Solucionario Capitulo 24 - Paul E. Tippens

Chapter 24. The Electric Field

The Electric Field Intensity

24-1. A charge of +2 µC placed at a point P in an electric field experiences a downward force of 8 x 10-4 _{N. What is the electric field intensity at that point?}

-4 -6 8 x 10 N 2 x 10 C F E q = = ; E = 400 N/C, downward

24-2. A –5 nC charge is placed at point P in Problem 24-1. What are the magnitude and direction of the force on the –5 nC charge? (Direction of force F is opposite field E)

F = qE = (-5 x10-9 _{C)(-400 N/C); F = 2.00 x 10}-6 _{N, upward}

24-3. A charge of –3 µC placed at point A experiences a downward force of 6 x 10-5 _{N. What is the} electric field intensity at point A?

A negative charge will experience a force opposite to the field. Thus, if the –3 µC charge has a downward force, the E is upward.

-5 -6 6 x 10 N -3 x 10 C F E q − = = ; E = 20 N/C, upward

24-4. At a certain point, the electric field intensity is 40 N/C, due east. An unknown charge, receives a westward force of 5 x 10-5 _{N. What is the nature and magnitude of the charge?}

If the force on the charge is opposite the field E, it must be a negative charge.

-5 5 x 10 N ; ; 40 N/C F F E q q E − = = = q = -1.25 µC E F

24-5. What are the magnitude and direction of the force that would act on an electron (q = -1.6 x 10-19 _{C) if it were placed at (a) point P in Problem 24-1? (b) point A in Problem 24-3?}

The electric force on an electron will always be opposite the electric field.

(a) F = qE = (-1.6 x 10-19 _{C)(-400 N/C); F = 6.40 x 10}-17 _{N, upward} (b) F = qE = (-1.6 x 10-19 _{C)(+20 N/C); F = -3.20 x 10}-18 _{N, downward}

24-6. What must be the magnitude and direction of the electric field intensity between two

horizontal plates if one wants to produce an upward force of 6 x 10-4 _{N on a +60-µC charge?} (The upward force on +q means E is also upward.)

-4 -6 6 x 10 N 60 x 10 C F E q = = ; E = 10.0 N/C, up

24-7. The uniform electric field between two horizontal plates is 8 x 104 _{C. The top plate is} positively charged and the lower plate has an equal negative charge. What are the magnitude and direction of the electric force acting on an electron as it passes horizontally through the plates? (The electric field is from + to -, i.e., downward; force on e is up.)

F = qE = (-1.6 x 10-19 _{C)(8 x 10}4 _{N/C); F = 1.28 x 10}-14 _{N, upward}

24-8. Find the electric field intensity at a point P, located 6 mm to the left of an 8-µC charge. What are the magnitude and direction of the force on a –2-nC charge placed at point P?

9 2 2 6 2 -3 2 (9 x 10 N m /C )(8 x 10 C) (6 x 10 mm) kQ E r − ⋅ = = ; E = 2.00 x 109 _{N/C, toward Q} F = qE = (-2 x 10-9 _{C)(2.00 x 10}9 _N/C) F = -4.00 N, away from Q +q F E -2 nC 8 µC F E 6 mm P E P

24-9. Determine the electric field intensity at a point P, located 4 cm above a –12-µC charge. What are the magnitude and direction of the force on a +3-nC charge placed at point P?

Electric field will be downward, since that is the direction a positive charge would move.

9 2 2 6 2 2 (9 x 10 N m /C )( 12 x 10 C) (0.04 m) kQ E r − ⋅ − = = ; E = -6.75 x 107 _{N/C, downward} F = qE = (3 x 10-9 _{C)(-6.75 x 10}7 _{N/C) ; F = -0.202 N, downward}

Calculating the Resultant Electric Field Intensity

24-10. Determine the electric filed intensity at the midpoint of a 70 mm line joining a –60-µC charge with a +40-µC charge.

9 2 2 6 1 1 2 2 (9 x 10 N m /C )( 60 x 10 C) (0.035 m) kq E r − ⋅ − = = 9 2 2 6 2 2 2 2 (9 x 10 N m /C )(40 x 10 C) (0.035 m) kq E r − ⋅ = = ; ER = E1 + E2 (Both to left) ER = -4.41 x 108 N/C – 2.94 x 108 N/C ; ER = 7.35 x 108 N/C. toward –60 µC

24-11. An 8-nC charge is located 80 mm to the right of a +4-nC charge. Determine the field intensity at the midpoint of a line joining the two charges.

9 2 2 9 1 1 2 2 (9 x 10 N m /C )(4 x 10 C) (0.040 m) kq E r − ⋅ = = 9 2 2 9 2 2 2 2 (9 x 10 N m /C )(8 x 10 C) (0.040 m) kq E r − ⋅ = = ; ER = E1 + E2 (E1 right, E2 left) ER = -4.50 x 104 N/C + 2.25 x 104 N/C ; ER = -2.25 x 104 N/C, left

Note: The directions of the E field are based on how a test + charge would move.

q₁ q₂ E₂ E₁ +40 µC -60 µC 35 mm 35 mm q 1 q2 E_{2 E} 1 +8 nC 4 nC 40 mm 40 mm

24-12. Find the electric field intensity at a point 30 mm to the right of a 16-nC charge and 40 mm to the left of a 9-nC charge.

9 2 2 9 1 1 2 2 (9 x 10 N m /C )(16 x 10 C) (0.030 m) kq E r − ⋅ = = 9 2 2 9 2 2 2 2 (9 x 10 N m /C )(9 x 10 C) (0.040 m) kq E r − ⋅ = = ; ER = E1 + E2 (E1 right, E2 left) ER = 16.0 x 104 N/C - 5.06 x 104 N/C ; ER = 1.09 x 105 N/C, right

24-13. Two equal charges of opposite signs are separated by a horizontal distance of 60 mm. If the resultant electric field at the midpoint of the line is 4 x 104 _{N/C. What is the magnitude} of each charge?

Equal and opposite charges make field at center

equal to vector sum with both to left or both to right.. ER = E1 + E2 = E1 + E2

9 2 2 4 4 2 2 2 2(9 x 10 N m /C ) 4 x 10 N/C; 4 x 10 N/C (0.030 m) kq q E r ⋅ = = =

q = 2.00 nC (One positive and the other negative.)

*24-14. A 20-µC charge is 4 cm above an unknown charge q. The resultant electric intensity at a point 1 cm above the 20-µC charge is 2.20 x 109 _{N/C and is directed upward? What are the} magnitude and sign of the unknown charge?

E1 + E2 = 2.20 x 109 _{N/C; First we find E1 and E} 2 9 2 2 6 1 1 2 2 (9 x 10 N m /C )(20 x 10 C) (0.010 m) kq E r − ⋅ = = ; E1 = 1.80 x 109 _N E2 = ER – E1 = 2.20 x 109 _{N/C – 1.80 x 10}9 _{N/C; E2 = 4 x 10}8 _{N/C, up} 2 8 2 2 2 2 2 2 9 2 2 (4 x 10 N/C)(0.05 m) ; (9 x 10 N m /C ) kq E r E q r k = = = ⋅ ; q = q2 = 111 µC q 1 q2 E_{2 E} 1 +9 nC +16 nC 30 mm 40 mm q 1 q2 E₂ E₁ -q +q 30 mm 30 mm q₂ q 1 4 cm 20 µC 1 cm E_R

*24-15. A charge of –20 µC is placed 50 mm to the right of a 49µC charge. What is the resultant field intensity at a point located 24 mm directly above the –20-µC charge?

_{R= (50 mm)}2_{+(24 mm)}2 _{=55.5 mm} tan 24 mm 50 mm θ = ; θ = 25.60 9 2 2 6 1 1 2 2 (9 x 10 N m /C )(49 x 10 C) (0.0555 m) kq E r − ⋅ = = ; E1 = 1.432 x 108 _{N/C at 25.6}0 _{N of E} 9 2 2 6 1 2 2 2 (9 x 10 N m /C )(20 x 10 C) (0.024 m) kq E r − ⋅ = = ; E2 = 3.125 x 108 _{N/C, downward} Ex = (1.432 x 108 N/C) cos 25.60 + 0; Ex = 1.291 x 108 N/C Ey = (1.432 x 108 _{N/C) sin 25.6}0 _{– 3.125 x 10}8 _{N/C; Ey = -2.506 x 10}8 _N/C 8 2 8 2 (1.29 x 10 ) (-2.51 x 10 ) R E = + ; ER = 2.82 x 108 _N/C 8 8 2.51 x 10 N/C tan 1.29 x 10 N/C θ −= ; θ = 62.70 _{S of E; ER = 2.82 x 10}8 _{N/C, 297.3}0_.

*24-16. Two charges of +12 nC and +18 nC are separated horizontally by 28 mm. What is the

resultant field intensity at a point 20 mm from each charge and above a line joining the two charges? cos 14 mm; 45.60 20 mm θ = θ = 9 2 2 9 1 1 2 2 (9 x 10 N m /C )(12 x 10 C) (0.020 m) kq E r − ⋅ = = E1 = 2.70 x 105 _{N/C, 45.6}0 _{N of E} 9 2 2 9 1 2 2 2 (9 x 10 N m /C )(18 x 10 C) (0.020 m) kq E r − ⋅ = = ; E2 = 4.05 x 105 _{N/C, 45.6}0 _{N of W} -20 µC 49 µC q₂ q₁ 24 mm 50 mm R θ E₁ E₂ θ θ 20 mm θ E₂ q₁ q2 E 1 +18 nC +12 nC 14 mm 14 mm θθ

*24-16. (Cont.) Ex = (2.70 x 105 _{N/C) cos 45.6}0 _{– (4.05 x 10}5 _{N/C) cos 45.6}0 _{= -9.45 x 10}4 _N/C Ey = (2.70 x 105 _{N/C) sin 45.6}0 _{– (4.05 x 10}5 _{N/C) sin 45.6}0 _{= +4.82 x 10}5 _N/C 4 2 5 2 ( 9.45 x 10 ) (4.82 x 10 ) R E = − + ; ER = 4.91 x 105 _N/C 5 4 4.82 x 10 N/C tan -9.45 x 10 N/C θ = ; θ = 78.90 _{N of W; ER = 4.91 x 10}5 _{N/C, 101.1}0

*24-17. A +4 nC charge is placed at x = 0 and a +6 nC charge is placed at x = 4 cm on an x-axis.

Find the point where the resultant electric field intensity will be zero?

1 = ; 2 21 _{(4 cm - x)}2 2 kq kq E E x = 2 2 2 2 1 1 (4 x) q x or 4 x = q x q q − = − 4 cm - x = 6 nC ; 4 cm - x = 1.225 ; 4 nCx x x = 1.80 cm

Applications of Gauss’s Law

24-18. Use Gauss’s law to show that the field outside a solid charged sphere at a distance r from its center is given by 2 0 4 Q E R πε =

where Q is the total charge on the sphere.

Construct a spherical gaussian surface around the charged sphere at the distance r from its center. Then, we have

Σε0AE= Σq ; ε0E(4πR2)=Q 2 0 4 Q E R πε = 4 cm - x q₁ q 2 E₂ = E₁ +6 nC +4 nC x = 0 _{x = 4 cm} x Gaussian surface R

24-19. A charge of +5 nC is placed on the surface of a hollow metal sphere whose radius is 3 cm. Use Gauss’s law to find the electric field intensity at a distance of 1 cm from the surface of the sphere? What is the electric field at a point 1 cm inside the surface?

Draw gaussian surface of radius R = 3 cm + 1 cm = 4 cm. This surface encloses a net positive charge of +5 nC and has a surface area of 4πR2_{, so Gauss’ law gives us:}

(a) 0 0 2 2 0 ; (4 ) ; 4 q AE q R E q E R ε ε π πε Σ = Σ = = -9 -12 2 2 2 5 x 10 C 4 (8.85 x 10 C /N m )(0.04 m) E π = ⋅ ; E = 2.81 x 104 N/C, radially outward.

(b) Draw a gaussian surface just inside the sphere. Now, all charge resides on the

surface of the sphere, so that zero net charge is enclosed, and ΣεoAE = Σq = 0. E = 0, inside sphere

24-20. Two parallel plates, each 2 cm wide and 4 cm long, are stacked vertically so that the field intensity between the two plates is 10,000 N/C directed upward. What is the charge on each plate? First use Gauss’ law to find E between plates.

Draw gaussian cylinder of area Aenclosing charge q.

0 0 0 ; ; q AE q AE q E A ε ε ε Σ = Σ = =

The charge density q/A enclosed is same as Q/Ap for plate. First find q/A from E :

-12 2 2 0 (8.85 x 10 C /N m )(10,000 N/C) q E A=ε = ⋅ ; -8 2 8.85 x 10 C/m q A= -8 2 8.85 x 10 C/m (0.02 m)(0.04 m) q Q A= = ; Q = 7.09 x 10-11 C 3 cm Gaussian surface R +5 nC E

24-21. A sphere 8 cm in diameter has a charge of 4 µC placed on its surface. What is the electric field intensity at the surface, 2 cm outside the surface, and 2 cm inside the surface? (a) Draw gaussian surface just outside so that R = 4 cm

and encloses the net charge of +4 uC. Then, -6 2 -12 2 2 2 0 4 x 10 C E = 4 4 (8.85 x 10 C /N m )(0.04 m) net q R πε = π ⋅ E = 2.25 x 107 _{N/C, radially outward}

(b) Draw gaussian surface of radius R = 4 cm + 2 cm = 6 cm. This surface encloses a net

positive charge of +4 nC and Gauss law gives: -6 -12 2 2 2 4 x 10 C 4 (8.85 x 10 C /N m )(0.06 m) E π = ⋅ ; E = 9.99 x 106 N/C, radially outward.

(b) Since no net charge is inside the surface, ΣεoAE = Σq = 0. E = 0, inside sphere

Challenge Problems

24-22. How far from a point charge of 90 nC will the field intensity be 500 N/C?

₂ ; (9 x 10 N m /C )(90 x 10 C)9 2 2 -9 500 N/C kQ kQ E r r E ⋅ = = = ; r = 1.27 m

24-23. The electric field intensity at a point in space is found to be 5 x 105 _{N/C, directed due west.} What are the magnitude and direction of the force on a –4-µC charge placed at that point?

Consider East positive: F = qE = (-4 µC)(-5 x 105 _{N/C); F = 2.00 N, East} 4 cm

Gaussian surface

R

24-24. What are the magnitude and direction of the force on an alpha particle (q = +3.2 x 10-19 _C) as it passes into an upward electric field of intensity 8 x 104 _{N/C? (Choose up as + )}

F = qE = (3.2 x 10-19 _{C)(+8 x 10}4_{); F = 2.56 x 10}-14 _N

24-25. What is the acceleration of an electron (e = -1.6 x 10-19 _{C) placed in a constant downward} electric field of 4 x 105 _{N/C? What is the gravitational force on this charge if me} = 9.11 x 10-31 _{kg. (Choose up as +, then E = -4 x 10}5 _N/C.)

F = qE = (-1.6 x 10-19 _{C)(-4 x 10}5 _{N/C); F = 6.40 x 10}-14 _{N, upward}

W = mg = (9.11 x 10-31 _{kg)(9.8 m/s}2_{); W = 8.93 x 10}-30 _{N, downward}

The weight of an electron is often negligible in comparison with electric forces!

24-26. What is the electric field intensity at the midpoint of a 40 mm line between a 6-nC charge and a –9-nC charge? What force will act on a –2-nC charge placed at the midpoint?

9 2 2 9 1 1 2 2 (9 x 10 N m /C )(6 x 10 C) (0.020 m) kq E r − ⋅ = = 9 2 2 9 2 2 2 2 (9 x 10 N m /C )(9 x 10 C) (0.020 m) kq E r − ⋅

= = ; ER = E1 + E2 (both to the right)

ER = 1.35 x 105 N/C + 2.025 x 105 N/C ; ER = 3.38 x 105 N/C, right

*24-27. The charge density on each of two parallel plates is 4 µC/m2_{. What is the electric field} intensity between the plates? Recall that σ = q/A, and see Prob.24-20:

0 0 0 0 ; ; q AE q AE q E A σ ε ε ε ε Σ = Σ = = = -6 2 -12 2 2 0 4 x 10 C/m (8.85 x 10 C /N m ) E σ ε = = ⋅ ; E = 4.52 x 105 N/C q 1 q2 E₂ E₁ -9 nC 6 nC 20 mm 20 mm E

*24-28. A -2 nC charge is placed at x = 0 on the x-axis. A +8 nC charge is placed at x = 4 cm. At what point will the electric field intensity be equal to zero?

The point can only be to the left of the –2 nC

1 = ; 2 21 _{( + 4 cm)}2 2 kq kq E E x = x 2 2 2 2 1 1 (4 x) q x or 4 + = x q x q q + = 4 cm + x = 8 nC ; 4 cm + x = 2 ; 2 nCx x x = 8.00 cm, left, or x = -4.00 cm

*24-29. Charges of –2 and +4 µC are placed at base corners of an equilateral triangle with 10-cm sides. What are the magnitude and direction of the electric field at the top corner?

cos 5 mm ; 600 10 mm θ = θ = 9 2 2 6 1 1 2 2 (9 x 10 N m /C )(2 x 10 C) (0.10 m) kq E r − ⋅ = = E1 = 1.80 x 106 _{N/C, 60}0 _{N of E} 9 2 2 6 1 2 2 2 (9 x 10 N m /C )(4 x 10 C) (0.10 m) kq E r − ⋅ = = ; E2 = 3.60 x 106 _{N/C, 60}0 _{N of W} Ex = - (1.80 x 106 _{N/C) cos 60}0 _{– (3.60 x 10}6 _{N/C) cos 60}0 _{= -2.70 x 10}6 _N/C Ey = - (1.80 x 106 _{N/C) sin 60}0 _{+ (3.60 x 10}6 _{N/C) sin 60}0 _{= +1.56 x 10}6 _N/C 6 2 6 2 ( 2.70 x 10 ) (1.56 x 10 ) R E = − + ; ER = 3.12 x 106 _N/C 6 6 1.56 x 10 N/C tan -2.70 x 10 N/C θ = ; θ = 30.0 0 _{N of W; ER = 3.12x 10}6 _{N/C, 150.0}0 x 4 cm q 1 q₂ E₂ = E₁ +8 nC -2 nC x = 0 _{x = 4 cm} x + 4 cm θ q₂ q₁ E 2 E₁ 4 µC -2 µC 5 cm 5 cm 10 cm θ θ

24-30. What are the magnitude and direction of the force that would act on a –2-µC charge placed at the apex of the triangle described by Problem 24-29?

First we find the magnitude: F = qE = (2 x 10-6 _{C)(3.12 x 10}6 _{N/C); F = 6.24 N}

Force is opposite field: θ = 1800 _{+ 150}0 _{= 330}0 _{F = 6.24 N, 330}0

*24-31. A 20-mg particle is placed in a uniform downward field of 2000 N/C. How many excess electrons must be placed on the particle for the electric and gravitational forces to balance? (The gravitational force must balance the electric force.)

qE = mg; (2 x 10 kg)(9.8 m/s )-5 2 2000 N/C mg q E = = q = 9.00 x 10-8 _{C; 1 e = 1.6 x 10}-19 _C -8 -19 1 9.8 x 10 C 1.6 x 10 C e e q = _ _  ; qe = 6.12 x 10 11 _electrons

*24-32. Use Gauss’s law to show that the electric field intensity at a distance R from an infinite line of charge is given by

E

R

= λ πε 2 ₀ where λ is the charge per unit length.

Gaussian surface area A = [ (2πR)L + A1 + A2 ] Σε0AE= Σq; ε0 1AE1+ε0A2E2+ε π0(2 RL E q) = net

The fields E1 and E2 are balanced through ends: ε π0(2 RL E q) = net;

0 2 q E RL πε

= _{But the linear charge density is λ = q/L, therefore:}

A A₂ A₁ L E R mg qE

0 2 E R λ πε =

*24-33. Use Gauss’s law to show that the field just outside any solid conductor is given by

E= σ

ε0

Draw a cylindrical pill box as gaussian surface.

The field lines through the sides are balanced and the field inside the surface is zero. Thus, only one surface needs to be considered, the area A of the top of the pill box.

0AE q ε =

∑

∑

*24-34. What is the electric field intensity 2 m from the surface of a sphere 20 cm in diameter having a surface charge density of +8 nC/m2_{? [ A = 4πR}2_{; r = 2 m + 0.2 m = 2.2 m ]}

q = σA = (8 x 10-9 _{C)(4π)(0.20 m)}2_{; q = 2.01 x 10}-12 _C 9 2 2 -12 2 2 (9 x 10 N m /C )(2.01 x 10 C) (2.20 m) kq E r ⋅ = = ; E = 3.74 x 10-3 _N/C

*24-35. A uniformly charged conducting sphere has a radius of 24 cm and a surface charge density of +16 µC/m2_{. What is the total number of electric field lines leaving the sphere?}

q = σA = (16 x 10-6 _{C)(4π)(0.24 m)}2_{; q = 1.16 x 10}-5 _C

N = ΣεοAE = q; N = 1.16 x 10-5 lines

*24-36. Two charges of +16 µC and +8 µC are 200 mm apart in air. At what point on a line joining the two charges will the electric field be zero? (200 mm = 20 cm)

1 = ; 2 21 _{(20 cm - x)}2 2 kq kq E E x = E 20 cm - x q₁ q₂ +8 µC +16 µC _x

2 2 2 2 1 1 (20 x) q x or 20 x = q x q q − = − *24-36 (Cont.) 20 cm - x = 8 C ; 20 cm - x = 0.707 ; 16 Cx x µ µ x = 11.7 cm

*24-37. Two charges of +8 nC and –5 nC are 40 mm apart in air. At what point on a line joining

the two charges will the electric field intensity be zero?

The point can only be to right of –5 nC charge

2 = ; 1 22 _{( + 4 cm)}1 2 kq kq E E x = x 2 1 2 1 2 2 (4 x) q x or 4 + = x q x q q + = 4 cm + x = 8 nC ; 4 cm + x = 1.265 ; 5 nCx x x = 15.1 cm outside of –5 nC charge.

Critical Thinking Questions

*24-38. Two equal but opposite charges +q and –q are placed at the base corners of an equilateral

triangle whose sides are of length a. Show that the magnitude of the electric field intensity at the apex is the same whether one of the charges is removed or not? What is the angle between the two fields so produced?

E = kq/r2_{; E}

1 = E2 since q and r are the same for each. Ey = E1 sin 600 _{– E2 sin 60 = 0, (since E1 = E2 )} Let E be magnitude of either E1 or E2, then

Ex = E sin 600 + E sin 600 = 2E cos 600 = E

Thus, for both charges in place E = E1 = E2

4 cm 4 cm + x q 1 q_{2 E} 2 = E1 -5 nC +8 nC x = 0 x a a 600 600 600 -q q E₂ E₁

The field with both charges in place is at 00_{. The field produced by –q is at –60}0 _{and the}

field produced by +q is at +600_{. In either case the angle is 60}0 _{between the fields.}

*24-39. What are the magnitude and direction of the electric field intensity at the center of the

square of Fig. 24-16. Assume that q = 1 µC and that d = 4 cm. (d/2 = 2 cm).

Rotate x and y-axes 450 _{clockwise as shown to make}

calculating resultant easier. The distances r from each charge to center is:

_{r= (2 cm)}2_{+(2 cm) ;} 2 _{r=2.83 cm;}

9 2 2 -6

1 -2 2

(9 x 10 N m /C )(1 x 10 C) (2.828 x 10 m)

E = ⋅ ; E1 = 1.125 x 107 N/C (E1 refers to E for –q)

9 2 2 -6

2 -2 2

(9 x 10 N m /C )(2 x 10 C) (2.828 x 10 m)

E = ⋅ ; E2 = 2.25 x 107 N/C, (E2 refers to E for ±2q)

Ex = -E1 – E2 = -1.125 x 107 _{N/C – 2.25 x 10}7 _{N/C; Ex = -3.38 x 10}7 _N/C Ey = E1 – E2 = 1.125 x 107 _{N/C – 2.25 x 10}7 _{N/C; Ey = -1.125 x 10}7 _N/C 7 2 7 2 ( 3.38 x 10 N/C) ( 1.125 x 10 N/C) E= − + − ; E = 3.56 x 107 _N/C 7 0 0 7 1.125 x 10 N/C tan ; 18.4 or 198.4 -3.38 x 10 N/C θ =− θ = from +x-axis

It is better to give direction with respect to horizontal, instead of with diagonal. Since we rotated axes 450 _{clockwise, the true angle is: θ = 198.4}0 _{– 45}0 _{= 153.4}0

Ans. E = 3.56 x 107 _{N, 153.4}0 2 cm x E₂ E₂ E1 E₁ +2q -2q -q -q 2 cm d _{4 cm} d y

60 cm

r1 *24-40. The electric field intensity between the plates in Fig. 24-17 is 4000 N/C. What is the

magnitude of the charge on the suspended pith ball whose mass is 3 mg? (θ = 300₎

W = mg; E = 4000 N/C; m = 3 mg = 3 x 10-6 _kg Σ Fx = 0 and ΣFy = 0 ( right = left; up = down ) T sin 600 _{= (3 x 10}-6 _{kg)(9.8 m/s}2_{); T = 3.395 x 10}-5 _N Fe = T cos 600 _{= (3.395 x 10}-5 _{N)(0.500) = 1.70 x 10}-5 _N 5 1.70 x 10 N ; 4000 N/C e e F F E q q E − = = = ; q = 4.24 x 10-9 _{C; q = 4.24 nC}

*24-41. Two concentric spheres have radii of 20 cm and 50 cm. The inner sphere has a negative charge of –4 µC and the outer sphere has a positive charge of +6 µC. Use Gauss’s law to find the electric field intensity at distances of 40 cm and 60 cm from the center of the spheres. Draw concentric gaussian spheres.

2

0AE q; (40 r E2 ) 4 C 6 C

ε ε π µ µ

Σ = Σ = − +

First find field at 60 cm from center:

-6 2 -12 2 2 2 0 2 x 10 C 4 4 (8.85 x 10 C /N m )(0.60 m) net q E r πε π + = = ⋅ ; E = 5.00 x 104 _{N/C, radially outward}

Now for field at 40 cm, only enclosed charge matters.

-6 2 -12 2 2 2 0 -4 x 10 C 4 4 (8.85 x 10 C /N m )(0.40 m) net q E r πε π = = ⋅ ; E = 2.25 x 105 _{N/C, radially inward} E θ W T F_e 40 cm -4 µC +6 µC r2

*24-42. The electric field intensity between the two plates in Fig. 24-4 is 2000 N/C. The length of the plates is 4 cm, and their separation is 1 cm. An electron is projected into the field from the left with horizontal velocity of 2 x 107 _{m/s. What is the upward deflection of the} electron at the instant it leaves the plates?

We may neglect the weight of the electron.

F = qE = may; y ; 0 qE a x v t g = = 2 2 2 2 0 0 ½ _y and x ; t x y a t t v v = = = 2 -19 2 2 -31 7 2 0 1 1 (1.6 x 10 C)(2000 N/C)(0.04 m) 2 2 (9.11 x 10 kg)(2 x 10 m/s) qE x y m v       = _{  }= _{ }      y = 0.0704 cm or y = 0.70 mm y x E = 2000 N/C