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ch24
Course: PHYSIC 2, Spring 2008School: Lehigh
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Word Count: 11016
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(a) 1. An Ampere is a Coulomb per second, so 84 A h = 84 FG H Ch s IJ FG 3600 s IJ = 3.0 10 K H hK 5 C. (b) The change in potential energy is U = qV = (3.0 105 C)(12 V) = 3.6 106 J. 2. The magnitude is U = eV = 1.2 109 eV = 1.2 GeV. 3. The electric field produced by an infinite sheet of charge has magnitude E = /20, where is the surface charge density. The field is normal to the sheet and is uniform....
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(a) 1. An Ampere is a Coulomb per second, so
84 A h = 84
FG H
Ch s
IJ FG 3600 s IJ = 3.0 10 K H hK
5
C.
(b) The change in potential energy is U = qV = (3.0 105 C)(12 V) = 3.6 106 J.
2. The magnitude is U = eV = 1.2 109 eV = 1.2 GeV.
3. The electric field produced by an infinite sheet of charge has magnitude E = /20, where is the surface charge density. The field is normal to the sheet and is uniform. Place the origin of a coordinate system at the sheet and take the x axis to be parallel to the field and positive in the direction of the field. Then the electric potential is
V = Vs -
z
x
0
E dx = Vs - Ex ,
where Vs is the potential at the sheet. The equipotential surfaces are surfaces of constant x; that is, they are planes that are parallel to the plane of charge. If two surfaces are separated by x then their potentials differ in magnitude by V = Ex = (/20)x. Thus, x = 2 0 V = 2 8.85 10-12 C 2 N m2 50 V . 010 10 C m
-6 2
c
hb g = 8.8 10
-3
m.
4. (a) VB VA = U/q = W/(e) = (3.94 1019 J)/(1.60 1019 C) = 2.46 V. (b) VC VA = VB VA = 2.46 V. (c) VC VB = 0 (Since C and B are on the same equipotential line).
. h c160 10 Ch = 2.4 10 N C . . (b) V = Es = c2.4 10 N Chb012 mg = 2.9 10 V.
5. (a) E = F e = 3.9 10-15 N
4
c
-19
4
3
6. (a) By Eq. 24-18, the change in potential is the negative of the "area" under the curve. Thus, using the area-of-a-triangle formula, we have
V - 10 = -
z
x =2
0
E ds =
1 2 20 2
b gb g
which yields V = 30 V. (b) For any region within 0 < x < 3 m,- E ds is positive, but for any region for which x > 3 m it is negative. Therefore, V = Vmax occurs at x = 3 m.
V - 10 = -
z
z
x =3
0
E ds =
1 3 20 2
b gb g
which yields Vmax = 40 V. (c) In view of our result in part (b), we see that now (to find V = 0) we are looking for some X > 3 m such that the "area" from x = 3 m to x = X is 40 V. Using the formula for a triangle (3 < x < 4) and a rectangle (4 < x < X), we require
1 1 20 + X - 4 20 = 40 . 2
b gb g b
gb g
Therefore, X = 5.5 m.
7. (a) The work done by the electric field is (in SI units) W=
f i
q q0 E ds = 0 2 0
d 0
q0 d (1.60 10-19 )(5.80 10-12 )(0.0356) = = 1.87 10-21 J. dz = -12 2 0 2(8.85 10 )
(b) Since V V0 = W/q0 = z/20, with V0 set to be zero on the sheet, the electric potential at P is (in SI units)
z (5.80 10-12 )(0.0356) V =- =- = -1.17 10-2 V. -12 2 0 2(8.85 10 )
8. We connect A to the origin with a line along the y axis, along which there is no change of potential (Eq. 24-18: E ds = 0 ). Then, we connect the origin to B with a line along
z
the x axis, along which the change in potential is
V = -
z
x =4
0
E ds = -4.00
z
4
0
x dx = -4.00
FG 4 IJ H 2K
2
which yields VB VA = 32.0 V.
9. (a) The potential as a function of r is (in SI units) V ( r ) = V (0) - =-
r 0
E ( r )dr = 0 -
r 0
qr qr 2 dr = - 4 0 R 3 8 0 R 3
(8.99 109 )(3.50 10-15 )(0.0145) 2 = -2.68 10-4 V. 2(0.0231)3
(b) Since V = V(0) V(R) = q/80R, we have (in SI units) (8.99 109 )(3.50 10-15 ) V ( R) = - =- = -6.8110-4 V. 8 0 R 2(0.0231) q
10. The charge is
q = 4 0 RV =
(10m) (-1.0V) 8.99 10 N m
9
2
/C
2
= -1.110-9 C.
11. (a) The charge on the sphere is q = 4 0 VR = (200 V)(0.15 m) = 3.3 10 -9 C. N m2 8.99 10 9 C2
(b) The (uniform) surface charge density (charge divided by the area of the sphere) is
=
q 3.3 10 -9 C = = 12 10 -8 C / m 2 . . 4 R 2 4 015 m 2 .
b
g
12. (a) The potential difference is VA - VB = q 4 0 rA - q 4 0 rB = (1.0 10
-6
C)
N m2 8.99 10 C2
9
1 1 - 2.0 m 1.0 m
= -4.5 103 V. (b) Since V(r) depends only on the magnitude of r , the result is unchanged.
13. First, we observe that V (x) cannot be equal to zero for x > d. In fact V (x) is always negative for x > d. Now we consider the two remaining regions on the x axis: x < 0 and 0 < x < d. (a) For 0 < x < d we have d1 = x and d2 = d x. Let V ( x) = k
FG q Hd
1 1
+
q2 q = 4 0 d2
IJ K
FG 1 + -3 IJ = 0 H x d - xK
and solve: x = d/4. With d = 24.0 cm, we have x = 6.00 cm. (b) Similarly, for x < 0 the separation between q1 and a point on the x axis whose coordinate is x is given by d1 = x; while the corresponding separation for q2 is d2 = d x. We set V ( x) = k
FG q Hd
1 1
+
q2 q = 4 0 d2
IJ K
FG 1 + -3 IJ = 0 H -x d - xK
to obtain x = d/2. With d = 24.0 cm, we have x = 12.0 cm.
14. Since according to the problem statement there is a point in between the two charges on the x axis where the net electric field is zero, the fields at that point due to q1 and q2 must be directed opposite to each other. This means that q1 and q2 must have the same sign (i.e., either both are positive or both negative). Thus, the potentials due to either of them must be of the same sign. Therefore, the net electric potential cannot possibly be zero anywhere except at infinity.
15. A charge 5q is a distance 2d from P, a charge 5q is a distance d from P, and two charges +5q are each a distance d from P, so the electric potential at P is (in SI units) V= q 4 0 - 1 1 1 1 q (8.99 109 )(5.00 10-15 ) - + + = = = 5.62 10-4 V. 2d d d d 8 0 d 2(4.00 10-2 )
The zero of the electric potential was taken to be at infinity.
16. In applying Eq. 24-27, we are assuming V 0 as r . All corner particles are equidistant from the center, and since their total charge is 2q1 3q1+ 2 q1 q1 = 0, then their contribution to Eq. 24-27 vanishes. The net potential is due, then, to the two +4q2 particles, each of which is a distance of a/2 from the center. In SI units, it is V= 4q2 1 4q2 16q2 16(8.99 109 )(6.00 10-12 ) + = = = 2.21 V. 4 0 a / 2 4 0 a / 2 4 0 a 0.39 1
17. (a) The electric potential V at the surface of the drop, the charge q on the drop, and the radius R of the drop are related by V = q/40R. Thus
8.99 10 9 N m 2 / C 2 30 10 -12 C q R= = = 5.4 10 -4 m. 4 0V 500 V
c
hc
h
(b) After the drops combine the total volume is twice the volume of an original drop, so the radius R' of the combined drop is given by (R')3 = 2R3 and R' = 21/3R. The charge is twice the charge of original drop: q' = 2q. Thus,
V =
1 q 1 2q = = 2 2 / 3V = 2 2 / 3 (500 V) 790 V. 4 0 R 4 0 2 1/ 3 R
18. When the charge q2 is infinitely far away, the potential at the origin is due only to the charge q1 : V1 =
q1
4 0 d
= 5.76 10-7 V.
Thus, q1/d = 6.41 10-17 C/m. Next, we note that when q2 is located at x = 0.080 m, the net potential vanishes (V1 + V2 = 0). Therefore,
0=
kq2 kq + 1 0.08 m d
Thus, we find q2 = -(q1 / d )(0.08 m) = 5.13 10-18 C = 32 e.
19. We use Eq. 24-20:
8.99 109 1 p V= = 4 0 r 2
e
Nm2 C2
. j c147 3.34 10 c52.0 10 mh
-9 2
-30
Cm
h
. = 163 10-5 V.
20. From Eq. 24-30 and Eq. 24-14, we have (for i = 0) Wa = qV = e p cos p cos i - = 4o r2 4o r2 ep (cos - 1) . 4o r2
where r = 20 10-9 m. For = 180 the graph indicates Wa = -4.0 10-30 J, from which we can determine p. The magnitude of the dipole moment is therefore 5.6 10-37 C.m.
21. (a) From Eq. 24-35, in SI units,
V =2
L / 2 + ( L2 / 4) + d 2 ln 4 0 d
9
= 2(8.99 10 )(3.68 10 = 2.43 10-2 V.
-12
(0.06 / 2) + (0.06) 2 / 4 + (0.08) 2 ) ln 0.08
(b) The potential at P is V = 0 due to superposition.
22. The potential is (in SI units) 1 VP = 4 0 dq 1 = rod R 4 0 R -Q (8.99 109 )(25.6 10-12 ) dq = =- = -6.20 V. rod 4 0 R 3.7110-2
We note that the result is exactly what one would expect for a point-charge Q at a distance R. This "coincidence" is due, in part, to the fact that V is a scalar quantity.
23. (a) All the charge is the same distance R from C, so the electric potential at C is (in SI units) V= 1 4 0 Q1 6Q1 5Q1 5(8.99 109 )(4.20 10-12 ) - =- =- = -2.30 V, R R 4 0 R 8.20 10-2
where the zero was taken to be at infinity. (b) All the charge is the same distance from P. That distance is potential at P is (in SI units)
V= 1 4 0 Q1 R +D
2 2
R 2 + D 2 , so the electric
-
6Q1 R +D
2 2
=-
5Q1 4 0 R 2 + D
2
=-
5(8.99 109 )(4.20 10-12 ) (8.20 10-2 ) 2 + (6.7110-2 ) 2
= -1.78 V.
24. Since the charge distribution on the arc is equidistant from the point where V is evaluated, its contribution is identical to that of a point charge at that distance. We assume V 0 as r and apply Eq. 24-27:
V= = 1 +Q1 1 +4Q1 1 -2Q1 1 Q1 + + = 4 0 R 4 2 R 4 0 R 4 0 R (8.99 109 )(7.2110-12 ) = 3.24 10-2 V. 2.00
25. The disk is uniformly charged. This means that when the full disk is present each quadrant contributes equally to the electric potential at P, so the potential at P due to a single quadrant is one-fourth the potential due to the entire disk. First find an expression for the potential at P due to the entire disk. We consider a ring of charge with radius r and (infinitesimal) width dr. Its area is 2r dr and it contains charge dq = 2r dr. All the charge in it is a distance r 2 + D 2 from P, so the potential it produces at P is dV = The total potential at P is
V=
1 2 rdr rdr . = 2 2 4 0 r + D 2 0 r 2 + D 2
2 0
R
0
rdr r +D
2 2
=
r 2 + D2 2 0
R 0
=
2 0
R2 + D2 - D .
The potential Vsq at P due to a single quadrant is (in SI units)
Vsq = V = 4 8 0 R2 + D2 - D = (7.73 10-15 ) 8(8.85 10-12 ) (0.640) 2 + (0.259) 2 - 0.259
= 4.7110-5 V.
26. The dipole potential is given by Eq. 24-30 (with = 90 in this case) V= p cos =0 4o r2
since cos(90) = 0 . The potential due to the short arc is q1 / 4 0 r1 and that caused by the long arc is q2 / 4 0 r2 . Since q1 = +2 C, r1 = 4.0 cm, q2 = -3 C, and r2 = 6.0 cm, the potentials of the arcs cancel. The result is zero.
27. Letting d denote 0.010 m, we have (in SI units) Q1 3Q1 3Q1 Q1 (8.99 109 )(30 10-9 ) + - = = = 1.3 104 V. V= 4 0 d 8 0 d 16 0 d 8 0 d 2(0.01)
28. Consider an infinitesimal segment of the rod, located between x and x + dx. It has length dx and contains charge dq = dx, where = Q/L is the linear charge density of the rod. Its distance from P1 is d + x and the potential it creates at P1 is
dV = 1 dq 1 dx = . 4 0 d + x 4 0 d + x
To find the total potential at P1, we integrate over the length of the rod and obtain (in SI units): V= =
4 0
L 0
dx = ln(d + x) d + x 4 0
L 0
=
Q L ln 1 + d 4 0 L
(8.99 109 )(56.110-15 ) 0.12 = 7.39 10-3 V. ln 1 + 0.12 0.025
29. Consider an infinitesimal segment of the rod, located between x and x + dx. It has length dx and contains charge dq = dx = cx dx. Its distance from P1 is d + x and the potential it creates at P1 is
dV = 1 dq 1 cx dx = . 4 0 d + x 4 0 d + x
To find the total potential at P1, we integrate over the length of the rod and obtain (in SI units):
V=
c 4 0
L 0
L xdx c c L = L - d ln 1 + [ x - d ln( x + d )] = d + x 4 0 d 4 0 0
= (8.99 109 )(28.9 10-12 ) 0.12 - (0.03) ln 1 +
0.12 0.03
= 1.86 10-2 V.
30. The magnitude of the electric field is given by
| E |= - V 2(5.0V) = = 6.7 102 V m. 0.015m x
At any point in the region between the plates, E points away from the positively charged plate, directly towards the negatively charged one.
31. We use Eq. 24-41: V =- (2.0V / m2 ) x 2 - 3.0V / m2 ) y 2 = -2(2.0V / m2 ) x; x x V E y ( x, y) = - =- (2.0V / m2 ) x 2 - 3.0V / m2 ) y 2 = 2(3.0V / m2 ) y . y y E x ( x, y) = -
c c
h h
We evaluate at x = 3.0 m and y = 2.0 m to obtain
^ ^ E = (-12 V/m)i + (12 V/m)j .
32. We use Eq. 24-41. This is an ordinary derivative since the potential is a function of only one variable. E=-
FG dV IJ i = - d (1500x ) i = (-3000x) i H dx K dx
2
= ( -3000 V / m2 ) (0.0130 m)i = ( -39 V / m)i. (a) Thus, the magnitude of the electric field is E = 39 V/m.
i (b) The direction of E is -^ , or toward plate 1.
33. We apply Eq. 24-41: V = -2.00 yz 2 x V = -2.00 xz 2 Ey = - y V = -4.00 xyz Ez = - z Ex = - which, at (x, y, z) = (3.00, 2.00, 4.00), gives (Ex, Ey, Ez) = (64.0, 96.0, 96.0) in SI units. The magnitude of the field is therefore
2 E = Ex2 + E y + Ez2 = 150 V m = 150 N C.
34. (a) According to the result of problem 28, the electric potential at a point with coordinate x is given by V= At x = d we obtain (in SI units) V= Q d+L (8.99 109 )(43.6 10-15 ) 0.135 ln ln 1 + = 4 0 L d 0.135 d 0.135 . d Q x-L ln . 4 0 L x
= (2.90 10-3 V) ln 1 +
(b) We differentiate the potential with respect to x to find the x component of the electric field (in SI units): Ex = - =- or | Ex |= (3.92 10-4 ) . x( x + 0.135) V Q x-L Q x 1 x-L Q ln =- =- - 2 =- 4 0 L x x 4 0 L x - L x x 4 0 x ( x - L) x (8.99 109 )(43.6 10-15 ) (3.92 10-4 ) , =- x( x + 0.135) x( x + 0.135)
(c) Since Ex < 0 , its direction relative to the positive x axis is 180. (d) At x = d we obtain (in SI units) | Ex |= (3.92 10-4 ) = 0.0321 N/C. (0.0620)(0.0620 + 0.135)
(e) Consider two points an equal infinitesimal distance on either side of P1, along a line that is perpendicular to the x axis. The difference in the electric potential divided by their separation gives the transverse component of the electric field. Since the two points are situated symmetrically with respect to the rod, their potentials are the same and the potential difference is zero. Thus, the transverse component of the electric field Ey is zero.
35. The electric field (along some axis) is the (negative of the) derivative of the potential V with respect to the corresponding coordinate. In this case, the derivatives can be read off of the graphs as slopes (since the graphs are of straight lines). Thus, -500 V dV Ex = d x = 0.20 m = 2500 V/m = 2500 N/C 300 V dV Ey = d y = 0.30 m = 1000 V/m = 1000 N/C . These components imply the electric field has a magnitude of 2693 N/C and a direction of 21.8 (with respect to the positive x axis). The force on the electron is given by F = qE where q = e. The minus sign associated with the value of q has the implication that F points in the opposite direction from E (which is to say that its angle is found by adding 180 to that of E ). With e = 1.60 1019 C, we obtain
^ ^ ^ ^ F = (-1.60 10-19 C)[(2500 N/C)i - (1000 N/C)j] = ( -4.0 10 -16 N)i + (1.60 10 -16 N)j .
36. (a) Consider an infinitesimal segment of the rod from x to x + dx. Its contribution to the potential at point P2 is
dV = 1 ( x )dx 1 = 2 2 4 0 x + y 4 0 cx x + y2
2
dx.
Thus, (in SI units) V= dVP = c 4 0
L
x x +y
2 2
rod
0
dx =
c 4 0
(
L2 + y 2 - y
) )
= (8.99 109 )(49.9 10-12 ) = 3.16 10-2 V. (b) The y component of the field there is
Ey = - VP c d =- 4 0 dy y
(
(0.100) 2 + (0.0356) 2 - 0.0356
(
L2 + y 2 - y =
)
c y 1- . 2 4 0 L + y2 0.0356
= (8.99 109 )(49.9 10-12 ) 1 - = 0.298 N/C.
(0.100) 2 + (0.0356) 2
(c) We obtained above the value of the potential at any point P strictly on the y-axis. In order to obtain Ex(x, y) we need to first calculate V(x, y). That is, we must find the potential for an arbitrary point located at (x, y). Then Ex(x, y) can be obtained from Ex ( x, y ) = -V ( x, y ) / x .
37. We choose the zero of electric potential to be at infinity. The initial electric potential energy Ui of the system before the particles are brought together is therefore zero. After the system is set up the final potential energy is Uf = q2 1 1 1 1 1 1 2q 2 - - + - - + = 4 0 a a 4 0 a 2a a a 2a 1 -2 . 2
Thus the amount of work required to set up the system is given by (in SI units)
2q 2 W = U = U f - U i = U f = 4 0 a = -1.92 10-13 J. 1 2(8.99 109 )(2.30 10-12 ) 2 -2 = (0.640) 2 1 -2 2
38. The work done must equal the change in the electric potential energy. From Eq. 2414 and Eq. 24-26, we find (with r = 0.020 m) W= (3e) (7e) = 2.1 10-25 J . 4o r
39. (a) We use Eq. 24-43 with q1 = q2 = e and r = 2.00 nm:
8.99 109 NCm (160 10-19 C) 2 . 2 e2 q1q2 =k = = 115 10-19 J. U =k . -9 r r 2.00 10 m
d
2
i
(b) Since U > 0 and U r1 the potential energy U decreases as r increases.
40. The work required is W = U = 1 q1Q q2Q 1 q1Q (-q1 / 2)Q + = + = 0. 4 0 2d d 4 0 2d d
41. (a) Let = 015 m be the length of the rectangle and w = 0.050 m be its width. Charge . q1 is a distance from point A and charge q2 is a distance w, so the electric potential at A is VA = 1 q1 q2 -5.0 10-6 C 2.0 10-6 C + = (8.99 109 N m 2 / C2 ) + 4 0 0.15 m 0.050 m w
= 6.0 104 V. (b) Charge q1 is a distance w from point b and charge q2 is a distance , so the electric potential at B is VB = 1 q1 q2 -5.0 10-6 C 2.0 10-6 C + = (8.99 109 N m 2 / C2 ) + 4 0 w 0.050 m 0.15 m
= -7.8 105 V. (c) Since the kinetic energy is zero at the beginning and end of the trip, the work done by an external agent equals the change in the potential energy of the system. The potential energy is the product of the charge q3 and the electric potential. If UA is the potential energy when q3 is at A and UB is the potential energy when q3 is at B, then the work done in moving the charge from B to A is W = UA UB = q3(VA VB) = (3.0 106 C)(6.0 104 V + 7.8 105 V) = 2.5 J. (d) The work done by the external agent is positive, so the energy of the three-charge system increases. (e) and (f) The electrostatic force is conservative, so the work is the same no matter which path is used.
42. Let r = 1.5 m, x = 3.0 m, q1 = 9.0 nC, and q2 = 6.0 pC. The work done by an external agent is given by W = U = q1q2 1 1 - 4 0 r r 2 + x2
FG H
IJ K h FGH 8.99 10
9
= -9.0 10-9 C -6.0 10-12 C = 18 10-10 J. .
c
hc
N m2 1 - 2 C 15 m .
IJ K
LM MN
OP . b15 mg + b3.0 mg PQ
1
2 2
43. We use the conservation of energy principle. The initial potential energy is Ui = q2/40r1, the initial kinetic energy is Ki = 0, the final potential energy is Uf = q2/40r2, 1 and the final kinetic energy is K f = 2 mv 2 , where v is the final speed of the particle. Conservation of energy yields
q2 q2 1 = + mv 2 . 4 0r1 4 0r2 2
The solution for v is
v= 2q 2 1 1 (8.99 109 N m 2 C2 )(2)(3.1 10-6 C) 2 1 1 - = - -6 -3 4 0 m r1 r2 20 10 kg 0.90 10 m 2.5 10-3 m
= 2.5 103 m s.
44. The change in electric potential energy of the electron-shell system as the electron starts from its initial position and just reaches the shell is U = (e)(V) = eV. Thus from 1 U = K = 2 me vi2 we find the initial electron speed to be (in SI units)
vi =
2U 2eV 2(1.6 10-19 )(125) = = = 6.63106 m/s. -31 9.1110 me me
45. We use conservation of energy, taking the potential energy to be zero when the moving electron is far away from the fixed electrons. The final potential energy is then U f = 2e 2 / 4 0 d , where d is half the distance between the fixed electrons. The initial
1 kinetic energy is Ki = 2 mv 2 , where m is the mass of an electron and v is the initial speed of the moving electron. The final kinetic energy is zero. Thus Ki = Uf or 2 2 1 2 mv = 2e / 4 0 d . Hence
4e 2 v= = 4 0 dm
. c8.99 10 N m C h b4gc160 10 b0.010 mgc9.11 10 kgh
9 2 2 -31
-19
C
h
2
= 3.2 102 m s.
46. (a) The electric field between the plates is leftward in Fig, 24-50 since it points towards lower values of potential. The force (associated with the field, by Eq. 23-28) is evidently leftward, from the problem description (indicating deceleration of the rightward moving particle), so that q > 0 (ensuring that F is parallel to E ); it is a proton. (b) We use conservation of energy: K0 + U0 =K + U 1 1 2 2 2 mpv0 + qV1= 2 mpv + qV 2 .
Using q = +1.6 10-19 C, mp = 1.67 10-27 kg, v0 = 90 103 m/s, V1 = -70 V and V2 = -50 V , we obtain the final speed v = 6.53 104 m/s. We note that the value of d is not used in the solution.
47. Let the distance in question be r. The initial kinetic energy of the electron is 1 Ki = 2 me vi2 , where vi = 3.2 105 m/s. As the speed doubles, K becomes 4Ki. Thus
U = or r= 2e 2
-e2 3 = - K = - (4 Ki - Ki ) = -3Ki = - me vi2 , 4 0 r 2
3 ( 4 0 ) m v
2 e i
=
3 ( 9.1110
2 (1.6 10-19 C ) 8.99 109
2
-19
( kg )( 3.2 10
5
) = 1.6 10 m s)
N m 2 C2 2
-9
m.
48. When particle 3 is at x = 0.10 m, the total potential energy vanishes. Using Eq. 24-43, we have (with meters understood at the length unit) 0 = This leads to q2 q1 q2 q1 q3 (d + 0.10) + 0.10 = d which yields q3 = -5.7 C. q1 q2 q1 q3 q3 q2 + + . 4o d 4o (d + 0.10) 4o (0.10)
49. We apply conservation of energy for particle 3 (with q' = -15 10-6 C):
K 0 + U0 = K f + U f where (letting x = 3 m and q1 = q2 = 50 10-6 C = q) U = q1 q' q2 q' q q' . 2 2+ 2 2 = 2o x2 + y2 4o x + y 4o x + y
(a) We solve for Kf (with y0 = 4 m): Kf =K0 + U0 - Uf = 1.2 J + q q' + 2o 1 1 2 - |x| = 3.0 J . x + y0
2
(b) We set Kf = 0 and solve for y (choosing the negative root, as indicated in the problem statement): K0 + U0 = U f This yields y = -8.5 m. 1.2 J + q q' q q' 2 2= 2o x + y0 2o x2 + y2
50. From Eq. 24-30 and Eq. 24-7, we have (for = 180)
U = qV = e
p cos ep = 4o r2 4o r2
where r = 0.020 m. Appealing to energy conservation, we set this expression equal to 100 eV and solve for p. The magnitude of the dipole moment is therefore 4.5 10-12 C.m.
51. (a) Using U = qV we can "translate" the graph of voltage into a potential energy graph (in eV units). From the information in the problem, we can calculate its kinetic energy (which is its total energy at x = 0) in those units: Ki = 284 eV. This is less than the "height" of the potential energy "barrier" (500 eV high once we've translated the graph as indicated above). Thus, it must reach a turning point and then reverse its motion.
(b) Its final velocity, then, is in the negative x direction with a magnitude equal to that of its initial velocity. That is, its speed (upon leaving this region) is 1.0 107 m/s.
52. (a) The work done results in a potential energy gain: W = q V = (- e) Q = + 2.16 10-13 J . 4o R
With R = 0.0800 m, we find Q = 1.20 10-5 C. (b) The work is the same, so the increase in the potential energy is U = + 2.16 10-13 J.
53. If the electric potential is zero at infinity, then the potential at the surface of the sphere is given by V = q/40r, where q is the charge on the sphere and r is its radius. Thus
q = 4 0 rV =
. b015 mgb1500 Vg 8.99 10 N m C
9 2 2
= 2.5 10-8 C.
54. Since the electric potential throughout the entire conductor is a constant, the electric potential at its center is also +400 V.
55. (a) The electric potential is the sum of the contributions of the individual spheres. Let q1 be the charge on one, q2 be the charge on the other, and d be their separation. The point halfway between them is the same distance d/2 (= 1.0 m) from the center of each sphere, so the potential at the halfway point is
(8.99 109 N m2 C2 )(1.0 10-8 C - 3.0 10-8 C ) = -1.8 102 V. q1 + q2 V= = 4 0 d 2 1.0 m
(b) The distance from the center of one sphere to the surface of the other is d R, where R is the radius of either sphere. The potential of either one of the spheres is due to the charge on that sphere and the charge on the other sphere. The potential at the surface of sphere 1 is V1 = 1 4 0 q1 q2 1.0 10-8 C 3.0 10-8 C 9 2 2 + = ( 8.99 10 N m C ) - = 2.9 103 V. R d -R 0.030 m 2.0 m - 0.030 m
(c) The potential at the surface of sphere 2 is V2 = 1 4 0 q1 q 1.0 10-8 C 3.0 10-8 C + 2 = ( 8.99 109 N m 2 C 2 ) - = -8.9 103 V. d -R R 2.0 m - 0.030 m 0.030 m
56. (a) Since the two conductors are connected V1 and V2 must be equal to each other. Let V1 = q1/40R1 = V2 = q2/40R2 and note that q1 + q2 = q and R2 = 2R1. We solve for q1 and q2: q1 = q/3, q2 = 2q/3, or (b) q1/q = 1/3 = 0.333, (c) and q2/q = 2/3 = 0.667. (d) The ratio of surface charge densities is
1 q1 4R12 q = = 1 2 q2 2 q2 4R2
R2 R1
2
= 2.00.
57. (a) The magnitude of the electric field is N m2 ( 3.0 10 C ) 8.99 10 C2
-8
9
E=
q = = 0 4 0 R 2
( 0.15 m )
2
= 1.2 104 N C.
(b) V = RE = (0.15 m)(1.2 104 N/C) = 1.8 103 V. (c) Let the distance be x. Then V = V x - V = which gives x= 015 m -500 V . RV . = = 58 10-2 m. -V - V -1800 V + 500 V
bg
q 1 1 - = -500 V, 4 0 R + x R
FG H
IJ K
b
gb
g
58. Since the charge distribution is spherically symmetric we may write
E r =
bg
1 qencl , 4 0 r
where qencl is the charge enclosed in a sphere of radius r centered at the origin. (a) For r = 4.00 m, R2 = 1.00 m and R1 = 0.500 m, with r > R2 > R1 we have (in SI units) E (r ) = q1 + q2 (8.99 109 )(2.00 10-6 + 1.00 10-6 ) = = 1.69 103 V/m. 2 2 4 0 r (4.00)
(b) For R2 > r = 0.700 m > R2 q1 (8.99 109 )(2.00 10-6 ) E (r ) = = = 3.67 104 V/m. 2 2 4 0 r (0.700) (c) For R2 > R1 > r, the enclosed charge is zero. Thus, E = 0. The electric potential may be obtained using Eq. 24-18: V r - V r = (d) For r = 4.00 m > R2 > R1, we have V (r ) = q1 + q2 (8.99 109 )(2.00 10-6 + 1.00 10-6 ) = = 6.74 103 V. 4 0 r (4.00)
bg b g
z
r
r
E r dr .
bg
(e) For r = 1.00 m = R2 > R1, we have V (r ) = q1 + q2 (8.99 109 )(2.00 10-6 + 1.00 10-6 ) = = 2.70 104 V. 4 0 r (1.00)
(f) For R2 > r = 0.700 m > R2, 1 V (r ) = 4 0 q1 q2 2.00 10-6 1.00 10-6 9 + = (8.99 10 ) + = 3.47 104 V. r R2 0.700 1.00
(g) For R2 > r = 0.500 m = R2,
V (r ) =
1 4 0
q1 q2 2.00 10-6 1.00 10-6 + = (8.99 109 ) + = 4.50 104 V. r R2 0.500 1.00
(h) For R2 > R1 > r, V= 1 4 0 q1 q2 2.00 10-6 1.00 10-6 + = (8.99 109 ) + = 4.50 104 V. R1 R2 0.500 1.00
(i) At r = 0, the potential remains constant, V = 4.50 104 V. (j) The electric field and the potential as a function of r are depicted below:
59. Using Gauss' law, q = = +495.8 nC. Consequently, V =
q = 37.1 kV. 4o r
60. (a) We use Eq. 24-18 to find the potential: Vwall - V = -
R r
Edr , or
0 -V = -
R r
r 2 0
-V = -
( R2 - r 2 ) . 4 0
Consequently, V = (R2 r2)/40. (b) The value at r = 0 is Vcenter -11 10-3 C m3 . = 4 8.85 10-12 C V m
c
h eb0.05 mg - 0j = -7.8 10 V.
2 4
Thus, the difference is | Vcenter |= 7.8 104 V.
61. The electric potential energy in the presence of the dipole is U = qVdipole= q p cos (-e)( e d) cos = . 4o r2 4o r2
Noting that i = f = 0, conservation of energy leads to Kf + Uf = Ki + Ui v= 1 2 e2 1 - 4o m d 25 49 = 7.0 105 m/s .
62. (a) When the proton is released, its energy is K + U = 4.0 eV + 3.0 eV (the latter value is inferred from the graph). This implies that if we draw a horizontal line at the 7.0 Volt "height" in the graph and find where it intersects the voltage plot, then we can determine the turning point. Interpolating in the region between 1.0 cm and 3.0 cm, we find the turning point is at roughly x = 1.7 cm.
(b) There is no turning point towards the right, so the speed there is nonzero, and is given by energy conservation: v= 2(7.0 eV) = m 2(7.0 eV)(1.6 x 10-19 J/eV) = 20 km/s. 1.67 x 10-27 kg
(c) The electric field at any point P is the (negative of the) slope of the voltage graph evaluated at P. Once we know the electric field, the force on the proton follows immediately from F = q E , where q = +e for the proton. In the region just to the left of x i = 3.0 cm, the field is E = (+300 V/m) ^ and the force is F = +4.8 10-17 N. (d) The force F points in the +x direction, as the electric field E .
i (e) In the region just to the right of x = 5.0 cm, the field is E =(200 V/m) ^ and the -17 magnitude of the force is F = 3.2 10 N.
(f) The force F points in the -x direction, as the electric field E .
63. Eq. 24-32 applies with dq = dx = bx dx (along 0 x 0.20 m).
(a) Here r = x > 0, so that V= 1 4 0
z
0.20
0
bx dx b 0.20 = = 36 V. x 4 0
b g
(b) Now r = x 2 + d 2 where d = 0.15 m, so that 1 V= 4 0
0.20 0
b = 2 2 4 0 x +d
bxdx
(
x +d
2
2
)
0.20
= 18 V.
0
64. (a)When the electron is released, its energy is K + U = 3.0 eV - 6.0 eV (the latter value is inferred from the graph along with the fact that U = qV and q = - e). Because of the minus sign (of the charge) it is convenient to imagine the graph multiplied by a minus sign so that it represents potential energy in eV. Thus, the 2 V value shown at x = 0 would become 2 eV, and the 6 V value at x = 4.5 cm becomes 6 eV, and so on. The total energy (- 3.0 eV) is constant and can then be represented on our (imagined) graph as a horizontal line at - 3.0 V. This intersects the potential energy plot at a point we recognize as the turning point. Interpolating in the region between 1.0 cm and 4.0 cm, we find the turning point is at x = 1.75 cm 1.8 cm. (b) There is no turning point towards the right, so the speed there is nonzero. Noting that the kinetic energy at x = 7.0 cm is - 3.0 eV - (- 5.0 eV) = 2.0 eV, we find the speed using energy conservation: v= 2(2.0 eV) = m 2(2.0 eV)(1.6 x 10-19 J/eV) = 8.4 105 m/s . 9.11 x 10-31 kg
(c) The electric field at any point P is the (negative of the) slope of the voltage graph evaluated at P. Once we know the electric field, the force on the electron follows immediately from F = q E , where q = -e for the electron. In the region just to the left i of x = 4.0 cm, the field is E = (-133 V/m) ^ and the magnitude of the force is -17 F = 2.110 N . (d) The force points in the +x direction.
(e) In the region just to the right of x = 5.0 cm, the field is E = +100 V/m ^ and the force i -17 ^ . Thus, the magnitude of the force is F = 1.6 10-17 N . is F = ( 1.6 x 10 N) i
(f) The minus sign indicates that F points in the x direction.
65. We treat the system as a superposition of a disk of surface charge density and radius R and a smaller, oppositely charged, disk of surface charge density and radius r. For each of these, Eq 24-37 applies (for z > 0)
V=
2 0
e
z2 + R2 - z +
j
- 2 0
e
z2 + r 2 - z .
j
This expression does vanish as r , as the problem requires. Substituting r = 0.200R and z = 2.00R and simplifying, we obtain
V=
R 5 5 - 101 (6.20 10-12 )(0.130) 5 5 - 101 = = 1.03 10-2 V. 10 8.85 10-12 10 0
66. Since the electric potential energy is not changed by the introduction of the third particle, we conclude that the net electric potential evaluated at P caused by the original two particles must be zero: q1 q2 + =0. 4o r1 4o r2 Setting r1 = 5d/2 and r2 = 3d /2 we obtain q1 = 5q2/3, or q1 / q2 = -5 / 3 -1.7 .
67. The electric field throughout the conducting volume is zero, which implies that the potential there is constant and equal to the value it has on the surface of the charged sphere:
VA = VS =
q 40 R
where q = 30 10-9 C and R = 0.030 m. For points beyond the surface of the sphere, the potential follows Eq. 24-26: VB = where r = 0.050 m. (a) We see that VS VB = (b) Similarly, VA VB = q 4 0 1 1 - = 3.6 103 V. R r q 4 0 1 1 - = 3.6 103 V. R r q 40 r
68. The escape speed may be calculated from the requirement that the initial kinetic energy (of launch) be equal to the absolute value of the initial potential energy (compare with the gravitational case in chapter 14). Thus, 1 eq 2 2 m v = 4o r where m = 9.11 10-31 kg, e = 1.60 10-19 C, q = 10000e, and r = 0.010 m. This yields the answer v = 22490 m/s 2.2 104 m/s .
69. We apply conservation of energy for the particle with q = 7.5 10-6 C (which has zero initial kinetic energy):
U0 = Kf + Uf
where U =
qQ . 4or
(a) The initial value of r is 0.60 m and the final value is (0.6 + 0.4) m = 1.0 m (since the particles repel each other). Conservation of then, energy, leads to Kf = 0.90 J. (b) Now the particles attract each other so that the final value of r is 0.60 - 0.40 = 0.20 m. Use of energy conservation yields Kf = 4.5 J in this case.
70. (a) Using d = 2 m, we find the potential at P:
VP =
1 +2e 1 -2e 1 e + = . 40 d 40 2d 40 d
Thus, with e = 1.60 10-19 C, we find VP = 7.19 10-10 V. Note that we are implicitly assuming that V 0 as r . (b) Since U = qV , then the movable particle's contribution of the potential energy when it is at r = is zero, and its contribution to Usystem when it is at P is (2e)VP = 2.30 10-28 J. Thus, we obtain Wapp = 2.30 10-28 J. (c) Now, combining the contribution to Usystem from part (b) and from the original pair of fixed charges Ufixed = we obtain Usystem = Upart (b) + Ufixed = 2.43 1029 J . 1 (2e)(-2e) = 2.1 10-28 J , 40 42 + 22
71. The derivation is shown in the book (Eq. 24-33 through Eq. 24-35) except for the change in the lower limit of integration (which is now x = D instead of x = 0). The result is therefore (cf. Eq. 24-35)
L + L2 + d2 V= ln 4o D + D2 + d2
2.0 x 10-6 4 + 17 = ln = 2.18 104 V. 4o 1+ 2
72. Using Eq. 24-18, we have
V = -
3 2
A 1 1 A dr = 3 23 - 33 = A(0.029/m3). 4 r
73. The work done results in a change of potential energy: W = U = 2(0.12 C)2 2(0.12 C)2 8 - 1.7 m 4o (1.7 m) =1.5 10 J . 4o 2
At a rate of P = 0.83 103 Joules per second, it would take W/P = 1.8 105 seconds or about 2.1 days to do this amount of work.
74. The charges are equidistant from the point where we are evaluating the potential -- which is computed using Eq. 24-27 (or its integral equivalent). Eq. 24-27 implicitly assumes V 0 as r . Thus, we have
1 +Q1 1 -2Q1 1 +3Q1 1 2Q1 2(8.99 109 )(4.52 10-12 ) V= + + = = 4 0 R 4 0 R 4 0 R 4 0 R 0.0850 = 0.956 V.
75. The radius of the cylinder (0.020 m, the same as rB) is denoted R, and the field magnitude there (160 N/C) is denoted EB. The electric field beyond the surface of the sphere follows Eq. 23-12, which expresses inverse proportionality with r:
E EB = R r for r R .
(a) Thus, if r = rC = 0.050 m, we obtain E = 160 0.020
b gb
g b0.050g = 64 N C .
(b) Integrating the above expression (where the variable to be integrated, r, is now denoted ) gives the potential difference between VB and VC.
VB - VC =
r R
EB R
d = EB R ln
r = 2.9 V . R
(c) The electric field throughout the conducting volume is zero, which implies that the potential there is constant and equal to the value it has on the surface of the charged cylinder: VA VB = 0.
76. We note that for two points on a circle, separated by angle (in radians), the directline distance between them is r = 2R sin(/2). Using this fact, distinguishing between the cases where N = odd and N = even, and counting the pair-wise interactions very carefully, we arrive at the following results for the total potential energies. We use k = 1 4 0 . For configuration 1 (where all N electrons are on the circle), we have
U1, N =even
Nke 2 = 2R
N -1 2
1 1 Nke 2 + , U1, N =odd = 2 2R j =1 sin ( j 2 )
N -1 2
1 j =1 sin ( j 2 )
where =
2 . For configuration 2, we find N
U 2 , N = even
U 2 , N = odd
b N - 1gke FG = GH 2R b N - 1gke FG = GH 2R
2 2
N -1 2
1 +2 j =1 sin j 2
N -3 2 j =1
I J b g JK I 1 5J + sin b j 2g 2 J K
where =
2 . The results are all of the form N -1
U 1or 2
ke 2 a pure number. 2R
In our table, below, we have the results for those "pure numbers" as they depend on N and on which configuration we are considering. The values listed in the U rows are the potential energies divided by ke2/2R.
N 4 5 U1 3.83 6.88 U2 4.73 7.83 6 10.96 11.88 7 16.13 16.96 8 22.44 23.13 9 29.92 30.44 10 38.62 39.92 11 48.58 48.62 12 59.81 59.58 13 72.35 71.81 14 86.22 85.35 15 101.5 100.2
We see that the potential energy for configuration 2 is greater than that for configuration 1 for N < 12, but for N 12 it is configuration 1 that has the greatest potential energy. (a) N = 12 is the smallest value such that U2 < U1.
(b) For N = 12, configuration 2 consists of 11 electrons distributed at equal distances around the circle, and one electron at the center. A specific electron e0 on the circle is R distance from the one in the center, and is
r = 2 R sin
FG IJ 0.56R H 11K FG 2 IJ 11R H 11 K .
distance away from its nearest neighbors on the circle (of which there are two -- one on each side). Beyond the nearest neighbors, the next nearest electron on the circle is
r = 2 R sin
distance away from e0. Thus, we see that there are only two electrons closer to e0 than the one in the center.
77. We note that the net potential (due to the "fixed" charges) is zero at the first location ("at ") being considered for the movable charge q (where q = +2e). Thus, the work required is equal to the potential energy in the final configuration: qV where V = 1 (+2e) 1 +e + . 40 2D 40 D
Using D = 4.00 m and e = 1.60 10-19 C, we obtain Wapp = qV = (2e)(7.20 10-10 V) = 2.30 10-28 J.
78. Since the electric potential is a scalar quantity, this calculation is far simpler than it would be for the electric field. We are able to simply take half the contribution that would be obtained from a complete (whole) sphere. If it were a whole sphere (of the same density) then its charge would be qwhole = 8.00 C. Then
1 1 qwhole 1 8.00 x 10-6 C V = 2 Vwhole = 2 = 2 = 2.40 105 V . 4o r 4o(0.15 m)
79. The net potential at point P (the place where we are to place the third electron) due to the fixed charges is computed using Eq. 24-27 (which assumes V 0 as r ):
VP =
1 -e 1 -e -e + = . 40 d 40 d 20d
Thus, with d = 2.00 10-6 m and e = 1.60 10-19 C, we find VP = -1.438 10-3 V. Then the required "applied" work is, by Eq. 24-14, Wapp = (-e) VP = 2.30 10-22 J .
80. The work done is equal to the change in the (total) electric potential energy U of the system, where
U =
q1 q2 q3 q2 q1 q3 + + 4o r12 4o r23 4o r13
and the notation r13 indicates the distance between q1 and q3 (similar definitions apply to r12 and r23). (a) We consider the difference in U where initially r12 = b and r23 = a, and finally r12 = a and r23 = b (r13 doesn't change). Converting the values given in the problem to SI units (C to C, cm to m), we obtain U = 24 J. (b) Now we consider the difference in U where initially r23 = a and r13 = a, and finally r23 is again equal to a and r13 is also again equal to a (and of course, r12 doesn't change in this case). Thus, we obtain U = 0.
81. (a) Clearly, the net voltage
V= is not zero for any finite value of x.
q 2q + 4o | x| 4o | d - x|
(b) The electric field cancels at a point between the charges: q 2q = 4o x2 4o (d - x)2 which has the solution: x = ( 2 - 1) d = 0.41 m.
82. (a) The potential on the surface is
4.0 10-6 C 8.99 109 q V= = 4 0 R 010 m . (b) The field just outside the sphere would be E= q 4 0 R 2 =
c
he
Nm2 C2
j = 3.6 10 V .
5
V 3.6 105 V = = 3.6 106 V m , R 010 m .
which would have exceeded 3.0 MV/m. So this situation cannot occur.
83. This can be approached more than one way, but the simplest is to observe that the net potential (using Eq. 24-27) due to q1 = +2e and q3 = 2e is zero at both the initial and final positions of the movable charge q2 = +5q. This implies that no work is necessary to effect its change of position, which, in turn, implies there is no resulting change in potential energy of the configuration. Hence, the ratio is unity.
84. We use Ex = dV/dx, where dV/dx is the local slope of the V vs. x curve depicted in Fig. 24-54. The results are: (a) Ex(ab) = 6.0 V/m, (b) Ex(bc) = 0, (c) Ex(cd) 3.0 V/m, (d) Ex(de) = 3.0 V/m, (e) Ex(ef) = 15 V/m, (f) Ex(fg) = 0, (g) Ex(gh) = 3.0 V/m. Since these values are constant during their respective time-intervals, their graph consists of several disconnected line-segments (horizontal) and is not shown here.
85. (a) We denote the surface charge density of the disk as 1 for 0 < r < R/2, and as 2 for R/2 < r < R. Thus the total charge on the disk is given by
q= = dq =
R 2 0
disk
2 1r dr +
R R 2
2 2 r dr =
2 ( 2.20 10-2 m ) 1.50 10-6 C m2 + 3 (8.00 10-7 C m2 ) 4 = 1.48 10-9 C .
2 R ( 1 + 3 2 ) 4
(b) We use Eq. 24-36:
V z =
bg
z
disk
dV = k
LM Nz
R2
1 2 R dR
z2 + R2
b
g
0
+
z
R
2 2 R dR
2 2 2
R2
= 1 2 0
F GH
R2 z + -z + 2 4 2 0
2
I JK
F GH
z +R -
2 2
g OP z + R Q R I z + . 4 J K b
2
Substituting the numerical values of 1, 2, R and z, we obtain V(z) = 7.95 102 V.
86. The net potential (at point A or B) is computed using Eq. 24-27. Thus, using k for 1/40, the difference is VA - VB = ke k ( -5e ) ke k ( -5e ) 2ke 2(8.99 109 )(1.6 10-19 ) + - + = = = 5.14 10-4 V. -6 d 5d 2d 2d d 5.60 10
87. We denote q = 25 109 C, y = 0.6 m, x = 0.8 m, with V = the net potential (assuming V 0 as r ). Then, VA = VB = leads to
VB - V A = q 2 q 2 q 1 1 - = - 4 0 x 4 0 y 2 0 x y
1 q 1 -q + 4 0 y 4 0 x 1 q 1 -q + 4 0 x 4 0 y
b g
b g
FG H
IJ K
which yields V = -187V.
88. In the "inside" region between the plates, the individual fields (given by Eq. 24-13) are in the same direction ( - i ): Ein = -
FG 50 10 H 2
0
-9
+
25 10-9 i = -4.2 103 i 2 0
IJ K
in SI units (N/C or V/m). And in the "outside" region where x > 0.5 m, the individual fields point in opposite directions: Eout = - 50 10-9 25 10-9 i+ i = -14 103 i . . 2 0 2 0
Therefore, by Eq. 24-18, we have
V = -
0.8 0
E ds = -
0.5 0
E dx -
in
0.8 0.5
E
out
dx = - ( 4.2 103 ) ( 0.5 ) - (1.4 103 ) ( 0.3)
= 2.5 103 V.
89. (a) The charges are equal and are the same distance from C. We use the Pythagorean theorem to find the distance r =
bd 2 g + bd 2 g
2
2
=d
2 . The electric potential at C is
the sum of the potential due to the individual charges but since they produce the same potential, it is twice that of either one:
9 2 2 -6 2q 2 2 2q ( 8.99 10 N m C ) ( 2 ) 2 ( 2.0 10 C ) = = = 2.5 106 V. V= 4 0 d 4 0 d 0.020 m
(b) As you move the charge into position from far away the potential energy changes from zero to qV, where V is the electric potential at the final location of the charge. The change in the potential energy equals the work you must do to bring the charge in:
W = qV = ( 2.0 10-6 C )( 2.54 106 V ) = 5.1 J.
(c) The work calculated in part (b) represents the potential energy of the interactions between the charge brought in from infinity and the other two charges. To find the total potential energy of the three-charge system you must add the potential energy of the interaction between the fixed charges. Their separation is d so this potential energy is q 2 4 0 d . The total potential energy is
(8.99 109 N m2 C2 )( 2.0 10-6 C ) = 6.9 J. q2 U =W + = 5.1 J + 4 0 d 0.020 m
2
90. The potential energy of the two-charge system is N m2 8.9910 C2
9
U=
1 4 0
q1q2
( x1 - x2 ) + ( y1 - y2 )
2
2
=
( 3.00 10 C )( -4.00 10 C )
-6 -6
( 3.50 + 2.00 ) + ( 0.500 - 1.50 )
2
2
cm
= -1.93 J. Thus, 1.93 J of work is needed.
91. For a point on the axis of the ring the potential (assuming V 0 as r ) is V= q 4 0 z 2 + R 2
where q = 16 106 C and R = 0.0300 m. Therefore, VB - V A = q 4 0
F GH
1
2 zB + R 2
-
1 R
I JK
where zB = 0.040 m. The result is 1.92 106 V.
1 92. The initial speed vi of the electron satisfies Ki = 2 me vi2 = eV , which gives
2 160 10-19 J 625 V . 2eV . vi = = = 148 107 m s. -31 9.11 10 kg me
c
hb
g
93. (a) The potential energy is
8.99 109 N m2 C 2 5.0 10-6 C q2 U= = . 4 0 d 100 m relative to the potential energy at infinite separation.
c
hc
h
2
= 0.225 J
(b) Each sphere repels the other with a force that has magnitude
8.99 109 N m2 C 2 5.0 10-6 C q2 F= = 2 4 0 d 2 1.00 m
c
b
hc g
h
2
= 0.225 N.
According to Newton's second law the acceleration of each sphere is the force divided by the mass of the sphere. Let mA and mB be the masses of the spheres. The acceleration of sphere A is
aA = 0.225 N F = = 45.0 m s2 -3 mA 5.0 10 kg
and the acceleration of sphere B is
aB = 0.225 N F = = 22.5 m s2 . -3 mB 10 10 kg
(c) Energy is conserved. The initial potential energy is U = 0.225 J, as calculated in part (a). The initial kinetic energy is zero since the spheres start from rest. The final potential energy is zero since the spheres are then far apart. The final kinetic energy is 2 2 1 1 2 m A v A + 2 mB v B , where vA and vB are the final velocities. Thus,
U= 1 1 2 mA v 2 + mB v B . A 2 2
Momentum is also conserved, so
0 = mA v A + mB v B .
These equations may be solved simultaneously for vA and vB. Substituting vB = -(mA / mB )v A , from the momentum equation into the energy equation, and collecting
1 terms, we obtain U = 2 (mA / mB )(mA + mB )v 2 . Thus, A
vA =
2UmB 2(0.225 J)(10 10-3 kg) = = 7.75 m/s. mA (mA + mB ) (5.0 10-3 kg)(5.0 10-3 kg + 10 10-3 kg)
We thus obtain vB = - or | vB |= 3.87 m/s. mA vA = - mB 5.0 10-3 kg (7.75 m/s) = -3.87 m/s, 10 10-3 kg
94. The particle with charge q has both potential and kinetic energy, and both of these change when the radius of the orbit is changed. We first find an expression for the total energy in terms of the orbit radius r. Q provides the centripetal force required for q to move in uniform circular motion. The magnitude of the force is F = Qq/40r2. The acceleration of q is v2/r, where v is its speed. Newton's second law yields mv 2 = r 4 0 r 2 Qq mv 2 = Qq , 4 0 r
1 and the kinetic energy is K = 2 mv 2 = Qq 8 0r . The potential energy is U = Qq/40r, and the total energy is
E = K +U =
Qq Qq Qq - =- . 8 0 r 4 0 r 8 0 r
When the orbit radius is r1 the energy is E1 = Qq/80r1 and when it is r2 the energy is E2 = Qq/80r2. The difference E2 E1 is the work W done by an external agent to change the radius: W = E2 - E1 = - Qq 1 1 Qq 1 1 - = - . 8 0 r2 r1 8 0 r1 r2
FG H
IJ K
FG H
IJ K
95. (a) The total electric potential energy consists of three equal terms: U= q1 q2 q2 q3 q1 q3 + + 4o r 4o r 4o r
e where q1 = q2 = q3 = - 3 , and r as given in the problem. The result is U = 2.72 10-14 J. (b) Dividing by the square of the speed of light (roughly 3.0 108 m/s), we obtain a value in kilograms (about a third of the correct electron mass value): 3.02 10-31 kg.
96. A positive charge q is a distance r d from P, another positive charge q is a distance r from P, and a negative charge q is a distance r + d from P. Sum the individual electric potentials created at P to find the total: V= q 1 1 1 + - . 4 0 r - d r r + d
LM N
OP Q
We use the binomial theorem to approximate 1/(r d) for r much larger than d:
1 1 d = ( r - d ) - 1 ( r ) -1 - ( r ) -2 ( - d ) = + 2 . r-d r r
Similarly,
1 1 d - 2. r+d r r
Only the first two terms of each expansion were retained. Thus, V q 1 d 1 1 d q q 1 2d 2d + 2+ - + 2 = + 2 = . 1+ r r r r 4 0 r r 4 0 r r 4 0 r
LM N
OP Q
LM N
OP Q
LM N
OP Q
97. Assume the charge on Earth is distributed with spherical symmetry. If the electric potential is zero at infinity then at the surface of Earth it is V = q/40R, where q is the charge on Earth and R = 6.37 106 m is the radius of Earth. The magnitude of the electric field at the surface is E = q/40R2, so V = ER = (100 V/m) (6.37 106 m) = 6.4 108 V.
98. The net electric potential at point P is the sum of those due to the six charges:
6 6
VP =
VPi =
qi 4 0 ri
=
i =1
i =1
10-15 4 0
5.00 d + ( d / 2)
2 2
+
-2.00 -3.00 + 2 2 d /2 d + ( d / 2)
+
3.00 d 2 + ( d / 2)
2
+
9.4 10-16 -2.00 +5.00 + = = 3.34 10-4 V. -2 2 2 d /2 4 0 (2.54 10 ) d + ( d / 2)
99. In the sketches shown next, the lines with the arrows are field lines and those without are the equipotentials (which become more circular the closer one gets to the individual charges). In all pictures, q2 is on the left and q1 is on the right (which is reversed from the way it is shown in the textbook). (a)
(b)
100. (a) We use Gauss' law to find expressions for the electric field inside and outside the spherical charge distribution. Since the field is radial the electric potential can be written as an integral of the field along a sphere radius, extended to infinity. Since different expressions for the field apply in different regions the integral must be split into two parts, one from infinity to the surface of the distribution and one from the surface to a point inside. Outside the charge distribution the magnitude of the field is E = q/40r2 and the potential is V = q/40r, where r is the distance from the center of the distribution. This is the same as the field and potential of a point charge at the center of the spherical distribution. To find an expression for the magnitude of the field inside the charge distribution, we use a Gaussian surface in the form of a sphere with radius r, concentric with the distribution. The field is normal to the Gaussian surface and its magnitude is uniform over it, so the electric flux through the surface is 4r2E. The charge enclosed is qr3/R3. Gauss' law becomes qr 3 4 0 r E = 3 , R
2
so
E= qr . 4 0 R 3
If Vs is the potential at the surface of the distribution (r = R) then the potential at a point inside, a distance r from the center, is V = Vs -
z
r
R
E dr = Vs -
q 4 0 R 3
z
r
R
r dr = Vs -
qr 2 q + . 3 8 0 R 8 0 R
The potential at the surface can be found by replacing r with R in the expression for the potential at points outside the distribution. It is Vs = q/40R. Thus, V= q 1 r2 1 q - + = 3R 2 - r 2 . 3 3 4 0 R 2 R 2 R 8 0 R
LM N
OP Q
c
h
(b) The potential difference is
V = Vs - Vc = 2q 3q q - =- , 8 0 R 8 0 R 8 0 R
or | V |= q / 8 0 R .
101. (a) For r > r2 the field is like that of a point charge and
V= 1 Q , 4 0 r
where the zero of potential was taken to be at infinity. (b) To find the potential in the region r1 < r < r2, first use Gauss's law to find an expression for the electric field, then integrate along a radial path from r2 to r. The Gaussian surface is a sphere of radius r, concentric with the shell. The field is radial and therefore normal to the surface. Its magnitude is uniform over the surface, so the flux through the surface is = 4r2E. The volume of the shell is 4 3 r23 - r13 , so the
b
gc
h
charge density is
=
3Q , 4 r23 - r13
c
h
and the charge enclosed by the Gaussian surface is q= Gauss' law yields
4 0r 2 E = Q
FG 4 IJ cr H 3K
FG r Hr
3
3
- r13 = Q
h
FG r Hr
- r13 . 3 3 2 -r 1
3
IJ K
- r13 3 3 2 -r 1
IJ K
E=
Q r 3 - r13 . 4 0 r 2 r23 - r13
c
h
If Vs is the electric potential at the outer surface of the shell (r = r2) then the potential a distance r from the center is given by
V = Vs -
z
r
r2
E dr = Vs -
Q 1 = Vs - 3 4 0 r2 - r13
z FGH r - rr IJK dr FG r - r + r - r IJ . H2 2 r rK
Q 1 3 4 0 r2 - r13
2 2 2 3 1 r r2 3 1 2 3 1 2
The potential at the outer surface is found by placing r = r2 in the expression found in part (a). It is Vs = Q/40r2. We make this substitution and collect terms to find
V=
Q 1 3r22 r 2 r13 - - . 4 0 r23 - r13 2 2 r
FG H
IJ K
Since = 3Q 4 r23 - r13 this can also be written V=
c
h
3r22 r 2 r13 - - . 3 0 2 2 r
FG H
IJ K
(c) The electric field vanishes in the cavity, so the potential is everywhere the same inside and has the same value as at a point on the inside surface of the shell. We put r = r1 in the result of part (b). After collecting terms the result is
2 2 Q 3 r2 - r1 V= , 4 0 2 r23 - r13
c c
h h
or in terms of the charge density V =
2 2 r2 - r1 . 2 0
c
h
(d) The solutions agree at r = r1 and at r = r2.
102. The distance r being looked for is that where the alpha particle has (momentarily) zero kinetic energy. Thus, energy conservation leads to K0 + U0 = K + U (0.48 10-12 J) + (2e)(92e) (2e)(92e) = 0 + . 40 r0 40 r
If we set r0 = (so U0 = 0) then we obtain r = 8.8 10-14 m.
103. (a) The net potential is
V = V1 + V2 =
q1 q2 + 4o r1 4o r2
where r1 = x2 + y2 and r2 = (x- d)2 + y2. The distance d is 8.6 nm. To find the locus of points resulting in V = 0, we set V1 equal to the (absolute value of) V2 and square both sides. After simplifying and rearranging we arrive at an equation for a circle: 9d y2 + x + 16
2
225 = 256 d 2 .
From this form, we recognize that the center of the circle is 9d/16 = 4.8 nm. (b) Also from this form, we identify the radius as the square root of the right-hand side: R = 15d/16 = 8.1 nm. (c) If one uses a graphing program with "implicitplot" features, it is certainly possible to set V = 5 volts in the expression (shown in part (a)) and find its (or one of its) equipotential curves in the xy plane. In fact, it will look very much like a circle. Algebraically, attempts to put the expression into any standard form for a circle will fail, but that can be a frustrating endeavor. Perhaps the easiest way to show that it is not truly a circle is to find where its "horizontal diameter" Dx and its "vertical diameter" Dy (not hard to do); we find Dx = 2.582 nm and Dy = 2.598 nm. The fact that Dx Dy is evidence that it is not a true circle.
104. The electric field (along the radial axis) is the (negative of the) derivative of the
voltage with respect to r. There are no other components of E in this case, so (noting that the derivative of a constant is zero) we conclude that the magnitude of the field is dV Ze d r -1 1 d r2 E = - dr = - + 0 + 2R3 dr 4o dr = Ze 1 r 2- 3 R 4o r
for r R. This agrees with the Rutherford field expression shown in exercise 37 (in the textbook). We note that he has designed his voltage expression to be zero at r = R. Since the zero point for the voltage of this system (in an otherwise empty space) is arbitrary, then choosing V = 0 at r = R is certainly permissible.
105. If the electric potential is zero at infinity then at the surface of a uniformly charged sphere it is V = q/40R, where q is the charge on the sphere and R is the sphere radius. Thus q = 40RV and the number of electrons is
10 10-6 m 400 V . q 4 0 RV N= = = = 2.8 105 . 9 2 2 -19 e e 8.99 10 N m C 160 10 C .
c
c
hb hc
g
h
106. We imagine moving all the charges on the surface of the sphere to the center of the the sphere. Using Gauss' law, we see that this would not change the electric field outside the sphere. The magnitude of the electric field E of the uniformly charged sphere as a function of r, the distance from the center of the sphere, is thus given by E(r) = q/(40r2) for r > R. Here R is the radius of the sphere. Thus, the potential V at the surface of the sphere (where r = R) is given by V ( R) = V +
r =
R
E ( r ) dr =
R
8.99 109 NCm (1.50 108 C ) 2 q = dr = 2 4 0 r 4 0 R 0.160m
2
q
(
)
= 8.43 102 V.
107. On the dipole axis = 0 or , so |cos | = 1. Therefore, magnitude of the electric field is E r =-
bg
V p d 1 = 4 0 dr r 2 r
FG IJ = p H K 2 r
0
3
.
108. The potential difference is V = Es = (1.92 105 N/C)(0.0150 m) = 2.90 103 V.
109. (a) Using Eq. 24-26, we calculate the radius r of the sphere representing the 30 V equipotential surface:
r= q = 4.5 m. 4 0V
(b) If the potential were a linear function of r then it would have equally spaced equipotentials, but since V 1 r they are spaced more and more widely apart as r increases.
110. (a) Let the quark-quark separation be r. To "naturally" obtain the eV unit, we only plug in for one of the e values involved in the computation:
2e 3 r 2e 3 4 8.99 109
U up - up =
1 4 0
4ke = e= 9r
(1.60 10 9 (1.32 10 m )
-15
N m2 C2
-19
C) e
= 4.84 105 eV = 0.484 MeV.
(b) The total consists of all pair-wise terms: 1 U= 4 0
LM b gb g + b gb g + b gb g OP = 0. r r Q N r
2e 3 2e 3
-e 3
2e 3
-e 3
2e 3
111. (a) At the smallest center-to-center separation d p the initial kinetic energy Ki of the proton is entirely converted to the electric potential energy between the proton and the nucleus. Thus,
Ki = 1 eqlead 82e 2 = . 4 0 d p 4 0 d p
In solving for d p using the eV unit, we note that a factor of e cancels in the middle line:
2 82 1.6 10 -19 C ( ) 82e 2 82e 2 9 Nm dp = =k = 8.99 10 4 0 K i 4.80 106 eV C2 4.80 106 V
= 2.5 10-14 m = 25fm . It is worth recalling that a volt is a newtonmeter/coulomb, in making sense of the above manipulations. (b) An alpha particle has 2 protons (as well as 2 neutrons). Therefore, using rmin for the new separation, we find 1 q qlead 82e 2 82e 2 =2 = Ki = 4 0 d 4 0 d 4 0 d p which leads to d / d p = 2.00 .
112. (a) The potential would be
Ve = Qe 4 Re2 e = = 4 Re e k 4 0 Re 4 0 Re
. . = 4 6.37 10 6 m 10 electron m2 -16 10-9 C electron 8.99 109 . = -012 V. (b) The electric field is
E=
c
hc
hc
h FGH
N m2 C2
IJ K
e Ve 012 V . = =- = -18 10-8 N C , . 6 0 Re 6.37 10 m
or | E |= 1.8 10-8 N C. (c) The minus sign in E indicates that E is radially inward.
113. The electric potential energy is
U =k
i j
qi q j rij 1.3
=
9
qq q q 1 q1q2 + q1q3 + q2 q4 + q3 q4 + 1 4 + 2 3 4 0 d 2 2 (12)(-24) + (12)(31) + (-24)(17) + (31)(17) + (12)(17) (-24)(31) + (10-19 ) 2 2 2
(8.99 10 ) =
= -1.2 10-6 J.
114. (a) The charge on every part of the ring is the same distance from any point P on the axis. This distance is r = z 2 + R 2 , where R is the radius of the ring and z is the distance from the center of the ring to P. The electric potential at P is
V= 1 4 0
z
dq 1 = r 4 0
z
dq z2 + R2
=
1 4 0
1 z2 + R2
z
dq =
1 4 0
q z2 + R2
.
(b) The electric field is along the axis and its component is given by E=- V q 2 q 1 q z ( z + R 2 ) -1/ 2 = ( z 2 + R 2 ) -3/ 2 (2 z ) = . =- 2 4 0 z 4 0 2 4 0 ( z + R 2 )3/ 2 z
This agrees with Eq. 23-16.
115. From the previous chapter, we know that the radial field due to an infinite linesource is
E= 2 0 r
which integrates, using Eq. 24-18, to obtain Vi = V f + 2 0
z
rf
ri
rf dr = Vf + ln 2 0 r ri
FG IJ . H K
The subscripts i and f are somewhat arbitrary designations, and we let Vi = V be the potential of some point P at a distance ri = r from the wire and Vf = Vo be the potential along some reference axis (which intersects the plane of our figure, shown next, at the xy coordinate origin, placed midway between the bottom two line charges -- that is, the midpoint of the bottom side of the equilateral triangle) at a distance rf = a from each of the bottom wires (and a distance a 3 from the topmost wire). Thus, each side of the triangle is of length 2a. Skipping some steps, we arrive at an expression for the net potential created by the three wires (where we have set Vo = 0):
Vnet =
4 0
F F x + d y - a 3i I I K JJ G H lnG GH eb x + ag + y jeb x - ag + y jJK
2 2 2 2 2 2 2
which forms the basis of our contour plot shown below. On the same plot we have shown four electric field lines, which have been sketched (as opposed to rigorously calculated) and are not meant to be as accurate as the equipotentials. The 2 by the top wire in our figure should be 2 (the typo is an artifact of our plotting routine).
116. From the previous chapter, we know that the radial field due to an infinite linesource is
E= 2 0 r
which integrates, using Eq. 24-18, to obtain
Vi = V f +
2 0
z
rf
ri
rf dr = Vf + ln 2 0 r ri
FG IJ . H K
The subscripts i and f are somewhat arbitrary designations, and we let Vi = V be the potential of some point P at a distance ri = r from the wire and Vf = Vo be the potential along some reference axis (which will be the z axis described in this problem) at a distance rf = a from the wire. In the "end-view" presented here, the wires and the z axis appear as points as they intersect the xy plane. The potential due to the wire on the left (intersecting the plane at x = a) is
Vnegative wire = Vo
( - ) ln +
2 0
, x + a 2 + y2 ) ( a
and the potential due to the wire on the right (intersecting the plane at x = +a) is
Vpositive wire = Vo +
( + ) ln
2 0
. x - a 2 + y2 ) ( a
Since potential is a scalar quantity, the net potential at point P is the addition of V and V+ which simplifies to
ln 2 0
Vnet = 2V0 +
F GG H
F a GG H b x - ag + y
2
2
I F a JJ - lnGG K H b x + ag + y
2
2
I I F b x + ag + y I JJ JJ = 4 lnGH b x - ag + y JK KK
2 2 2 0 2
where we have set the potential along the z axis equal to zero (Vo = 0) in the last step (which we are free to do). This is the expression used to obtain the equipotentials shown next. The center dot in the figure is the intersection of the z axis with the xy plane, and the dots on either side are the intersections of the wires with the plane.
117. (a) With V = 1000 V, we solve V = q 4o R where R = 0.010 m
for the net charge on the sphere, and find q = 1.1 10-9 C. Dividing this by e yields 6.95 109 electrons that entered the copper sphere. Now, half of the 3.7 108 decays per second resulted in electrons entering the sphere, so the time required is 6.95 x 109 = 38 seconds. 1 8 2 (3.7 x 10 ) (b) We note that 100 keV is 1.6 10-14 J (per electron that entered the sphere). Using the given heat capacity, we note that a temperature increase of T = 5.0 K = 5.0 C required 71.5 J of energy. Dividing this by 1.6 10-14 J, we find the number of electrons needed to enter the sphere (in order to achieve that temperature change); since this is half the number of decays, we multiply to 2 and find N = 8.94 1015 decays. We divide N by 3.7 108 to obtain the number of seconds. Converting to days, this becomes roughly 280 days.
118. The (implicit) equation for the pair (x,y) in terms of a specific V is V= q2 q1 2 2 + 2 4o x + y 4o x + (y - d)2
where d = 0.50 m. The values of q1 and q2 are given in the problem. (a) We set V = 5.0 V and plotted (using MAPLE's implicit plotting routine) those points in the xy plane which (when plugged into the above expression for V) yield 5.0 volts. The result is
(b) In this case, the same procedure yields these two equipotential lines:
(c) One way to search for the "crossover" case (from a single equipotential line, to two) is to "solve" for a point on the y axis (chosen here to be an absolute distance below q1 that is, the point is at a negative value of y, specifically at y = -) in terms of V (or more conveniently, in terms of the parameter = 4oV x 1010). Thus, the above expression for V becomes simply
=
-12 +
25 . d+
This leads to a quadratic equation with the (formal) solution = 13 - d d2 2 + 169 - 74 d . 2
Clearly there is the possibility of having two solutions (implying two intersections of equipotential lines with the y axis) when the square root term is nonzero. This suggests that we explore the special case where the square root term is zero; that is, d2 2 + 169 - 74 d = 0 . Squaring both sides, using the fact that d = 0.50 m and recalling how we have defined the parameter , this leads to a "critical value" of the potential (corresponding to the crossover case, between one and two equipotentials): critical = 37 - 20 3 d Vcritical = critical = 4.2 V. 4o x 1010
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Ch.55 German Opera of the 19th Century: Weber & Wagner Singspiel play w/ singing; far more modest Carl Maria Von Weber 1786-1826 Friderich kind was librettist for Der Freischutz Romantic opera term used by Weber for certain of his operas and by W
Cal Poly Pomona - COM - 413
Man Kiu Chu COM 413 Mariusz Ozminkowski, Ph.D. 2:06 p.m. 3:40pm 10/10/07 "Though Letter"At each naturalization ceremony, every newly "naturalized" U.S. citizens have to declare if they are Democratic or Republican, etc. So it is very hard to be un
USC - POSC - 130g
Question 1: Is Galanter wrong? Galanter is right 1. same argument that Galanter made, RP's have relationships with judges, know the system, have more resources 2. you can't reform A-L, due to capture, the distrust of agencies, bargaining in the shado
Cal Poly Pomona - COM - 106
COM 106 Writing for Communication PractitionersEssay 1: Topic 50 pointsWe sometimes say or think: "There needs to be a change." About the 2008 presidential elections, we think: there needs to be a change in the way people vote. There needs to be a
USC - POSC - 130g
Nation of strangers o ID: idea that America is diverse and not close-knit o SIG: need for more A-L in America since we sue others more (not neighborneighbor); comparison of American courts to other nations with smaller, more homogeneous populations w
USC - BUAD - 304
CHAPTER 14 POWER AND POLITICS Formal power based on indiv position in org 1. coercive power dependent on fear; one reacts out of fear of the negative results that might occur if one failed to comply 2. reward power opposite of coercive; people co
USC - BUAD - 304
Leader as Sense Maker Biographical Features Age: older turnover less than younger, older are absent less Gender: women don't turnover/perform/etc. less than men; women absent more than men Tenure: the greater the tenure the more productive, happier,
USC - POSC - 130g
Essay Questions 1. When are courts most likely to be constrained/dynamic? CCV: Definition: courts are limited in ability to make a difference and thus "constrained" When: Basically when all forms of constraints are strong: Strong doctrinal constraint
USC - POSC - 130g
Part I: Identify and give significance of 3 of 5 terms and concepts, which will be selected from the following list: The logic of the triad o ID: Triadic relationship between the Courts and Litigants 1 and 2, propped up by consent (agreement by sides
Cal Poly Pomona - COM - 413
Man Kiu Chu COM 413 Maurisz Ozminkowski, Ph.D. 2:06 p.m. 3:40 p.m. 10/07/07 Propaganda Example: MUFON (Mutual UFO Network) The propaganda example I am using is the Mutual UFO Network of United States. From reporting of the latest daily sightings to
Cal Poly Pomona - COM - 413
PUBLIC OPINION Definitional preliminaries Measurements Formation Ideological differences in the U.S.What constitutes a "public"? a group of people who are confronted by an issue who are divided in the ideas as how to meet the issue who
Cal Poly Pomona - COM - 260
Com260:Access to Places and InformationPower Point Presentations for Cal Poly Pomona COM 260 Based on J.D. Zelezny's "Communications Law" Copyright 2006 by Mariusz Ozminkowski For permission to use email mozminkowski@csupomona.eduThe First Amen
Binghamton - ENG - 117D
1The novel One flew Over The Cuckoo's Nest focuses on ideas of conformity and power distribution. The best and easiest way to achieve these two things in society is through Jeremy Bentham's idea and strategies involved with the Panopticon. Characte
Cal Poly Pomona - HIST - 370
In terms of their work force, American farmers and ranchers a. continued to use Indian laborers to work their lands b. hired Chinese immigrants d. relied on black workersThe Big Four included all of the following except a. Leland Stanford b. Collis
Binghamton - ENG - 117G
The Big Sleep's SignificanceThe Big Sleep by Raymond Chandler contains many symbols and themes that are socially, culturally, and historically significant in real life. Much of the novel is focused around the demand for money and the countless acti
Cal Poly Pomona - HIST - 370
What event greatly contributed to California's increasing importance in world trade? the opening of the Suez Canal the opening of the Panama Canal the international exposition held in Los Angeles in 1915 all of the above Which of the following statem
USC - ANTH - 200Lg
ANTH Exam 1 ReviewEvolution9/26/2007 8:56:00 PMGradual change over time Change in gene allele frequencies over generations Framework used to explain the origin of adaptations Mechanisms: o Mutation o Gene flow o Genetic drift o Natural selection
Cal Poly Pomona - HIST - 370
What has been the result of extensive water development in California? a. It has augmented the power of both state and local governments. b. It has tendedto favor large-scale commercial farming over small family farms. c. It has intensified political
Cal Poly Pomona - HIST - 370
The foreigners who arrived in California in the late 1840s could best be described as a. people who came mostly in families or as part of communities and, as aresult, were unwilling to assimilate into Californio society b. mainly single men who often
Binghamton - ENG - 117G
Real Life Significance of "The Birds" In the short story ,The Birds" by Daphne du Maurier, there are many symbols and events which closely resemble society in Britain during this time period. Many aspects of the story are socially, politically, and t
Binghamton - ENG - 117D
Foucault begins his story by describing the seventeenth century plaque. He tells how houses were closed off, there was separation, inspection, and how things were quarantined. From this, concepts of power and discipline were created. Since that time,
USC - HIST - 200gm
American Midterm ReviewPart I Essay Question 1: Please characterize the changes in American politics and the American economy from the beginning of the 19th century through the 1828 election of Andrew Jackson. What were these changes, and how did t
USC - HIST - 200gm
History midterm PART I Essay #1 Major changes within political party system with both the rise of new parties and division amongst them. 1800 Thomas Jefferson elected president Jefferson and Burr tied in the electoral college so the vote went to the
USC - ECON - 205
REVIEW FOR MACRO MIDTERM #1 CH 1 Economics study of how people use their scarce resources to satisfy their unlimited wants Scarcity amount people desire exceeds amount available, not freely available Unlimited wants people can want virtually anyth
USC - BUAD - 310
Brandon Lang December 11, 2007 Mon/Wed 4-6 BUAD 310 Case Study 1. a. The histograms for the cost of an ad and the circulation are skewed to the right and unimodal. The histogram for median income appears to be fairly normal with no skewness. The hist
USC - ANTH - 200Lg
ANTH 200Lg: The Origins of Humanity Chapters 5-9, AE 10-13). http:/www.wwnorton.com/web/evolve/ Heterodontism -having different kinds of teeth for different functions -canines, incisors, premolars, molars Reasoning by analogy / homology -homology: lo
USC - ANTH - 200Lg
FINAL EXAM: Thursday, 13 Dec 2007, 2:00 4:00pmReview Questions for Exam #3 (the FINAL) The FINAL exam will be mixed format and non-cumulative. You are responsible for both lecture and material from the text (see below). Also take advantage of your
Binghamton - ENG - 117G
Rashomon / In a Grove Significance The story of Rashomon by Ryunosuke Akutagawa is very socially and culturally significant in both 1950's society and even today. Many themes and symbols in the short story are to be understood and seen in everyday li
USC - ECON - 205
Midterm #2 Review CH 6 Productivity ratio of total output to a specific measure of input Economy grows because of greater availability of resources, an improvement in the quality of resources, technological change that makes better use of resources,
USC - ECON - 205
FINAL REVIEW GUIDE CH 9 Investment spending on (1) new factories, office buildings, equipment, etc.; (2) new housing; and (3) net increases to inventories Investment and interest firm will invest in any project with a rate of return that exceeds th
USC - HIST - 200gm
History Final Exam Review Part 1 The Know Nothing Party The party was created out of a nativist movement in the 1850s as a result of fears that cities were becoming overwhelmed with Irish Catholics who took American jobs and threatened American value
Cal Poly Pomona - HIST - 370
The most popular demand of women's groups in California was the right to a. vote b. run for public office c. own property d. divorce The last decades of the 19th century are known as the gilded age because a. it was an era of technological advancemen
Cornell - ORIE - 350
Feb 27, 2008 4) Teledyne Dist. Sell 4 warehouses for $900,000 Lease them backWarehouse 950,000 950,000 0 Accum Dep 350,000 350,000 0Show Sale Account Dr Cr. Dec 31, 2004 Cash (A) 900,000 Accum Dep. (xA) 350,000 Warehouses 950,000 Deferred Gain 300
Cornell - S&TS - 2011
What do scientists do most in the lab? Observe? Experiment? Theorize? Read and write? (paper work?) Scientists are literary reasoners (Bruno Latour). They read and write lab notes, scientific papers, grant applications, data tables, and charts. They
Cornell - AEM - 2200
Lecture 1 (1.21.08) Social changes: 1750-1914 Increase in Population o Better nutrition o Medicine and hygiene o Potential mass markets Increase in knowledge o Scientific Revolution o Industrial Revolution o Global trade Political changes o Increase
Cornell - ORIE - 350
Feb 20, 2008 BOND EQUATION PV = A[(1-(1+i)^(-n) / i ] + FV/(1+i)^n Interest payments Face value payment PV equal to cash received N = number of 6 month periods FV = face value of bond i = 6 month interest rate And yield = 2; A = [face interest rate]
Cornell - S&TS - 2011
The Golem Ch 2: Theory of Relativity: mass and energy should be interchangeable. Time, mass, and length are not fixed but are relative to the speed at which things move. - Michelson-Morley ,aether-drift experiment of the 1880s o Showed that light tra
Cal Poly Pomona - BIO - 110
Evolution: Getting from There to HereThe word "evolution" refers to how an entity changes through time Darwin initially used the phrase "descent with modification" to explain the concept of evolution The concept of evolution helps explain the great
Penn State - PSYCH - 100
Chapter 1 The Earth -crust, mantle, core most of the earth is igneous molten material Crust - The continental crust Granite coarse, more siliet Andesite near volcanos in the Andes Mountains -Thicker crust, float (floats higher, is less dense and th