Campos eléctricos: problemas e solucións

Campos eléctricos: problemas e solucións

1. Point A located at the center between two charges. Both charges have the same magnitude but opposite sign and separated by a distance of a. The magnitude of the electric field at point A is 36 N/C. If point A moved 1/2a close to one of both cargas, what is the magnitude of the campo eléctrico at point A?

Coñecido:

cobrar 1 (q1) = +Q

cobrar 2 (q2) = -Q

The distance between charge 1 and point A (r1A) = ½ a

The distance between charge 2 and point A (r2A) = ½ a

The magnitude of the electric field at point A (EA) = 36 NC-1

Quería: A magnitude do campo eléctrico

Solución:

Paso 1.

The electric field produced by a charge +Q no punto A :

Electric field – problems and solutions 1

Test charge is positive and charges 1 is positive so that the direction of the electric field points to charge 2.

The electric charge produced by a charge -Q no punto A :

Electric field – problems and solutions 2

Test charge is positive and charges 2 is negative so that the direction of the electric field points to charge 2.

A resultante do campo eléctrico no punto A:

Electric field – problems and solutions 3

Paso 2.

If point A is moved close to charge 1 then :

The distance between charge 1 and point Unha (r)1A) = ¼ de a

The distance between charge 2 and point A (r2A) = ¾ a

The electric field produced by charge +Q no punto A :

Electric field –a problems and solutions 4

Test charge is positive and charges 1 is positive so that the direction of the electric field points to charge 2.

The electric field produced by charge -Q at point A :

Electric field – problems and solutions 5

Test charge is positive and charges 2 is negative so that the direction of the electric field points to charge 2.

A resultante do campo eléctrico no punto A:

Electric field – problems and solutions 6

2. Dúas cargas qA = 1 μC e qB = 4 μC are separated by a distance of 4 cm (k = 9 x 109 N m2 C-2). What is the magnitude of the electric field at the center between qA and qB.

Coñecido:

Carga A (qA) = 1 μC = 1 x 10-6 C

Carga B (qB) = 4 μC = 4 x 10-6 C

k = 9 x 109 N m2 C-2

Distancia entre as cargas A e B (rAB) = 4 cm = 0.04 metros

Distance between charge A and the center point (rA) = 0.02 metross

Distance between charge B and the center point (rB) = 0.02 metross

Coñecido: A magnitude do campo eléctrico

Solución:

The electric field produced by charge A at the center point :

Electric field – problems and solutions 7

Test charge is positive and charges A is positive so that the direction of the electric field points to charge B.

The electric field produced by charge B at the center point :

Electric field – problems and solutions 8

Test charge is positive and charge B is positive so that the direction of the electric field points to charge A.

The resultant of the electric field at the center point :

EA e E.B have the opposite direction.

E = EB – EA = 9 x 107 - 2.25 x 107 = 6.75 x 107 NC-1

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3. According to figure below, where the point P is located so that the magnitude of the electric field at point P = 0 ? (k = 9 x 109 Nm2C-2, 1 μC = 10-6 C)

Electric field – problems and solutions 9

solución

If point P located at the left of Q1; the electric field produced by Q1 on point P points to leftward (lonxe Q1) and the electric field produced by Q2 on point P points to rightward (point to Q1). The direction of the electric field is opposite so that the electric field at point P = 0.

Coñecido:

Q1 = +9 μC = +9 x 10-6 C

Q2 = -4 μC = -4 x 10-6 C

k = 9 x 109 Nm2C-2

Distancia entre a carga 1 e a carga 2 = 3 cm

Distancia entre Q1 and point P (r1P) = unha

Distancia entre Q2 e punto P (r2P) = 3 + a

Buscase: Position of point P

Solución:

Point P located at leftward of Q1.

The electric field produced by Q1 no punto P:

Electric field – problems and solutions 10

Test charge is positive and Q1 is positive so that the direction of the electric field to leftward.

The electric field produced by Q2 no punto P :

Electric field – problems and solutions 11

Test charge is positive and Q2 is negative so that the direction of the electric field to rightward.

Resultant of the electric field at point A :

Electric field – problems and solutions 12

Use quadratic formula to find a :

Electric field – problems and solutions 12

Distancia entre Q2 e punto P (r2P) = 3 + a = 3 – 1.8 = 1.2 cm or 3 + a = 3 – 9 = -6 cm.

Distancia entre Q1 e punto P (r1P) = a = -9 cm or -1.8 cm.

Point P located at 1.2 cm rightward of Q2.

4. Charge q3 located at 5 cm rightward of q2, as shown in the figure below. What is the magnitude of the electric field at charge q3 (1 µC = 10-6 C).

Electric field – problems and solutions 14

Solución:

Electric field – problems and solutions 15

Charge q3 is positive so that the direction of the electric field at charge q3 points to the minus charge q2 (E2) and away from the plus charge q1 (E1). The resultant of the electric field is the sum of the electric field E1 e E.2.

Coñecido:

Charge q1 = 5 µC = 5 x 10-6 Coulomb

Charge q2 = 5 µC = -5 x 10-6 Coulomb

Distance between charge q1 and charge q3 (r1) = 15 cm = 0.15 m = 15 x 10-2 metros

Distance between charge q2 and charge q3 (r2) = 5 cm = 0.05 m = 5 x 10-2 metros

k = 9 x 109 N m2 C-2

Buscase: The electric field at charge q3

Solución:

The electric field 1 :

E1 = kq1 /r12

E1 = (9 x 109)(5 x 10-6) / (15 x 10-2)2

E1 = (45 x 103) / (225 x 10-4)

E1 = 0.2 x 107 N / C

The electric field 2 :

E2 = kq2 /r22

E2 = (9 x 109)(5 x 10-6) / (5 x 10-2)2

E2 = (45 x 103) / (25 x 10-4)

E2 = 1.8 x 107 N / C

Resultant of the electric field :

The resultant of the electric field at charge q3 :

E = E2 – E1 = (1.8 x 107) – (0.2 x 107) = 1.6 x 107 N / C

The direction of the electric field points to leftward (same direction as E2).

5. Two charges are separated as shown in figure below. What is the electric field at point P (k = 9 x 109 N m2 C-2)

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solución

Electric field – problems and solutions 16

Coñecido:

Charge qA = +2.5 °C

Charge qB = -2 °C

Distance between charge qA e o punto P (rA) = 5 m

Distance between charge qB e o punto P (rB) = 2 m

k = 9 x 109 N m2 C-2

Buscase: the magnitude of the electric field at point P.

Solución:

The electric field A :

EA = kqA /rA2

EA = (9 x 109)(2.5) / (5)2

EA = (22.5 x 109) / 25

EA = 0.9 x 109 N / C

The electric field B :

EB = kqB /rB2

EB = (9 x 109)(2) / (2)2

EB = (18 x 109) / 4

EB = 4.5 x 109 N / C

Resultant of the electric field :

Resultant of the electric field at point P :

E = EB – EA = (4.5 – 0.9) x 109 = 3.6 x 109 N / C

The direction to leftward (same direction as EB).

6. Two charges Q1 = -40 µC and Q2 = +5 µC as shown in figure below (k = 9 x 109 Nm2.C-2 and 1 µC = 10-6 C),. What is the magnitude of the electric field at point P.

Electric field – problems and solutions 17

Coñecido:

Charge q1 = -40 µC = -40 x 10-6 C

Charge q2 = +5 µC = +5 x 10-6 C

Distancia entre q1 e o punto P (r1) = 40 cm = 0.4 m = 4 x 10-1 m

Distancia entre q2 e o punto P (r2) = 10 cm = 0.1 = 1 x 10-1 m

k = 9 x 109 N m2 C-2

Buscase: the magnitude of the electric field at point P.

Solución:

The electric field 1 :

E1 = kq1 /r12

E1 = (9 x 109)(40 x 10-6) / (4 x 10-1)2

E1 = (360 x 103) / (16 x 10-2)

E1 = 22.5 x 105 N / C

The electric field 2 :

E2 = kq2 /r22

E2 = (9 x 109)(5 x 10-6) / (1 x 10-1)2

E2 = (45 x 103) / 1 x 10-2

E2 = 45 x 105 N / C

Resultant of the electric field :

The resultant of the electric field at point P :

E = E2 – E1 = (45 – 22.5) x 105 = 22.5 x 105 N / C

E = 2.25 x 106 N / C

The direction of the electric field points to rightward (same direction as E2).

7. Two point charges as shown in figure below.

Electric field – problems and solutions 18

Where is point P located so that the magnitude of the electric field at point P = 0. k = 9.109 Nm2.C-2, 1 µC = 10-6 C.

Coñecido:

Carga 1 (q1) = -9 µC = -9.10-6 Coulomb

Carga 2 (q2) = 1 µC = 1.10-6 Coulomb

Distancia entre q1 and q2 (r12) = 1 centímetros

k = 9.109 Nm2.C-2

Buscase: Position of point P

Solución:

E1 = the magnitude of the electric field produced by q1 at point P

The direction of E1 a q1 porque q1 é negativo.

E2 = the magnitude of the electric field produced by q2 at point P

The direction of E2 lonxe q2 porque q2 é positivo.

Electric field – problems and solutions 19

Electric field – problems and solutions 20

The electric field at point = 0.

Usa a fórmula cuadrática:

Electric field – problems and solutions 22

Distance between P and q2 = x = 0.5 cm.

Point P located at 0.5 cm rightward q2 or 0.25 cm leftward q1.

8. According to the figure below, if the magnitude of the electric field at point P = k Q/x2, then x = ….

Electric field – problems and solutions 23

Coñecido:

EP = k Q / x2

Buscase: x

Solución:

Electric field – problems and solutions 24

E2 = The magnitude of the electric field at point P by charge +32Q

r2 =Distance between charge +32Q and point P = a + x

Electric field – problems and solutions 25

Usa a fórmula cuadrática:

Electric field – problems and solutions 26

  1. What is an electric field?
    • Responder: An electric field is a region around a charged object where electric forces can be experienced by other charged objects. It is a vector field, meaning it has both magnitude and direction at every point.
  2. How is the strength of an electric field determined?
    • Responder: The strength or magnitude of an electric field at a point is defined as the force experienced by a positive test charge placed at that point, divided by the magnitude of the test charge itself: .
  3. How does the electric field due to a point charge vary with distance?
    • Responder: The electric field due to a point charge is inversely proportional to the square of the distance from the charge. The relationship is given by , Onde is Coulomb’s constant.
  4. What is the direction of the electric field due to a positive charge?
    • Responder: The electric field due to a positive charge points radially outward from the charge. For a negative charge, the field points radially inward, towards the charge.
  5. How can you represent electric fields graphically?
    • Responder: Electric fields can be represented graphically using field lines (or lines of force). The direction of the field at any point is tangent to the field line at that point, and the density of the lines indicates the magnitude of the field.
  6. What happens to the electric field inside a conductor in electrostatic equilibrium?
    • Responder: Inside a conductor in electrostatic equilibrium, the electric field is zero. This is because any external field causes free electrons in the conductor to redistribute, cancelling the external field inside.
  7. How do electric field lines behave near a sharp edge of a conductor?
    • Responder: Near a sharp edge or pointed tip of a conductor, the electric field lines are more concentrated, leading to a stronger electric field in that region. This is the basis for the operation of devices like the lightning rod.
  8. How do superposition principles apply to electric fields?
    • Responder: The electric field due to multiple charges at a point is simply the vector sum of the electric fields due to each individual charge. This is known as the superposition principle.
  9. How is the work done by an external agent related to the electric field when moving a charge within the field?
    • Responder: The work done by an external agent in moving a charge from one point to another in an electric field is equal to the negative of the change in electric potential energy, which is , Onde is the change in electric potential.
  10. Can electric field lines ever cross each other?

    • Responder: No, electric field lines cannot cross each other. If they did, it would imply that at the point of intersection, there are two different directions of the electric field, which is not possible.