3$ $\rho_0 = \frac{Q}{\pi R^3}$
Scoring: 3 points
- 1 point for the correct integral setup
- 1 point for the correct integration
- 1 point for the correct answer

(e) Electric Field for r <= R

Concept: Use Gauss's Law with a spherical Gaussian surface of radius r <= R. The enclosed charge is found by integrating the charge density up to r.
Calculation: $q_{enc} = \int_{0}^{r} \rho(r) 4\pi r^2 dr = \int_{0}^{r} \frac{Q}{\pi R^3} \frac{r}{R} 4\pi r^2 dr$ $q_{enc} = \frac{4Q}{R^4} \int_{0}^{r} r^3 dr = \frac{4Q}{R^4} \frac{r^4}{4} = \frac{Qr^4}{R^4}$ $E(4\pi r^2) = \frac{Qr^4}{\epsilon_0 R^4}$ $E = \frac{Qr^2}{4\pi \epsilon_0 R^4}$
Scoring: 4 points
- 1 point for using Gauss's law correctly
- 1 point for correct enclosed charge integral
- 1 point for correct integration
- 1 point for the correct answer

Exam Tip

Time Management: On FRQs, quickly jot down the key concepts and formulas before diving into calculations. This helps organize your thoughts and saves time.

#Final Exam Focus

Alright, you've made it to the home stretch! Here's a quick recap of the highest-priority topics and some final tips:

High-Value Topics:
- Gauss's Law: Understanding how to apply it to different charge distributions (spheres, cylinders, planes) is crucial.
- Electric Flux: Know the definition, how to calculate it, and its relationship to enclosed charge.
- Charge Density: Be comfortable with both uniform and non-uniform charge distributions and how to find the enclosed charge.
Common Question Types:
- FRQs: Expect at least one FRQ that requires you to apply Gauss's Law to find the electric field and potential for a given charge distribution. Be ready to integrate charge density.
- MCQs: Look for questions that test your understanding of flux, enclosed charge, and the behavior of conductors and insulators.
Last-Minute Tips:
- Practice, Practice, Practice: The more problems you solve, the more comfortable you'll be on exam day.
- Show Your Work: On FRQs, clearly show each step of your calculations. Partial credit is your friend!
- Units: Always include units in your final answers.
- Stay Calm: Take a deep breath, read each question carefully, and trust your preparation. You've got this!

Common Mistake

Common Mistake: Forgetting to use a 3D Gaussian surface on FRQs. Always use a sphere, cylinder, or pillbox, not a circle!

Quick Fact

Quick Fact: The electric field inside a conductor is always zero. This can save you time on MCQs!

Memory Aid

Memory Aid: Remember the relationship: Flux is like the 'flow' of electric field lines, and Gauss's Law connects that flow to the 'source' of the field (the charge).

Good luck on your exam! You've got the knowledge and the skills to ace it. Go get 'em!

Gauss' Law

Abigail Wright

#AP Physics C: E&M - Flux and Gauss's Law Study Guide

#Electric Flux: What's Flowing Through?

#What is Flux?

#

#Gauss's Law: Connecting Flux and Charge

#The Core Idea

#Breaking Down the Formula

#Applying Gauss's Law: Spherical Symmetry

#

#

#Multiple Choice Questions

#Free Response Question (FRQ)

#FRQ Answer and Scoring Breakdown

#Final Exam Focus

Explore more resources

How are we doing?

Gauss' Law

Abigail Wright

#AP Physics C: E&M - Flux and Gauss's Law Study Guide

#Electric Flux: What's Flowing Through?

#What is Flux?

#

#Gauss's Law: Connecting Flux and Charge

#The Core Idea

#Breaking Down the Formula

#Applying Gauss's Law: Spherical Symmetry

#

#

#Multiple Choice Questions

#Free Response Question (FRQ)

#FRQ Answer and Scoring Breakdown

#Final Exam Focus

Explore more resources

How are we doing?