electric field due to multiple point charges
two point charges are placed on the x axis. (figure 1)the
first charge, ( q_1 = 8.00 , ext{nc} ), is placed a distance 16.0 m
from the origin along the positive x axis; the second
charge, ( q_2 = 6.00 , ext{nc} ), is placed a distance 9.00 m from
the origin along the negative x axis.
figure
1 of 1
b (0 m, 15 m)
a (0 m, 12 m)
o (0 m, 0 m)
( q_2 ) (-9 m, 0 m)
( q_1 ) (+16 m, 0 m)
correct
part b
an unknown additional charge ( q_3 ) is now placed at point b, located at coordinates (0 m, 15.0 m )
find the magnitude and sign of ( q_3 ) needed to make the total electric field at point a equal to zero.
express your answer in nanocoulombs to three significant figures.
view available hint(s)
( q_3 = )
( square )
( ext{nc} )
submit
provide feedback

Question

electric field due to multiple point charges
two point charges are placed on the x axis. (figure 1)the
first charge, ( q_1 = 8.00 , 	ext{nc} ), is placed a distance 16.0 m
from the origin along the positive x axis; the second
charge, ( q_2 = 6.00 , 	ext{nc} ), is placed a distance 9.00 m from
the origin along the negative x axis.
figure
1 of 1
b (0 m, 15 m)
a (0 m, 12 m)
o (0 m, 0 m)
( q_2 ) (-9 m, 0 m)
( q_1 ) (+16 m, 0 m)
correct
part b
an unknown additional charge ( q_3 ) is now placed at point b, located at coordinates (0 m, 15.0 m )
find the magnitude and sign of ( q_3 ) needed to make the total electric field at point a equal to zero.
express your answer in nanocoulombs to three significant figures.
view available hint(s)
( q_3 = )
( square )
( 	ext{nc} )
submit
provide feedback

Accepted Answer

# Explanation:
## Step1: Find distances from $ q_1, q_2, q_3 $ to point A
- Distance from $ q_1 $ to A: $ r_{1A} = \sqrt{(16 - 0)^2 + (0 - 12)^2} = \sqrt{256 + 144} = \sqrt{400} = 20 \, \text{m} $
- Distance from $ q_2 $ to A: $ r_{2A} = \sqrt{(-9 - 0)^2 + (0 - 12)^2} = \sqrt{81 + 144} = \sqrt{225} = 15 \, \text{m} $
- Distance from $ q_3 $ to A: $ r_{3A} = 15 - 12 = 3 \, \text{m} $ (since $ q_3 $ is at (0,15) and A at (0,12))

## Step2: Calculate electric fields from $ q_1 $ and $ q_2 $ at A
- Electric field due to $ q_1 $ at A: $ E_{1A} = k\frac{|q_1|}{r_{1A}^2} $, direction: from $ q_1 $ to A (since $ q_1 $ is positive, field points away). The y - component: $ E_{1A,y} = E_{1A} \cdot \frac{12}{20} $ (using trigonometry, $ \sin\theta = \frac{12}{20} $ where $ \theta $ is the angle between $ r_{1A} $ and y - axis). $ E_{1A} = 9\times10^9 \times \frac{8\times10^{-9}}{20^2} = 9\times10^9 \times \frac{8\times10^{-9}}{400} = 0.18 \, \text{N/C} $. So $ E_{1A,y} = 0.18\times\frac{12}{20}= 0.108 \, \text{N/C} $ (upward? Wait, no: $ q_1 $ is at (16,0), A at (0,12). The vector from $ q_1 $ to A is (- 16,12). So the y - component is positive (upward) and x - component is negative (leftward). But we are interested in the total field at A, and we need to consider the direction of $ E_3 $ (from $ q_3 $ to A or A to $ q_3 $ depending on sign of $ q_3 $). Wait, actually, let's recast:

- Electric field due to $ q_2 $ at A: $ q_2 = 6 \, \text{nC} $ (positive? Wait, $ q_2 $ is at (- 9,0), so distance to A is 15 m. $ E_{2A} = k\frac{|q_2|}{r_{2A}^2} = 9\times10^9\times\frac{6\times10^{-9}}{15^2}=9\times10^9\times\frac{6\times10^{-9}}{225}=0.24 \, \text{N/C} $. The vector from $ q_2 $ to A is (9,12). The y - component: $ E_{2A,y}=E_{2A}\times\frac{12}{15}=0.24\times\frac{12}{15} = 0.192 \, \text{N/C} $ (upward), x - component: $ E_{2A,x}=E_{2A}\times\frac{9}{15}=0.24\times\frac{9}{15}=0.144 \, \text{N/C} $ (rightward)

- Electric field due to $ q_1 $ at A: vector from $ q_1 $ to A is (- 16,12). The magnitude $ E_{1A}=9\times10^9\times\frac{8\times10^{-9}}{20^2}=0.18 \, \text{N/C} $. y - component: $ E_{1A,y}=E_{1A}\times\frac{12}{20}=0.18\times0.6 = 0.108 \, \text{N/C} $ (upward), x - component: $ E_{1A,x}=E_{1A}\times\frac{- 16}{20}=0.18\times(- 0.8)= - 0.144 \, \text{N/C} $ (leftward)

Now, the x - components of $ E_{1A} $ and $ E_{2A} $ cancel out: $ E_{x,total}= - 0.144 + 0.144 = 0 $. The y - component of the total field from $ q_1 $ and $ q_2 $ is $ E_{y,total}=0.108 + 0.192 = 0.3 \, \text{N/C} $ (upward)

## Step3: Calculate $ q_3 $ to cancel $ E_{y,total} $
The electric field due to $ q_3 $ at A must be equal in magnitude and opposite in direction to $ E_{y,total} $. So $ E_{3A}=k\frac{|q_3|}{r_{3A}^2} $, and since $ E_{y,total} $ is upward, $ E_{3A} $ must be downward. So if $ E_{y,total}=0.3 \, \text{N/C} $ upward, $ E_{3A}=0.3 \, \text{N/C} $ downward.

$ E_{3A}=k\frac{|q_3|}{r_{3A}^2} $

$ 0.3 = 9\times10^9\times\frac{|q_3|\times10^{-9}}{3^2} $ (since $ q_3 $ is in nC, $ |q_3|\times10^{-9} $ C)

$ 0.3 = 9\times\frac{|q_3|}{9} $

$ 0.3 = |q_3| $

Wait, wait, let's redo the calculation:

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

We have $ E_{3A} = 0.3 \, \text{N/C} $ (magnitude), $ r = 3 \, \text{m} $, $ k = 9\times10^9 \, \text{N m}^2/\text{C}^2 $

$ |q_3| = \frac{E_{3A} \times r^2}{k} $

Substitute values:

$ E_{3A}=0.3 \, \text{N/C} $, $ r = 3 \, \text{m} $, $ k = 9\times10^9 $

$ |q_3|=\frac{0.3\times3^2}{9\times10^9} \, \text{C} $

$ |q_3|=\frac{0.3\times9}{9\times10^9} \, \text{C}=\frac{0.3}{10^9} \, \text{C}=0.3\times10^{-9} \, \text{C}=0.3 \, \text{nC} $

But wait, the direction: the field from $ q_3 $ at A is downward. So if $ q_3 $ is positive, the field from $ q_3 $ at A is away from $ q_3 $ (since $ q_3 $ is at (0,15), A is at (0,12), so the field from positive $ q_3 $ at A would be downward (towards A? No: positive charge repels, so field from $ q_3 $ at A is from $ q_3 $ to A? Wait, $ q_3 $ is at (0,15), A is at (0,12). So the vector from $ q_3 $ to A is (0, - 3). So the electric field due to $ q_3 $ at A is in the direction from $ q_3 $ to A (if $ q_3 $ is positive, field points away from $ q_3 $, so from $ q_3 $ to A (since A is below $ q_3 $). Wait, no: electric field due to a positive charge at a point below it is downward (towards the point below). Wait, no: the electric field lines go away from positive charges. So at point A (below $ q_3 $), the electric field due to $ q_3 $ (positive) would be downward (towards A? No, away from $ q_3 $, so from $ q_3 $ to A is downward, so the field is downward. The total field from $ q_1 $ and $ q_2 $ is upward, so to cancel it, the field from $ q_3 $ must be downward, which means $ q_3 $ is positive? Wait, no: if $ q_3 $ is negative, the field from $ q_3 $ at A is towards $ q_3 $ (upward), which would add to the upward field. So $ q_3 $ must be positive, so that its field at A is downward (away from $ q_3 $). Wait, but our calculation gave $ |q_3| = 0.3 \, \text{nC} $, but let's check the y - component again.

Wait, recalculating $ E_{1A,y} $ and $ E_{2A,y} $:

For $ q_1 $: $ r_{1A} = 20 \, \text{m} $, $ q_1 = 8 \, \text{nC} = 8\times10^{-9} \, \text{C} $

$ E_{1A} = k\frac{q_1}{r_{1A}^2} = 9\times10^9\times\frac{8\times10^{-9}}{20^2} = \frac{72}{400}=0.18 \, \text{N/C} $

The angle $ \theta_1 $ between $ r_{1A} $ (from $ q_1 $ to A) and the y - axis: $ \sin\theta_1=\frac{16}{20}=0.8 $, $ \cos\theta_1=\frac{12}{20}=0.6 $. Wait, I had the components reversed earlier! The x - component is $ E_{1A}\sin\theta_1 $ (since the horizontal distance is 16, vertical is 12), so $ E_{1A,x}=E_{1A}\times\frac{16}{20}=0.18\times0.8 = 0.144 \, \text{N/C} $ (leftward, since x is negative direction from $ q_1 $ to A), $ E_{1A,y}=E_{1A}\times\frac{12}{20}=0.18\times0.6 = 0.108 \, \text{N/C} $ (upward)

For $ q_2 $: $ r_{2A}=15 \, \text{m} $, $ q_2 = 6 \, \text{nC}=6\times10^{-9} \, \text{C} $

$ E_{2A}=k\frac{q_2}{r_{2A}^2}=9\times10^9\times\frac{6\times10^{-9}}{15^2}=\frac{54}{225}=0.24 \, \text{N/C} $

The angle $ \theta_2 $ between $ r_{2A} $ (from $ q_2 $ to A) and the y - axis: $ \sin\theta_2=\frac{9}{15}=0.6 $, $ \cos\theta_2=\frac{12}{15}=0.8 $

So $ E_{2A,x}=E_{2A}\times\frac{9}{15}=0.24\times0.6 = 0.144 \, \text{N/C} $ (rightward), $ E_{2A,y}=E_{2A}\times\frac{12}{15}=0.24\times0.8 = 0.192 \, \text{N/C} $ (upward)

Now, x - components: $ E_{x,total}= - 0.144 + 0.144 = 0 $ (correct). Y - components: $ E_{y,total}=0.108 + 0.192 = 0.3 \, \text{N/C} $ (upward, correct)

Now, $ q_3 $ is at (0,15), A is at (0,12), so distance $ r_{3A}=3 \, \text{m} $. The electric field due to $ q_3 $ at A must be downward (to cancel the upward $ E_{y,total} $). So the direction of $ E_{3A} $ is downward, which means the electric field is towards A from $ q_3 $ if $ q_3 $ is negative (since negative charges attract, field lines go towards the negative charge). Wait, I made a mistake earlier: if $ q_3 $ is negative, the field at A (below $ q_3 $) is upward (towards $ q_3 $)? No, wait: electric field due to a negative charge at a point below it: the field lines go towards the negative charge, so from A to $ q_3 $, which is upward. But we need the field from $ q_3 $ at A to be downward. So $ q_3 $ must be positive, so that the field at A is downward (away from $ q_3 $). Wait, no: positive charge repels, so at A (below $ q_3 $), the field due to positive $ q_3 $ is downward (away from $ q_3 $, towards A? No, away from $ q_3 $ would be downward (since $ q_3 $ is above A). So the field vector is from $ q_3 $ to A, which is downward. So $ E_{3A} $ is downward, magnitude equal to $ E_{y,total}=0.3 \, \text{N/C} $

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

$ |q_3|=\frac{E_{3A} \times r_{3A}^2}{k} $

$ E_{3A}=0.3 \, \text{N/C} $, $ r_{3A}=3 \, \text{m} $, $ k = 9\times10^9 $

$ |q_3|=\frac{0.3\times3^2}{9\times10^9}=\frac{0.3\times9}{9\times10^9}=\frac{0.3}{10^9}=0.3\times10^{-9} \, \text{C}=0.3 \, \text{nC} $

But wait, let's check the sign. The total field from $ q_1 $ and $ q_2 $ is upward. To make the total field at A zero, the field from $ q_3 $ must be downward. The field from a positive charge at A (below $ q_3 $) is downward (away from $ q_3 $), so $ q_3 $ must be positive? Wait, no: if $ q_3 $ is positive, field at A is downward (correct, to cancel upward field). Wait, but let's recalculate the magnitude again.

Wait, maybe I messed up the y - component of $ E_{1A} $ and $ E_{2A} $. Let's use vectors properly.

The position of $ q_1 $ is $ (16,0) $, A is $ (0,12) $. The vector $ \vec{r}_{1A} = (0 - 16, 12 - 0)=(- 16,12) $, magnitude $ r_{1A}=20 \, \text{m} $. The unit vector $ \hat{r}_{1A}=\frac{(- 16,12)}{20}=(- 0.8,0.6) $

Electric field due to $ q_1 $ at A: $ \vec{E}_{1A}=k\frac{q_1}{r_{1A}^2}\hat{r}_{1A} $, $ q_1 = 8\times10^{-9} \, \text{C} $

$ \vec{E}_{1A}=9\times10^9\times\frac{8\times10^{-9}}{20^2}(- 0.8,0.6)=9\times\frac{8}{400}(- 0.8,0.6)=0.18(- 0.8,0.6)=(- 0.144,0.108) \, \text{N/C} $

Position of $ q_2 $ is $ (- 9,0) $, A is $ (0,12) $. Vector $ \vec{r}_{2A}=(0 + 9,12 - 0)=(9,12) $, magnitude $ r_{2A}=15 \, \text{m} $.

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QUESTION IMAGE

Question

Explanation:

Step1: Find distances from \( q_1, q_2, q_3 \) to point A

Step2: Calculate electric fields from \( q_1 \) and \( q_2 \) at A

Step3: Calculate \( q_3 \) to cancel \( E_{y,total} \)

Answer:

Step1: Find distances from \( q_1, q_2, q_3 \) to point A

Step2: Calculate electric fields from \( q_1 \) and \( q_2 \) at A

Step3: Calculate \( q_3 \) to cancel \( E_{y,total} \)