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AP Physics 2 : Electric Fields

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Example Question #1 : Electric Fields

Physics2set1q8

What is the value of the electric field at point C?

Points A and B are point charges.

Possible Answers:

$22.5 \frac{N}{C}$ in the direction

$5.24 \frac{N}{C}$ in the direction

$8.99 \frac{N}{C}$ in the direction

$22.5 \frac{N}{C}$ in the direction

Correct answer:

$22.5 \frac{N}{C}$ in the direction

Explanation:

First, let's calculate the electric field at C due to point A.

$E_{1}=k\frac{Q_{1}}{R^2}$

$E_{2}=k\frac{Q_{2}}{R^2}$

We can tell that the net electric field will be in the direction.

$E_{net}=E_{2}-E_{1}$

$E_{net}=\frac{k\cdot 10^{-9}}{1^2}(3-\frac{1}{2})$

$E_{net}= 22.5 \frac{N}{C}$ in the direction.

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Example Question #12 : Electrostatics

What is the electric field 15m away from a particle with a charge of 15mC ?

Possible Answers:

$6\cdot 10^8\frac{N}{C}$ towards the charged particle

$6\cdot 10^3\frac{N}{C}$ away from the charged particle

$6\frac{N}{C}$ away from the charged particle

$6\cdot 10^5\frac{N}{C}$ towards the charged particle

$6\cdot 10^5\frac{N}{C}$ away from the charged particle

Correct answer:

$6\cdot 10^5\frac{N}{C}$ away from the charged particle

Explanation:

Use the equation to find the magnitude of an electric field at a point.

$E_{field}=\frac{kq}{r^2}$

$E_{field}=9\cdot10^{9}\frac{N\cdot m^{2}}{C^{2}}\cdot\frac{15mC}{(15m)^{2}}$

Solve.

$E_{field}=600000=6\cdot 10^5\frac{N}{C}$

Since it is a positive charge, the electric field lines will be pointing away from the charged particle.

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Example Question #1 : Electric Fields

You are at point (0,5). A charge of -50nC is placed at the origin. What charge would you need to place at (0,-3) to cause there to be no net electric field at your location.

Possible Answers:

None of these

64nC

-64nC

-128nC

128nC

Correct answer:

128nC

Explanation:

We will need to use the electric field equation, twice. Because we are given coordinates, we will need to use vector notation.

$E_{total}=E_{1}+E_{2}$

$E_{1}=k\frac{q_{1}}{r_{1}^2} \widehat{r_1}$

$E_{2}=k\frac{q_{2}}{r_{2}^2} \widehat{r_{2}}$

Combine the two equations.

$E_{total}=k\frac{q_{1}}{r_{1}^2} \widehat{r_1} + k\frac{q_{2}}{r_{2}^2} \widehat{r_2}$

Plug in known values.

$0 = \frac{50 nC}{5^2}\frac{<0, 5>}{5}+ \frac{q_2}{8^2}\frac{<0, 8>}{8}$

q_2 = 128 nC

Note that the charge is positive. This is because the electric field lines point towards the negative charge at the origin, and in order to balance this at your location, the electric field lines of the charge at (0,-3) must be pointing away from the charge.

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Example Question #1 : Electric Fields

Potential problem

In the diagram above where along the line connecting the two charges is the electric potential (V) due to the two charges zero?

Possible Answers:

1.2 m to the left of Q_B

1.2 m to the right of Q_B

1.2 m to the right of Q_A

There is no point on the line where the electric potential is zero

1.2 m to the left from Q_A

Correct answer:

1.2 m to the right of Q_A

Explanation:

Potential is not a vector, so we just add up the two potentials and set them to each other. The equation for electric potential is:

$V=\frac{1}{4\pi \epsilon _{0}}\frac{q}{r}$

$\frac{1}{4\pi \epsilon _{0}}\frac{Q_A}{d}=\frac{1}{4\pi \epsilon _{0}}\frac{Q_B}{(2-d)}$

If the point we are looking for is distance from Q_A , it's (2-d) from Q_B . Cancel all the common terms, then cross-multiply:

$\frac{1}{4\pi \epsilon _{0}}\frac{3\times10^{-9}}{d}=\frac{1}{4\pi \epsilon _{0}}\frac{2\times10^{-9}}{(2-d)}$

$\frac{3}{d}=\frac{2}{(2-d)}$

3(2-d)=2d

d=1.2 m

Since we had associated with Q_A , it's from that charge toward the weaker charge.

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Example Question #15 : Electrostatics

Electric field problem

In the diagram above, where is the electric field due to the two charges zero?

Possible Answers:

0.56 m to the right of Q_B

0.56 m to the left of Q_A

There is no point where the electric field is zero

0.56 m to the left of Q_B

0.56 m to the right of Q_A

Correct answer:

0.56 m to the right of Q_A

Explanation:

Electric field is a vector. In between the charges is where Q_A 's field points right and Q_B 's field points left, so somewhere in between, the two vectors will add to zero. It will be closer to the weaker charge, Q_B , but since field depends on the inverse-square of the distance, it will not be linear, and we'll have to do some math.

First set the magnitudes of the two fields equal to each other. The vectors point in opposite directions, so when their magnitudes are equal, the vector sum is zero.

$E_A=E_B \newline \frac{1}{4\pi _0}\frac{Q_A}{d_A^2}=\frac{1}{4\pi _0}\frac{Q_B}{d_B^2}\newline \frac{1}{4\pi _0}\frac{5\times10^{-9}}{d_A^2}=\frac{1}{4\pi _0}\frac{3\times10^{-9}}{(1-d_A)^{2}} \newline \frac{5}{d_A^{2}}=\frac{3}{(1-d_A)^{2}}$

Many of the terms cancel, making it a bit easier. Now cross multiply and solve the quadratic:

$2d_A^{2}-10d_A +5=0$

d_A=0.56 m

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Example Question #1 : Electric Fields

Coloumbs law for varsity

If charge has a value of $-9*10^{-13}C$ , charge has a value of $8*10^{-13}C$ , and is equal to 50 cm , what will be the magnitude of the force experienced by charge ?

Possible Answers:

None of these

$|F|=5.55*10^{-14}N$

$|F|=2.59*10^{-14}N$

$|F|=6.75*10^{-14}N$

$|F|=1.11*10^{-14}N$

Correct answer:

$|F|=2.59*10^{-14}N$

Explanation:

Using coulombs law to solve

$F=k\frac{q_1q_2}{r^2}$

Where:

q_1 it the first charge, in coulombs.

q_2 is the second charge, in coulombs.

is the distance between them, in meters

is the constant of $9*10^9\frac{N*m^2}{C^2}$

Converting into

$50cm*\frac{1m}{100cm}=.50m$

Plugging values into coulombs law

$F=9*10^{9}\frac{-9*10^{-13}8*10^{-13}}{.50^2}$

$F=-2.59*10^{-14}N$

Magnitude will be the absolute value

$|F|=2.59*10^{-14}N$

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Example Question #1 : Electric Fields

Coloumbs law for varsity

Charge has a charge of 9 nC

Charge has a charge of -8nC

The distance between their centers, is 3 mm .

What is the magnitude of the electric field at the center of due to

Possible Answers:

$|\overrightarrow{E}|=9.5*10^6\frac{N}{C}$

None of these

$|\overrightarrow{E}|=2.21*10^6\frac{N}{C}$

$|\overrightarrow{E}|=6.9*10^6\frac{N}{C}$

$|\overrightarrow{E}|=8*10^6\frac{N}{C}$

Correct answer:

$|\overrightarrow{E}|=8*10^6\frac{N}{C}$

Explanation:

Using the electric field equation:

$\overrightarrow{E}=k\frac{q}{r^2}$

Where is $9.0*10^9 N\frac{m^2}{C^2}$

is the charge, in coulombs

is the distance, in meters .

Convert to and plug in values:

$\overrightarrow{E}=9.0*10^9\frac{-8*10^{-9}}{.003^2}$

$\overrightarrow{E}=8*10^6\frac{N}{C}$

Magnitude is equivalent to absolute value:

$|\overrightarrow{E}|=8*10^6\frac{N}{C}$

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Example Question #18 : Electrostatics

Coloumbs law for varsity

Charge has a charge of 19 nC

Charge has a charge of -28nC

The distance between their centers, is 4.5 mm .

What is the magnitude of the electric field at the center of due to ?

Possible Answers:

$|\overrightarrow{E}|=8.44*10^6\frac{N}{C}$

$|\overrightarrow{E}|=3.98*10^6\frac{N}{C}$

None of these

$|\overrightarrow{E}|=6.11*10^6\frac{N}{C}$

$|\overrightarrow{E}|=3.75*10^6\frac{N}{C}$

Correct answer:

$|\overrightarrow{E}|=8.44*10^6\frac{N}{C}$

Explanation:

Using the electric field equation:

$\overrightarrow{E}=k\frac{q}{r^2}$

Where is $9.0*10^9 N\frac{m^2}{C^2}$

is the charge, in coulombs

is the distance, in meters .

Convert to and plug in values:

$\overrightarrow{E}=9.0*10^9\frac{19*10^{-9}}{.0045^2}$

$\overrightarrow{E}=8.44*10^6\frac{N}{C}$

Magnitude is equivalent to absolute value:

$|\overrightarrow{E}|=8.44*10^6\frac{N}{C}$

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Example Question #19 : Electrostatics

Coloumbs law for varsity

Charge has a charge of 35 nC

Charge has a charge of -48nC

The distance between their centers, is 25 mm .

What is the magnitude of the electric field at the center of due to

Possible Answers:

$|\overrightarrow{E}|=1.73*10^5\frac{N}{C}$

$|\overrightarrow{E}|=3.77*10^5\frac{N}{C}$

$|\overrightarrow{E}|=2.25*10^5\frac{N}{C}$

None of these

$|\overrightarrow{E}|=6.91*10^5\frac{N}{C}$

Correct answer:

$|\overrightarrow{E}|=6.91*10^5\frac{N}{C}$

Explanation:

Use the electric field equation:

$\overrightarrow{E}=k\frac{q}{r^2}$

Where is $9.0*10^9 N\frac{m^2}{C^2}$

is the charge, in coulombs

is the distance, in meters .

Convert to and plug in values:

$\overrightarrow{E}=9.0*10^9\frac{-48*10^{-9}}{.025^2}$

$\overrightarrow{E}=-6.91*10^5\frac{N}{C}$

Magnitude is equivalent to absolute value:

$|\overrightarrow{E}|=6.91*10^5\frac{N}{C}$

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Example Question #1 : Electric Fields

What is the electric field strength of a stationary 30C charge at a distance of 80cm away?

$k=8.9875*10^{9}\: \frac{N\cdot m^{2}}{C^{2}}$

Possible Answers:

$3.370*10^{11} \frac{N}{C}$ pointing away from the source charge

$3.370*10^{11} \frac{N}{C}$ pointing towards the source charge

$4.213*10^{11} \frac{N}{C}$ pointing towards the source charge

$4.213*10^{11} \frac{N}{C}$ pointing away from the source charge

Correct answer:

$4.213*10^{11} \frac{N}{C}$ pointing away from the source charge

Explanation:

To solve this question, we need to recall the equation for electric field strength.

$E=k\frac{q_{source}}{r^{2}}$

Notice that the equation above represents an inverse square relationship between the electric field and the distance between the source charge and the point of space that we are interested in.

Plug in the values given in the question stem to calculate the magnitude of the electric field.

$E=\left(8.9875*10^{9}\: \frac{N\cdot m^{2}}{C^{2}}\right)\frac{30 C}{(0.80 m)^{2}}=4.213*10^{11} \frac{N}{C}$

Now that we have determined the magnitude of the electric field, we need to identify which direction it is pointing with respect to the source charge. To do this, we'll need to remember that electric fields point away from positive charges and towards negative charges. Therefore, since our source charge is positive, the electric field will be pointing away from the source charge.

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AP Physics 2 : Electric Fields

Study concepts, example questions & explanations for AP Physics 2

All AP Physics 2 Resources

Example Questions

Example Question #1 : Electric Fields

Example Question #12 : Electrostatics

Example Question #1 : Electric Fields

Example Question #1 : Electric Fields

Example Question #15 : Electrostatics

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