1. Physics 6B Electric Field Examples
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2. Electric charge can be either positive or negative.
Matter is chiefly comprised of electrons (negative), protons (positive) and neutrons (electrically neutral). A neutral object will have equal numbers of protons and electrons.
Most of the time it is the negatively-charged electrons that can move back and forth between objects, so a negatively charged object has excess electrons, and a positively charged object has too few electrons.
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3. Electric charge can be either positive or negative.
Matter is chiefly comprised of electrons (negative), protons (positive) and neutrons (electrically neutral). A neutral object will have equal numbers of protons and electrons.
Most of the time it is the negatively-charged electrons that can move back and forth between objects, so a negatively charged object has excess electrons, and a positively charged object has too few electrons.
Elementary charge: Charge is quantized, which means that the charge on any object is always a multiple the charge on a proton (or electron).
e = 1.6 x C This is the smallest possible charge.
Units for charge are Coulombs. The Coulomb is a very large unit, so you can expect to see tiny values like nano-Coulombs.
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4. Charges interact with each other via the Electric Force.
Rules for interaction are based on the sign of the charge as follows:
* Like charges repel
* Opposite charges attract
The force is given by Coulomb’s Law:
Coulomb’s Constant
Notice that this is just the magnitude of the force, and the r is the center-to-center distance between the two charges.
My advice is to not put +- signs into this formula. Instead, find the direction of the force based on the attract/repel rules above.
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5. Electric Fields
This is just another (very important) way of looking at electric forces. We find the electric field near a charge distribution, then we can simply multiply by any charge to find the force on that charge.
E-field near a point-charge Q is just most of the force formula
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6. Electric Field Lines
The charge on the right is twice the magnitude of the charge on the left (and opposite in sign), so there are twice as many field lines, and they point towards the charge rather than away from it.

7. Electric Field of a Dipole+q -q
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8. Electric Field of a Dipole
Notice that the field lines point away from positive and toward negative charges. This will always be true.
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9. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin.
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10. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin. q2 q1 x
x=-0.3m
x=0
x=0.2m
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11. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin.
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one. q2 q1 x
x=-0.3m
x=0
x=0.2m
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12. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin.
The electric field near a single point charge is given by the formula: E1 E2
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
At the origin, q1 will produce an E-field vector that points left, and q2 gives an E-field vector to the right. q2 q1 x
x=-0.3m
x=0
x=0.2m
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13. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin.
The electric field near a single point charge is given by the formula: E1 E2
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
At the origin, q1 will produce an E-field vector that points left, and q2 gives an E-field vector to the right.
This is how we can put the +/- signs on the E-fields when we add them up. q2 q1 x
x=-0.3m
x=0
x=0.2m
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14. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin.
The electric field near a single point charge is given by the formula: E1 E2
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
At the origin, q1 will produce an E-field vector that points left, and q2 gives an E-field vector to the right.
This is how we can put the +/- signs on the E-fields when we add them up. q2 q1 x
x=-0.3m
x=0
x=0.2m
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15. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin.
The electric field near a single point charge is given by the formula:
Etotal
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
At the origin, q1 will produce an E-field vector that points left, and q2 gives an E-field vector to the right.
This is how we can put the +/- signs on the E-fields when we add them up. q2 q1 x
x=-0.3m
x=0
x=0.2m
(This means 400 N/C in the negative x-direction)
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16. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin.
The electric field near a single point charge is given by the formula:
Etotal
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
At the origin, q1 will produce an E-field vector that points left, and q2 gives an E-field vector to the right.
This is how we can put the +/- signs on the E-fields when we add them up. q2 q3 q1 x
x=-0.3m
x=0
x=0.2m
(This means 400 N/C in the negative x-direction)
For part b) all we need to do is multiply the E-field from part a) times the new charge q3.
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17. Two point charges are located on the x-axis as follows: charge q1 = +4 nC at position x=0.2m and charge q2 = +5 nC at position x = -0.3m.
a) Find the magnitude and direction of the net electric field produced by q1 and q2 at the origin.
b) Find the net electric force on a charge q3=-0.6nC placed at the origin.
The electric field near a single point charge is given by the formula:
Etotal
Fon3
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
At the origin, q1 will produce an E-field vector that points left, and q2 gives an E-field vector to the right.
This is how we can put the +/- signs on the E-fields when we add them up. q2 q3 q1 x
x=-0.3m
x=0
x=0.2m
(This means 400 N/C in the negative x-direction)
For part b) all we need to do is multiply the E-field from part a) times the new charge q3.
Note that this force is to the right, which is opposite the E-field
This is because q3 is a negative charge: E-fields are always set up as if there are positive charges.
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18. Two unequal charges repel each other with a force F
Two unequal charges repel each other with a force F. If both charges are doubled in magnitude, what will be the new force in terms of F?
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19. The formula for electric force between 2 charges is
Two unequal charges repel each other with a force F. If both charges are doubled in magnitude, what will be the new force in terms of F?
The formula for electric force between 2 charges is
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20. The formula for electric force between 2 charges is
Two unequal charges repel each other with a force F. If both charges are doubled in magnitude, what will be the new force in terms of F?
The formula for electric force between 2 charges is
If both charges are doubled, we will have
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21. The formula for electric force between 2 charges is
Two unequal charges repel each other with a force F. If both charges are doubled in magnitude, what will be the new force in terms of F?
The formula for electric force between 2 charges is
If both charges are doubled, we will have
So the new force is 4 times as large.
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22. Two unequal charges attract each other with a force F when they are a distance D apart. How far apart (in terms of D) must they be for the force to be 3 times as strong as F?
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23. Formula for electric force between 2 charges is
Two unequal charges attract each other with a force F when they are a distance D apart. How far apart (in terms of D) must they be for the force to be 3 times as strong as F?
Formula for electric force between 2 charges is
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24. Formula for electric force between 2 charges is
Two unequal charges attract each other with a force F when they are a distance D apart. How far apart (in terms of D) must they be for the force to be 3 times as strong as F?
Formula for electric force between 2 charges is
We want the force to be 3 times as strong, so we can set up the force equation and solve for the new distance.
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25. Formula for electric force between 2 charges is
Two unequal charges attract each other with a force F when they are a distance D apart. How far apart (in terms of D) must they be for the force to be 3 times as strong as F?
Formula for electric force between 2 charges is
We want the force to be 3 times as strong, so we can set up the force equation and solve for the new distance.
Canceling and cross-multiplying, we get
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26. Formula for electric force between 2 charges is
Two unequal charges attract each other with a force F when they are a distance D apart. How far apart (in terms of D) must they be for the force to be 3 times as strong as F?
Formula for electric force between 2 charges is
We want the force to be 3 times as strong, so we can set up the force equation and solve for the new distance.
Canceling and cross-multiplying, we get
Square-roots of both sides gives us the answer:
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27. When two unequal point charges are released a distance d from one another, the heavier one has an acceleration a. If you want to reduce this acceleration to 1/5 of this value, how far (in terms of d) should the charges be released?
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28. Recall that Newton's 2nd law says that Fnet = ma.
When two unequal point charges are released a distance d from one another, the heavier one has an acceleration a. If you want to reduce this acceleration to 1/5 of this value, how far (in terms of d) should the charges be released?
Recall that Newton's 2nd law says that Fnet = ma.
So this is really a problem about the force on the heavier charge.
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29. Recall that Newton's 2nd law says that Fnet = ma.
When two unequal point charges are released a distance d from one another, the heavier one has an acceleration a. If you want to reduce this acceleration to 1/5 of this value, how far (in terms of d) should the charges be released?
Recall that Newton's 2nd law says that Fnet = ma.
So this is really a problem about the force on the heavier charge.
formula for electric force between 2 charges is
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30. Recall that Newton's 2nd law says that Fnet = ma.
When two unequal point charges are released a distance d from one another, the heavier one has an acceleration a. If you want to reduce this acceleration to 1/5 of this value, how far (in terms of d) should the charges be released?
Recall that Newton's 2nd law says that Fnet = ma.
So this is really a problem about the force on the heavier charge.
formula for electric force between 2 charges is
If we want the acceleration to be 1/5 as fast, we need the force to be 1/5 as strong:
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31. Recall that Newton's 2nd law says that Fnet = ma.
When two unequal point charges are released a distance d from one another, the heavier one has an acceleration a. If you want to reduce this acceleration to 1/5 of this value, how far (in terms of d) should the charges be released?
Recall that Newton's 2nd law says that Fnet = ma.
So this is really a problem about the force on the heavier charge.
formula for electric force between 2 charges is
If we want the acceleration to be 1/5 as fast, we need the force to be 1/5 as strong:
We cancel common terms and cross-multiply to get
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32. Recall that Newton's 2nd law says that Fnet = ma.
When two unequal point charges are released a distance d from one another, the heavier one has an acceleration a. If you want to reduce this acceleration to 1/5 of this value, how far (in terms of d) should the charges be released?
Recall that Newton's 2nd law says that Fnet = ma.
So this is really a problem about the force on the heavier charge.
formula for electric force between 2 charges is
If we want the acceleration to be 1/5 as fast, we need the force to be 1/5 as strong:
We cancel common terms and cross-multiply to get
Square-root of both sides:
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33. A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
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34. A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
-4nC
+6nC x
x=0
x=0.8m
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35. A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
-4nC
+6nC x
x=0
x=0.8m
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36. A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
-4nC
+6nC x
x=0
x=0.8m
For part a) which direction do the E-field vectors point?
-4nC
+6nC a x
x=0
x=0.8m
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37. Call the -4nC charge #1 and the +6nC charge #2
A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
-4nC
+6nC x
x=0
x=0.8m
For part a) both E-field vectors point in the –x direction
Call the -4nC charge #1 and the +6nC charge #2 E2
Q1 = -4nC E1
Q2 = +6nC a x
x=0
x=0.8m
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38. Call the -4nC charge #1 and the +6nC charge #2
A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
-4nC
+6nC x
x=0
x=0.8m
For part a) both E-field vectors point in the –x direction
Call the -4nC charge #1 and the +6nC charge #2 E2
Q1 = -4nC E1
Q2 = +6nC a x
x=0
x=0.8m
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39. Call the -4nC charge #1 and the +6nC charge #2
A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
-4nC
+6nC x
x=0
x=0.8m
For part a) both E-field vectors point in the –x direction
Call the -4nC charge #1 and the +6nC charge #2 E2
Q1 = -4nC E1
Q2 = +6nC a x
x=0
x=0.8m E2
Q1 = -4nC
Q2 = +6nC E1
For part b) E1 points left and E2 points right b x
x=0
x=0.8m
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40. Call the -4nC charge #1 and the +6nC charge #2
A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
-4nC
+6nC x
x=0
x=0.8m
For part a) both E-field vectors point in the –x direction
Call the -4nC charge #1 and the +6nC charge #2 E2
Q1 = -4nC E1
Q2 = +6nC a x
x=0
x=0.8m E2
Q1 = -4nC
Q2 = +6nC E1
For part b) E1 points left and E2 points right b x
x=0
x=0.8m
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41. Call the -4nC charge #1 and the +6nC charge #2
A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
-4nC
+6nC x
x=0
x=0.8m
For part a) both E-field vectors point in the –x direction
Call the -4nC charge #1 and the +6nC charge #2 E2
Q1 = -4nC E1
Q2 = +6nC a x
x=0
x=0.8m E2
Q1 = -4nC
Q2 = +6nC E1
For part b) E1 points left and E2 points right b x
x=0
x=0.8m E2 E1
Q1 = -4nC
Q2 = +6nC c x
For part b) E1 points right and E2 points left
x=0
x=0.8m
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42. Call the -4nC charge #1 and the +6nC charge #2
A point charge of -4 nC is at the origin, and a second point charge of +6 nC is placed on the x-axis at x=0.8m. Find the magnitude and direction of the electric field at the following points on the x-axis: a) x=20 cm; b) x=1.20m; c) x= -20cm
The electric field near a single point charge is given by the formula:
This is only the magnitude. The direction is away from a positive charge, and toward a negative one.
-4nC
+6nC x
x=0
x=0.8m
For part a) both E-field vectors point in the –x direction
Call the -4nC charge #1 and the +6nC charge #2 E2
Q1 = -4nC E1
Q2 = +6nC a x
x=0
x=0.8m E2
Q1 = -4nC
Q2 = +6nC E1
For part b) E1 points left and E2 points right b x
x=0
x=0.8m E2 E1
Q1 = -4nC
Q2 = +6nC c x
For part b) E1 points right and E2 points left
x=0
x=0.8m
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43. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
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44. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m) x y
Part a): TRY DRAWING THE E-FIELD VECTORS ON THE DIAGRAM 2 1
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45. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m) x y E1 E2
Part a): both vectors point away from their charge.
Since the distances and the charges are equal, the vectors cancel out.
Etotal = 0 2 1
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46. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m) x y E1 E2
Part a): both vectors point away from their charge.
Since the distances and the charges are equal, the vectors cancel out.
Etotal = 0 2 1 x y
Part b): both vectors point away from their charge. E1 2 1 E2
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47. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m) x y E1 E2
Part a): both vectors point away from their charge.
Since the distances and the charges are equal, the vectors cancel out.
Etotal = 0 2 1 x y
Part b): both vectors point away from their charge.
Positive x-direction E1 2 1 E2
Positive x-direction
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48. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m) x y E1 E2
Part a): both vectors point away from their charge.
Since the distances and the charges are equal, the vectors cancel out.
Etotal = 0 2 1 x y
Part b): both vectors point away from their charge.
Positive x-direction E1 2 1 E2
Positive x-direction
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49. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
(0.15,- 0.4)
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For Campus Learning Assistance Services at UCSB

50. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
(0.15,- 0.4)
E1,y
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

51. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
(0.15,- 0.4)
E1,y
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

52. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
(0.15,- 0.4) E2
E1,y
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

53. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
The 0.5m in this formula for E2 is the distance to charge 2, using Pythagorean theorem or from recognizing a right triangle when you see it.
0.4m
(0.15,- 0.4)
0.3m E2
E1,y
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

54. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
The 0.5m in this formula for E2 is the distance to charge 2, using Pythagorean theorem or from recognizing a right triangle when you see it.
0.4m
(0.15,- 0.4)
E2,x
0.3m
E2,y
E1,y
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

55. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
The 0.5m in this formula for E2 is the distance to charge 2, using Pythagorean theorem or from recognizing a right triangle when you see it.
0.4m
(0.15,- 0.4)
E2,x
0.3m
E2,y
E1,y
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

56. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
The 0.5m in this formula for E2 is the distance to charge 2, using Pythagorean theorem or from recognizing a right triangle when you see it.
0.4m
(0.15,- 0.4)
E2,x
0.3m
E2,y
Add together the x-components and the y-components separately:
E1,y
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

57. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part c): both vectors point away from their charge. We will need to use vector components to add them together. x y
(- 0.15,0)
(0.15,0) 2 1
The 0.5m in this formula for E2 is the distance to charge 2, using Pythagorean theorem or from recognizing a right triangle when you see it.
(0.15,- 0.4)
75.7º
Add together the x-components and the y-components separately:
Etotal
Now find the magnitude and the angle using right triangle rules:
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

58. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part d): TRY THIS ONE ON YOUR OWN FIRST... x y
(0,0.2)
(- 0.15,0)
(0.15,0) 2 1
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

59. Find the magnitude and direction of the net electric field at:
A point charge of q=+6 nC is at the point (x=0.15m,y=0m), and an identical point charge is placed at (-0.15m,0m), as shown.
Find the magnitude and direction of the net electric field at:
a) the origin (0,0); b) (0.3m,0m); c) (0.15m,-0.4m); d) (0m,0.2m)
Part d): both vectors point away from their charge. We will need to use vector components to add them together. x y E1 E2
The 0.25m in this formula is the distance to each charge using the Pythagorean theorem or from recognizing a right triangle when you see it.
(0,0.2)
(- 0.15,0)
(0.15,0) 2 1
From symmetry, we can see that E2 will have the same components, except for +/- signs.
Now we can add the components (the x-component should cancel out)
The final answer should be N/C in the positive y-direction.
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB

60. Electric Flux
Field lines passing through a surface are called “flux”. To find the flux through a surface, multiply field strength times the area of the surface. Here is the formula:
Notice that if the field is not perpendicular to the area we need to multiply by cos(Φ).
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For Campus Learning Assistance Services at UCSB

61. Electric Flux Try this example:
A uniform electric field points in the +x direction and has magnitude 2000 N/C.
Find the electric flux through a circular window of radius 10cm, tilted at an angle of 30° to the x-axis, as shown below.
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For Campus Learning Assistance Services at UCSB

62. Electric Flux Try this example:
A uniform electric field points in the +x direction and has magnitude 2000 N/C.
Find the electric flux through a circular window of radius 10cm, tilted at an angle of 30° to the x-axis, as shown below.
We can apply our formula directly here:
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For Campus Learning Assistance Services at UCSB

63. Electric Flux Try this example:
A positive 3µC charge is surrounded by a spherical surface of radius 0.2m, as shown. Find the net electric flux through the sphere.
Notice that the electric field lines intercept the sphere at right angles, so the angle in our flux formula is 0°.
We can put in formulas for the electric field near a point charge, and the surface area for a sphere to arrive at a nice formula.
It turns out that the flux only depends on the enclosed charge, and furthermore, if we write it in terms of permittivity ε0, we find the following:
This is called Gauss’ Law, and it works out that we don’t even need a sphere – any closed surface will do.
Prepared by Vince Zaccone
For Campus Learning Assistance Services at UCSB