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YF_ISM_25
Course: MAE 162D, Spring 2012School: UCLA
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RESISTANCE, CURRENT, AND ELECTROMOTIVE FORCE 25 25.1. 25.2. IDENTIFY: I = Q / t . SET UP: 1.0 h = 3600 s EXECUTE: Q = It = (3.6 A)(3.0)(3600 s) = 3.89 104 C. EVALUATE: Compared to typical charges of objects in electrostatics, this is a huge amount of charge. IDENTIFY: I = Q / t . Use I = n q vd A to calculate the drift velocity vd . SET UP: EXECUTE: n = 5.8 1028 m -3 . q = 1.60 10-19 C . (a) I = 420 C Q =...
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RESISTANCE, CURRENT, AND ELECTROMOTIVE FORCE
25
25.1.
25.2.
IDENTIFY: I = Q / t . SET UP: 1.0 h = 3600 s EXECUTE: Q = It = (3.6 A)(3.0)(3600 s) = 3.89 104 C. EVALUATE: Compared to typical charges of objects in electrostatics, this is a huge amount of charge. IDENTIFY: I = Q / t . Use I = n q vd A to calculate the drift velocity vd . SET UP: EXECUTE:
n = 5.8 1028 m -3 .
q = 1.60 10-19 C .
(a) I =
420 C Q = = 8.75 10-2 A. t 80(60 s)
I 8.75 10-2 A = = 1.78 10-6 m s. 28 nqA (5.8 10 )(1.60 10-19 C)( (1.3 10-3 m) 2 )
(b) I = n q vd A. This gives vd = EVALUATE: 25.3. IDENTIFY: SET UP: EXECUTE: (b) J = (c) vd =
vd is smaller than in Example 25.1, because I is smaller in this problem.
I = Q / t . J = I / A . J = n q vd
A = ( / 4) D 2 , with D = 2.05 10 -3 m . The charge of an electron has magnitude +e = 1.60 10-19 C.
(a) Q = It = (5.00 A)(1.00 s) = 5.00 C. The number of electrons is
Q = 3.12 1019. e
I 5.00 A = = 1.51 106 A/m 2 . ( / 4) D 2 ( / 4)(2.05 10 -3 m) 2 J 1.51 106 A/m 2 = = 1.11 10 -4 m/s = 0.111 mm/s. n q (8.5 10 28 m -3 )(1.60 10-19 C)
25.4.
25.5.
EVALUATE: (a) If I is the same, J = I / A would decrease and vd would decrease. The number of electrons passing through the light bulb in 1.00 s would not change. (a) IDENTIFY: By definition, J = I/A and radius is one-half the diameter. SET UP: Solve for the current: I = JA = J (D/2)2 EXECUTE: I = (1.50 106 A/m2)()[(0.00102 m)/2]2 = 1.23 A EVALUATE: This is a realistic current. (b) IDENTIFY: The current density is J = nqvd SET UP: Solve for the drift velocity: vd = J/nq EXECUTE: Since most laboratory wire is copper, we use the value of n for copper, giving vd = (1.50 106 A/m 2 ) /[(8.5 1028 el/m3)(1.60 10 -19 C) = 1.1 10 -4 m/s = 0.11 mm/s EVALUATE: This is a typical drift velocity for ordinary currents and wires. IDENTIFY and SET UP: Use Eq. (25.3) to calculate the drift speed and then use that to find the time to travel the length of the wire. EXECUTE: (a) Calculate the drift speed vd :
J=
vd =
I I 4.85 A = 2= = 1.469 106 A/m 2 2 A r (1.025 10-3 m )
J 1.469 106 A/m 2 = = 1.079 10-4 m/s n q ( 8.5 10 28 / m3 )(1.602 10-19 C )
t=
L 0.710 m = = 6.58 103 s = 110 min. vd 1.079 10 -4 m/s
25-1
25-2
Chapter 25
(b) vd =
I
r 2n q
t=
2 L r n q L = vd I
t is proportional to r 2 and hence to d 2 where d = 2r is the wire diameter.
4.12 mm 4 t = ( 6.58 103 s ) = 2.66 10 s = 440 min. 2.05 mm (c) EVALUATE: The drift speed is proportional to the current density and therefore it is inversely proportional to the square of the diameter of the wire. Increasing the diameter by some factor decreases the drift speed by the square of that factor. IDENTIFY: The number of moles of copper atoms is the mass of 1.00 m 3 divided by the atomic mass of copper. There are N A = 6.023 1023 atoms per mole.
SET UP:
2
25.6.
The atomic mass of copper is 63.55 g mole, and its density is 8.96 g cm3 . Example 25.1 says there are
8.5 1028 free electrons per m3 . EXECUTE: The number of copper atoms in 1.00 m 3 is (8.96 g cm3 )(1.00 106 cm3 m3 )(6.023 1023 atoms mole) = 8.49 1028 atoms m3 . 63.55 g mole
25.7.
EVALUATE: Since there are the same number of free electrons m 3 as there are atoms of copper m 3 , the number of free electrons per copper atom is one. IDENTIFY and SET UP: Apply Eq. (25.1) to find the charge dQ in time dt. Integrate to find the total charge in the whole time interval. EXECUTE: (a) dQ = I dt
Q=
8.0 s 0
(55 A - ( 0.65 A / s ) t ) dt = (55 A ) t - ( 0.217 A / s ) t
2 2 2 3
2
8.0 s 0
Q = ( 55 A )( 8.0 s ) - ( 0.217 A / s
(b) I =
) (8.0 s )
3
= 330 C
25.8.
Q 330 C = = 41 A t 8.0 s EVALUATE: The current decreases from 55 A to 13.4 A during the interval. The decrease is not linear and the average current is not equal to (55A + 13.4 A) / 2. IDENTIFY: I = Q / t . Positive charge flowing in one direction is equivalent to negative charge flowing in the opposite direction, so the two currents due to Cl- and Na + are in the same direction and add. SET UP: Na + and Cl- each have magnitude of charge q = + e
EXECUTE: (a) Qtotal = ( nCl + nNa )e = (3.92 1016 + 2.68 1016 )(1.60 10 -19 C) = 0.0106 C. Then
I=
Qtotal 0.0106 C = = 0.0106A = 10.6 mA. t 1.00 s
25.9.
(b) Current flows, by convention, in the direction of positive charge. Thus, current flows with Na + toward the negative electrode. EVALUATE: The Cl- ions have negative charge and move in the direction opposite to the conventional current direction. IDENTIFY: The number of moles of silver atoms is the mass of 1.00 m 3 divided by the atomic mass of silver. There are N A = 6.023 1023 atoms per mole. SET UP: EXECUTE:
For silver, density = 10.5 103 kg/m3 and the atomic mass is M = 107.868 10-3 kg/mol. Consider 1 m3 of silver. m = (density)V = 10.5 103 kg .
n = m M = 9.734 104 mol and the
number of atoms is N = nN A = 5.86 1028 atoms . If there is one free electron per atom, there are
5.86 10 28 free electrons m3 . This agrees with the value given in Exercise 25.2. EVALUATE: Our result verifies that for silver there is approximately one free electron per atom. Exercise 25.6 showed that for copper there is also one free electron per atom. (a) IDENTIFY: Start with the definition of resisitivity and solve for E. SET UP: E = J = I/r2 EXECUTE: E = (1.72 10 -8 m)(2.75 A)/[(0.001025 m)2] = 1.43 10 -2 V/m
25.10.
Current, Resistance, and Electromotive Force
25-3
25.11.
25.12.
EVALUATE: The field is quite weak, since the potential would drop only a volt in 70 m of wire. (b) IDENTIFY: Take the ratio of the field in silver to the field in copper. SET UP: Take the ratio and solve for the field in silver: ES = EC(S/C) EXECUTE: ES = (0.0143 V/m)[(1.47)/(1.72)] = 1.22 10 -2 V/m EVALUATE: Since silver is a better conductor than copper, the field in silver is smaller than the field in copper. IDENTIFY: First use Ohm's law to find the resistance at 20.0C; then calculate the resistivity from the resistance. Finally use the dependence of resistance on temperature to calculate the temperature coefficient of resistance. SET UP: Ohm's law is R = V/I, R = L/A, R = R0[1 + (T T0)], and the radius is one-half the diameter. EXECUTE: (a) At 20.0C, R = V/I = (15.0 V)/(18.5 A) = 0.811 . Using R = L/A and solving for gives = RA/L = R (D/2)2/L = (0.811 ) [(0.00500 m)/2]2/(1.50 m) = 1.06 10 -6 m. (b) At 92.0C, R = V/I = (15.0 V)/(17.2 A) = 0.872 . Using R = R0[1 + (T T0)] with T0 taken as 20.0C, we have 0.872 = (0.811 )[1 + (92.0C 20.0C)]. This gives = 0.00105 (C) -1 EVALUATE: The results are typical of ordinary metals. IDENTIFY: E = J , where J = I / A . The drift velocity is given by I = n q vd A. SET UP: EXECUTE:
For copper, = 1.72 10-8 m . n = 8.5 10 28 / m3 . 3.6 A (a) J = I = = 6.81 105 A/m 2 . A (2.3 10-3 m) 2
25.13.
(b) E = J = (1.72 10 -8 m)(6.81 105 A/m 2 ) = 0.012 V m. (c) The time to travel the wire's length l is l ln q A (4.0 m)(8.5 1028 m3 )(1.6 10-19 C)(2.3 10-3 m) 2 t= = = = 8.0 104 s. vd I 3.6 A t = 1333 min 22 hrs! EVALUATE: The currents propagate very quickly along the wire but the individual electrons travel very slowly. IDENTIFY: E = J , where J = I / A. SET UP: EXECUTE:
For tungsten = 5.25 10-8 m and for aluminum = 2.75 10 -8 m.
(a) tungsten: E = J =
I
A
=
(5.25 10-8 m)(0.820 A) = 5.16 10-3 V m. ( 4)(3.26 10-3 m) 2
25.14.
(2.75 10-8 m)(0.820 A) = = 2.70 10-3 V m. (b) aluminum: E = J = A ( 4)(3.26 10-3 m) 2 EVALUATE: A larger electric field is required for tungsten, because it has a larger resistivity. IDENTIFY: The resistivity of the wire should identify what the material is. SET UP: R = L/A and the radius of the wire is half its diameter. EXECUTE: Solve for and substitute the numerical values. = 1.47 10 -8 m 6.50 m EVALUATE: This result is the same as the resistivity of silver, which implies that the material is silver. (a) IDENTIFY: Start with the definition of resistivity and use its dependence on temperature to find the electric field. I SET UP: E = J = 20 [1 + (T - T0 )] 2 r EXECUTE: E = (5.25 10 -8 m)[1 + (0.0045/ C )(120C 20C)](12.5 A)/[ (0.000500 m)2] = 1.21 V/m. (Note that the resistivity at 120C turns out to be 7.61 10 -8 m.) EVALUATE: This result is fairly large because tungsten has a larger resisitivity than copper. (b) IDENTIFY: Relate resistance and resistivity. SET UP: R = L/A = L/r2 EXECUTE: R = (7.61 10 -8 m)(0.150 m)/[(0.000500 m)2] = 0.0145 EVALUATE: Most metals have very low resistance. (c) IDENTIFY: The potential difference is proportional to the length of wire. SET UP: V = EL EXECUTE: V = (1.21 V/m)(0.150 m) = 0.182 V EVALUATE: We could also calculate V = IR = (12.5 A)(0.0145 ) = 0.181 V , in agreement with part (c).
I
25.15.
= AR / L = ( D / 2) R / L =
2
([0.00205 m]/2 ) (0.0290 )
2
25-4
Chapter 25
25.16.
25.17.
and solve for L. A SET UP: A = D 2 / 4 , where D = 0.462 mm . RA (1.00 )( 4)(0.462 10-3 m) 2 = = 9.75 m. EXECUTE: L = 1.72 10-8 m EVALUATE: The resistance is proportional to the length of the wire. L IDENTIFY: R = . A SET UP: For copper, = 1.72 10-8 m . A = r 2 . IDENTIFY:
Apply R =
L
25.18.
(1.72 10-8 m)(24.0 m) = 0.125 (1.025 10-3 m) 2 EVALUATE: The resistance is proportional to the length of the piece of wire. L L IDENTIFY: R = = . A d2 /4 SET UP: For aluminum, al = 2.63 10-8 m . For copper, c = 1.72 10-8 m.
EXECUTE:
R=
EXECUTE:
d
2
=
R c 1.72 10-8 m = constant , so al = c . d c = d al = (3.26 mm) = 2.64 mm. 2 2 4L d al d c al 2.63 10-8 m
25.19.
EVALUATE: Copper has a smaller resistivity, so the copper wire has a smaller diameter in order to have the same resistance as the aluminum wire. IDENTIFY and SET UP: Use Eq. (25.10) to calculate A. Find the volume of the wire and use the density to calculate the mass. EXECUTE: Find the volume of one of the wires: L L R= so A = and A R
volume = AL =
L2
R
=
(1.72 10
-8
m ) ( 3.50 m )
2
m = ( density )V = ( 8.9 103 kg/m3 )(1.686 10-6 m 3 ) = 15 g
25.20.
0.125
= 1.686 10-6 m3
The mass we calculated is reasonable for a wire. L IDENTIFY: R = . A SET UP: The length of the wire in the spring is the circumference d of each coil times the number of coils. EXECUTE: L = (75) d = (75) (3.50 10 -2 m) = 8.25 m.
EVALUATE:
A = r 2 = d 2 / 4 = (3.25 10-3 m) 2 / 4 = 8.30 10-6 m 2 .
25.21.
RA (1.74 )(8.30 10-6 m 2 ) = = 1.75 10-6 m. 8.25 m L EVALUATE: The value of we calculated is about a factor of 100 times larger than for copper. The metal of the spring is not a very good conductor. L IDENTIFY: R = . A SET UP: L = 1.80 m, the length of one side of the cube. A = L2 .
=
25.22.
2.75 10-8 m = 1.53 10-8 1.80 m A L2 L EVALUATE: The resistance is very small because A is very much larger than the typical value for a wire. IDENTIFY: Apply RT = R0 (1 + (T - T0 )).
EXECUTE:
R=
L
=
L
=
=
SET UP:
Since V = IR and V is the same,
RT I 20 = . For tungsten, = 4.5 10 -3 (C) -1. R20 IT
Current, Resistance, and Electromotive Force
25-5
EXECUTE:
The ratio of the current at 20C to that at the higher temperature is (0.860 A) (0.220 A) = 3.909.
RT = 1 + (T - T0 ) = 3.909 , where T0 = 20C. R20 3.909 - 1 = 666C. 4.5 10-3 (C) -1 EVALUATE: As the temperature increases, the resistance increases and for constant applied voltage the current decreases. The resistance increases by nearly a factor of four. IDENTIFY: Relate resistance to resistivity. SET UP: R = L/A EXECUTE: (a) R = L/A = (0.60 m)(0.25 m)/(0.12 m)2 = 10.4 (b) R = L/A = (0.60 m)(0.12 m)/(0.12 m)(0.25 m) = 2.4 EVALUATE: The resistance is greater for the faces that are farther apart. L IDENTIFY: Apply R = and V = IR . A SET UP: A = r 2 RA VA (4.50 V) (6.54 10-4 m) 2 = = = 1.37 10-7 m. EXECUTE: = L IL (17.6 A)(2.50 m) EVALUATE: Our result for shows that the wire is made of a metal with resistivity greater than that of good metallic conductors such as copper and aluminum. IDENTIFY and SET UP: Eq. (25.5) relates the electric field that is given to the current density. V = EL gives the potential difference across a length L of wire and Eq. (25.11) allows us to calculate R. EXECUTE: (a) Eq. (25.5): = E / J so J = E / T = T0 +
= 20C +
RT / R20 - 1
25.23.
25.24.
25.25.
From Table 25.1 the resistivity for gold is 2.44 10 -8 m. E 0.49 V/m J= = = 2.008 107 A/m 2 2.44 10-8 m
(b) V = EL = ( 0.49 V/m )( 6.4 m ) = 3.1 V
I = JA = J r 2 = ( 2.008 107 A/m 2 ) ( 0.4110-3 m ) = 11 A
2
(c) We can use Ohm's law (Eq. (25.11)): V = IR. V 3.1 V R= = = 0.28 I 11 A EVALUATE: We can also calculate R from the resistivity and the dimensions of the wire (Eq. 25.10):
R=
25.26.
L
A
=
L ( 2.44 10 m ) ( 6.4 m ) = = 0.28 , which checks. 2 r2 ( 0.42 10-3 m )
-8
IDENTIFY and SET UP: EXECUTE: (a) E =
Use V = EL to calculate E and then = E / J to calculate .
V 0.938 V = = 1.25 V/m L 0.750 m E 1.25 V/m (b) E = J so = = = 2.84 10-8 m J 4.40 107 A/m 2 EVALUATE: This value of is similar to that for the good metallic conductors in Table 25.1.
25.27. IDENTIFY: (a) SET UP: EXECUTE: (b) SET UP: EXECUTE:
Apply R = R0 1 + (T - T0 ) to calculate the resistance at the second temperature.
= 0.0004 ( C ) (Table 25.1). Let T0 be 0.0C and T be 11.5C.
-1
R0 =
100.0 R = = 99.54 1 + (T - T0 ) 1+ 0.0004 ( C )-1 (11.5 C )
(
)
= -0.0005 ( C )
-1
(Table 25.2). Let T0 = 0.0C and T = 25.8C.
R = R0 1 + (T - T0 ) = 0.0160 1+ -0.0005 ( C ) ( 25.8 C ) = 0.0158 EVALUATE: Nichrome, like most metallic conductors, has a positive and its resistance increases with temperature. For carbon, is negative and its resistance decreases as T increases.
-1
(
)
25-6
Chapter 25
25.28.
IDENTIFY: SET UP: EXECUTE:
RT = R0 [1 + (T - T0 )] R0 = 217.3 . RT = 215.8 . For carbon, = -0.00050 (C) -1. T - T0 = ( RT / R0 ) - 1 =
25.29.
25.30.
(215.8 / 217.3 ) - 1 = 13.8 C . T = 13.8 C + 4.0C = 17.8C. -0.00050 (C) -1 EVALUATE: For carbon, is negative so R decreases as T increases. L IDENTIFY and SET UP: Apply R = to determine the effect of increasing A and L. A EXECUTE: (a) If 120 strands of wire are placed side by side, we are effectively increasing the area of the current carrier by 120. So the resistance is smaller by that factor: R = (5.60 10-6 ) /120 = 4.67 10 -8 . (b) If 120 strands of wire are placed end to end, we are effectively increasing the length of the wire by 120, and so R = (5.60 10-6 )120 = 6.72 10-4 . EVALUATE: Placing the strands side by side decreases the resistance and placing them end to end increases the resistance. IDENTIFY: When the ohmmeter is connected between the opposite faces, the current flows along its length, but when the meter is connected between the inner and outer surfaces, the current flows radially outward. (a) SET UP: For a hollow cylinder, R = L/A, where A = (b2 a2).
(0.0460 m) 2 - (0.0320 m) 2
(b) SET UP:
25.31.
For radial current flow from r = a to r = b, R = (/2L) ln(b/a) (Example 25.4) 2.75 10 -8 m 4.60 cm -10 ln(b / a) = ln EXECUTE: R = = 6.35 10 2 L 2 (2.50 m) 3.20 cm EVALUATE: The resistance is much smaller for the radial flow because the current flows through a much smaller distance and the area through which it flows is much larger. L IDENTIFY: Use R = to calculate R and then apply V = IR . P = VI and energy = Pt A SET UP: For copper, = 1.72 10-8 m . A = r 2 , where r = 0.050 m. EXECUTE: (a) R =
L
A
=
(1.72 10-8 m)(100 103 m) = 0.219 . V = IR = (125 A)(0.219 ) = 27.4 V. (0.050 m) 2
25.32.
25.33.
25.34.
(b) P = VI = (27.4 V)(125 A) = 3422 W = 3422 J/s and energy = Pt = (3422 J/s)(3600 s) = 1.23 107 J. EVALUATE: The rate of electrical energy loss in the cable is large, over 3 kW. IDENTIFY: When current passes through a battery in the direction from the - terminal toward the + terminal, the terminal voltage Vab of the battery is Vab = E - Ir . Also, Vab = IR, the potential across the circuit resistor. SET UP: E = 24.0 V . I = 4.00 A. E - Vab 24.0 V - 21.2 V = = 0.700 . EXECUTE: (a) Vab = E - Ir gives r = I 4.00 A V 21.2 V = 5.30 . (b) Vab - IR = 0 so R = ab = I 4.00 A EVALUATE: The voltage drop across the internal resistance of the battery causes the terminal voltage of the 24.0 V battery to be less than its emf. The total resistance in the circuit is R + r = 6.00 . I = = 4.00 A, which 6.00 agrees with the value specified in the problem. IDENTIFY: V = E - Ir . SET UP: The graph gives V = 9.0 V when I = 0 and I = 2.0 A when V = 0. EXECUTE: (a) E is equal to the terminal voltage when the current is zero. From the graph, this is 9.0 V. (b) When the terminal voltage is zero, the potential drop across the internal resistance is just equal in magnitude to the internal emf, so rI = E , which gives r = E /I = (9.0 V)/(2.0 A) = 4.5 . EVALUATE: The terminal voltage decreases as the current through the battery increases. (a) IDENTIFY: The idealized ammeter has no resistance so there is no potential drop across it. Therefore it acts like a short circuit across the terminals of the battery and removes the 4.00- resistor from the circuit. Thus the only resistance in the circuit is the 2.00- internal resistance of the battery. SET UP: Use Ohm's law: I = E /r. EXECUTE: I = (10.0 V)/(2.00 ) = 5.00 A.
EXECUTE:
R = L / A =
( b2 - a 2 )
L
=
( 2.75 10
-8
m ) (2.50 m)
= 2.00 10 -5
Current, Resistance, and Electromotive Force
25-7
25.35.
25.36.
(b) The zero-resistance ammeter is in parallel with the 4.00- resistor, so all the current goes through the ammeter. If no current goes through the 4.00- resistor, the potential drop across it must be zero. (c) The terminal voltage is zero since there is no potential drop across the ammeter. EVALUATE: An ammeter should never be connected this way because it would seriously alter the circuit! IDENTIFY: The terminal voltage of the battery is Vab = E - Ir. The voltmeter reads the potential difference between its terminals. SET UP: An ideal voltmeter has infinite resistance. EXECUTE: (a) Since an ideal voltmeter has infinite resistance, so there would be NO current through the 2.0 resistor. (b) Vab = E = 5.0 V; since there is no current there is no voltage lost over the internal resistance. (c) The voltmeter reading is therefore 5.0 V since with no current flowing there is no voltage drop across either resistor. EVALUATE: This not the proper way to connect a voltmeter. If we wish to measure the terminal voltage of the battery in a circuit that does not include the voltmeter, then connect the voltmeter across the terminals of the battery. IDENTIFY: The sum of the potential changes around the circuit loop is zero. Potential decreases by IR when going through a resistor in the direction of the current and increases by E when passing through an emf in the direction from the - to + terminal. SET UP: The current is counterclockwise, because the 16 V battery determines the direction of current flow. EXECUTE: +16.0 V - 8.0 V - I (1.6 + 5.0 + 1.4 + 9.0 ) = 0 16.0 V - 8.0 V I= = 0.47 A 1.6 + 5.0 + 1.4 + 9.0 (b) Vb + 16.0 V - I (1.6 ) = Va , so Va - Vb = Vab = 16.0 V - (1.6 )(0.47 A) = 15.2 V. (c) Vc + 8.0 V + I (1.4 + 5.0 ) = Va so Vac = (5.0 )(0.47 A) + (1.4 )(0.47 A) + 8.0 V = 11.0 V. (d) The graph is sketched in Figure 25.36. EVALUATE: Vcb = (0.47 A)(9.0 ) = 4.2 V. The potential at point b is 15.2 V below the potential at point a and the potential at point c is 11.0 V below the potential at point a, so the potential of point c is 15.2 V - 11.0 V = 4.2 V above the potential of point b.
25.37.
Figure 25.36 IDENTIFY: The voltmeter reads the potential difference Vab between the terminals of the battery. SET UP: open circuit I = 0. The circuit is sketched in Figure 25.37a.
EXECUTE:
Figure 25.37a SET UP:
switch closed The circuit is sketched in Figure 35.37b. EXECUTE: Vab = E - Ir = 2.97 V E - 2.97 V r= I 3.08 V - 2.97 V r= = 0.067 1.65 A Figure 25.37b
Vab 2.97 V = = 1.80 . I 1.65 A EVALUATE: When current flows through the battery there is a voltage drop across its internal resistance and its terminal voltage V is less than its emf.
And Vab = IR so R =
Vab = E = 3.08 V
25-8
Chapter 25
25.38.
IDENTIFY: The sum of the potential changes around the loop is zero. SET UP: The voltmeter reads the IR voltage across the 9.0 resistor. The current in the circuit is counterclockwise because the 16 V battery determines the direction of the current flow. EXECUTE: (a) Vbc = 1.9 V gives I = Vbc Rbc = 1.9 V 9.0 = 0.21 A. (b) 16.0 V - 8.0 V = (1.6 + 9.0 + 1.4 + R )(0.21 A) and R =
5.48 V = 26.1 . 0.21 A
(c) The graph is sketched in Figure 25.38. EVALUATE: In Exercise 25.36 the current is 0.47 A. When the 5.0 resistor is replaced by the 26.1 resistor the current decreases to 0.21 A.
Figure 25.38 25.39. (a) IDENTIFY and SET UP: Assume that the current is clockwise. The circuit is sketched in Figure 25.39a.
Figure 25.39a
Add up the potential rises and drops as travel clockwise around the circuit. EXECUTE: 16.0 V - I (1.6 ) - I ( 9.0 ) + 8.0 V - I (1.4 ) - I ( 5.0 ) = 0 16.0 V + 8.0 V 24.0 V = = 1.41 A, clockwise 9.0 + 1.4 + 5.0 + 1.6 17.0 EVALUATE: The 16.0 V battery drives the current clockwise more strongly than the 8.0 V battery does in the opposite direction. (b) IDENTIFY and SET UP: Start at point a and travel through the battery to point b, keeping track of the potential changes. At point b the potential is Vb . I=
EXECUTE:
Va - Vb = -16.0 V + (1.41 A )(1.6 ) Va + 16.0 V - I (1.6 ) = Vb
Vab = -16.0 V + 2.3 V = -13.7 V (point a is at lower potential; it is the negative terminal) EVALUATE: Could also go counterclockwise from a to b: Va + (1.41 A )( 5.0 ) + (1.41 A )(1.4 ) - 8.0 V + (1.41 A )( 9.0 ) = Vb Vab = -13.7 V, which checks. (c) IDENTIFY and SET UP: State at point a and travel through the battery to point c, keeping track of the potential changes. EXECUTE: Va + 16.0 V - I (1.6 ) - I ( 9.0 ) = Vc
Va - Vc = -16.0 V + (1.41 A )(1.6 + 9.0 ) Va c = -16.0 V + 15.0 V = -1.0 V (point a is at lower potential than point c)
EVALUATE: Could also go counterclockwise from a to c: Va + (1.41 A )( 5.0 ) + (1.41 A )(1.4 ) - 8.0 V = Vc
Vac = -1.0 V, which checks.
Current, Resistance, and Electromotive Force
25-9
(d) Call the potential zero at point a. Travel clockwise around the circuit. The graph is sketched in Figure 25.39b.
Figure 25.39b 25.40.
Vab is a constant. I SET UP: (a) The graph is given in Figure 25.40a. EXECUTE: (b) No. The graph of Vab versus I is not a straight line so Thyrite does not obey Ohm's law. (c) The graph of R versus I is given in Figure 25.40b. R is not constant; it decreases as I increases. EVALUATE: Not all materials obey Ohm's law.
IDENTIFY:
Ohm's law says R =
Figure 25.40 25.41.
Vab is a constant. I SET UP: (a) The graph is given in Figure 25.41. EXECUTE: (b) The graph of Vab versus I is a straight line so Nichrome obeys Ohm's law. 15.52 V - 1.94 V (c) R is the slope of the graph in part (a). R = = 3.88 . 4.00 A - 0.50 A EVALUATE: Vab / I for every I gives the same result for R, R = 3.88 .
IDENTIFY:
Ohm's law says R =
Figure 25.41 25.42. IDENTIFY and SET UP: For a resistor, P = VI = V 2 / R and V = IR. V 2 (15.0 V) 2 = = 0.688 EXECUTE: (a) R = P 327 W V 15.0 V (b) I = = = 21.8 A R 0.688 P 327 W EVALUATE: We could also write P = VI to calculate I = = = 21.8 A. V 15.0 V
25-10
Chapter 25
25.43.
25.44.
IDENTIFY: The bulbs are each connected across a 120-V potential difference. SET UP: Use P = V2/R to solve for R and Ohm's law (I = V/R) to find the current. EXECUTE: (a) R = V2/P = (120 V)2/(100 W) = 144 . (b) R = V2/P = (120 V)2/(60 W) = 240 (c) For the 100-W bulb: I = V/R = (120 V)/(144 ) = 0.833 A For the 60-W bulb: I = (120 V)/(240 ) = 0.500 A EVALUATE: The 60-W bulb has more resistance than the 100-W bulb, so it draws less current. IDENTIFY: Across 120 V, a 75-W bulb dissipates 75 W. Use this fact to find its resistance, and then find the power the bulb dissipates across 220 V. SET UP: P = V2/R, so R = V2/P EXECUTE: Across 120 V: R = (120 V)2/(75 W) = 192 . Across a 220-V line, its power will be P = V2/R = (220 V)2/(192 ) = 252 W. EVALUATE: The bulb dissipates much more power across 220 V, so it would likely blow out at the higher voltage. An alternative solution to the problem is to take the ratio of the powers. 2 2 2 2 P220 V220 / R V220 220 220 = 2 = = . This gives P220 = (75 W) = 252 W. P V120 / R V120 120 120 120 IDENTIFY: A "100-W" European bulb dissipates 100 W when used across 220 V. (a) SET UP: Take the ratio of the power in the US to the power in Europe, as in the alternative method for problem 25.44, using P = V2/R.
2 PUS VUS / R VUS 120 V 120 V = 2 = = = 29.8 W. . This gives PUS = (100 W) PE VE / R VE 220 V 220 V (b) SET UP: Use P = IV to find the current. EXECUTE: I = P/V = (29.8 W)/(120 V) = 0.248 A EVALUATE: The bulb draws considerably less power in the U.S., so it would be much dimmer than in Europe. IDENTIFY: P = VI . Energy = Pt. SET UP: P = (9.0 V)(0.13 A) = 1.17 W EXECUTE: Energy = (1.17 W)(1.5 h)(3600 s/h) = 6320 J EVALUATE: The energy consumed is proportional to the voltage, to the current and to the time. P IDENTIFY and SET UP: By definition p = . Use P = VI , E = VL and I = JA to rewrite this expression in terms LA of the specified variables. VI EXECUTE: (a) E is related to V and J is related to I, so use P = VI. This gives p = LA V I = E and = J so p = EJ L A I 2R (b) J is related to I and is related to R, so use P = IR 2 . This gives p = . LA 2 2 L J A L 2 I = JA and R = so p = J A LA2 V2 (c) E is related to V and is related to R, so use P = V 2 / R. This gives p = . RLA E 2 L2 A E 2 L V = EL and R = so p = . = A LA L 2 2 2
25.45.
EXECUTE:
25.46.
25.47.
25.48.
EVALUATE: For a given material ( constant), p is proportional to J 2 or to E 2 . IDENTIFY: Calculate the current in the circuit. The power output of a battery is its terminal voltage times the current through it. The power dissipated in a resistor is I 2 R . SET UP: The sum of the potential changes around the circuit is zero. 8.0 V EXECUTE: (a) I = = 0.47 A . Then P9 = I 2 R = (0.47 A) 2 (5.0 ) = 1.1 W and 17 P9 = I 2 R = (0.47 A)2 (9.0 ) = 2.0 W. (b) P = EI - I 2 r = (16 V)(0.47 A) - (0.47 A) 2 (1.6 ) = 7.2 W. 16V (c) P8V = EI + Ir 2 = (8.0 V)(0.47 A) + (0.47 A) 2 (1.4 ) = 4.1 W. EVALUATE: (d) (b) = (a) + (c) . The rate at which the 16.0 V battery delivers electrical energy to the circuit equals the rate at which it is consumed in the 8.0 V battery and the 5.0 and 9.0 resistors.
Current, Resistance, and Electromotive Force
25-11
25.49.
(a) IDENTIFY and SET UP: P = VI and energy = (power) (time). EXECUTE: P = VI = (12 V )( 60 A ) = 720 W
The battery can provide this for 1.0 h, so the energy the battery has stored is U = Pt = ( 720 W )( 3600 s ) = 2.6 106 J
(b) IDENTIFY and SET UP: For gasoline the heat of combustion is Lc = 46 106 J/kg. Solve for the mass m required to supply the energy calculated in part (a) and use density = m / V to calculate V. EXECUTE:
The mass of gasoline that supplies 2.6 106 J is m =
2.6 106 J = 0.0565 kg. 46 106 J/kg
25.50.
The volume of this mass of gasoline is m 0.0565 kg 1000 L = 6.3 10-5 m 3 = 0.063 L V= = 3 900 kg/m3 1m (c) IDENTIFY and SET UP: Energy = (power) (time); the energy is that calculated in part (a). U 2.6 106 J = 5800 s = 97 min = 1.6 h. EXECUTE: U = Pt , t = = P 450 W EVALUATE: The battery discharges at a rate of 720 W (for 60 A) and is charged at a rate of 450 W, so it takes longer to charge than to discharge. IDENTIFY: The rate of conversion of chemical to electrical energy in an emf is EI . The rate of dissipation of electrical energy in a resistor R is I 2 R . SET UP: Example 25.10 finds that I = 1.2 A for this circuit. In Example 25.9, EI = 24 W and I 2r = 8 W . In Example 25.10, I 2 R = 12 W , or 11.5 W if expressed to three significant figures. EXECUTE: (a) P = EI = (12 V)(1.2 A) = 14.4 W . This is less than the previous value of 24 W.
(b) The energy dissipated in the battery is P = I 2 r = (1.2 A) 2 (2.0 ) = 2.9 W. This is less than 8 W, the amount found in Example (25.9). (c) The net power output of the battery is 14.4 W - 2.9 W = 11.5 W . This is the same as the power dissipated in the 8.0 resistor. EVALUATE: With the larger circuit resistance the current is less and the power input and power consumption are less. IDENTIFY: Some of the power generated by the internal emf of the battery is dissipated across the battery's internal resistance, so it is not available to the bulb. SET UP: Use P = I2R and take the ratio of the power dissipated in the internal resistance r to the total power. Pr I 2r r 3.5 EXECUTE: = 2 = = = 0.123 = 12.3% PTotal I (r + R ) r + R 28.5 EVALUATE: About 88% of the power of the battery goes to the bulb. The rest appears as heat in the internal resistance. IDENTIFY: The voltmeter reads the terminal voltage of the battery, which is the potential difference across the appliance. The terminal voltage is less than 15.0 V because some potential is lost across the internal resistance of the battery. (a) SET UP: P = V2/R gives the power dissipated by the appliance. EXECUTE: P = (11.3 V)2/(75.0 ) = 1.70 W (b) SET UP: The drop in terminal voltage ( E Vab) is due to the potential drop across the internal resistance r. Use Ir = E Vab to find the internal resistance r, but first find the current using P = IV. EXECUTE: I = P/V = (1.70 W)/(11.3 V) = 0.151 A. Then Ir = E Vab gives (0.151 A)r = 15.0 V 11.3 V and r = 24.6 . EVALUATE: The full 15.0 V of the battery would be available only when no current (or a very small current) flowing is in the circuit. This would be the base if the appliance had a resistance much greater than 24.6 . IDENTIFY: Solve for the current I in the circuit. Apply Eq. (25.17) to the specified circuit elements to find the rates of energy conversion. SET UP: The circuit is sketched in Figure 25.53. EXECUTE: Compute I: E - Ir - IR = 0 E 12.0 V I= = = 2.00 A r + R 1.0 + 5.0 Figure 25.53
25.51.
25.52.
25.53.
25-12
Chapter 25
(a) The rate of conversion of chemical energy to electrical energy in the emf of the battery is P = EI = (12.0 V )( 2.00 A ) = 24.0 W. (b) The rate of dissipation of electrical energy in the internal resistance of the battery is
P = I 2 r = ( 2.00 A ) (1.0 ) = 4.0 W.
2
(c) The rate of dissipation of electrical energy in the external resistor R is P = I 2 R = ( 2.00 A ) ( 5.0 ) = 20.0 W.
2
25.54.
EVALUATE: The rate of production of electrical energy in the circuit is 24.0 W. The total rate of consumption of electrical energy in the circuit is 4.00 W + 20.0 W = 24.0 W. Equal rate of production and consumption of electrical energy are required by energy conservation. IDENTIFY: The power delivered to the bulb is I 2 R . Energy = Pt . SET UP: The circuit is sketched in Figure 25.54. rtotal is the combined internal resistance of both batteries. EXECUTE: (a) rtotal = 0 . The sum of the potential changes around the circuit is zero, so
1.5 V + 1.5 V - I (17 ) = 0 . I = 0.1765 A . P = I 2 R = (0.1765 A) 2 (17 ) = 0.530 W . This is also (3.0 V)(0.1765 A) . (b) Energy = (0.530 W)(5.0 h)(3600 s/h) = 9540 J
0.530 W P 0.265 W = 0.265 W . P = I 2 R so I = = = 0.125 A . 2 R 17 The sum of the potential changes around the circuit is zero, so 1.5 V + 1.5 V - IR - Irtotal = 0 .
(c) P =
3.0 V - (0.125 A)(17 ) = 7.0 . 0.125 A EVALUATE: When the power to the bulb has decreased to half its initial value, the total internal resistance of the two batteries is nearly half the resistance of the bulb. Compared to a single battery, using two identical batteries in series doubles the emf but also doubles the total internal resistance. rtotal =
Figure 25.54 25.55. IDENTIFY: SET UP: EXECUTE:
V = VI . V = IR . R The heater consumes 540 W when V = 120 V . Energy = Pt. P = I 2R =
(a) P =
2
25.56.
V2 V 2 (120 V) 2 = = 26.7 so R = P 540 W R P 540 W (b) P = VI so I = = = 4.50 A V 120 V V 2 (110 V) 2 = = 453 W . P is smaller by a factor of (110 /120) 2 . (c) Assuming that R remains 26.7 , P = R 26.7 EVALUATE: (d) With the lower line voltage the current will decrease and the operating temperature will decrease. R will be less than 26.7 and the power consumed will be greater than the value calculated in part (c). m IDENTIFY: From Eq. (25.24), = 2 . ne SET UP: For silicon, = 2300 m.
EXECUTE: EVALUATE: (a) =
m 9.11 10 -31 kg = = 1.55 10-12 s. 2 16 -3 ne (1.0 10 m )(1.60 10-19 C) 2 (2300 m)
(b) The number of free electrons in copper (8.5 10 28 m -3 ) is much larger than in pure silicon
(1.0 1016 m -3 ). A smaller density of current carriers means a higher resistivity.
25.57.
(a) IDENTIFY and SET UP: Use R = EXECUTE:
L
A
.
2
-3 RA ( 0.104 ) (1.25 10 m ) = = = 3.65 10-8 m L 14.0 m
Current, Resistance, and Electromotive Force
25-13
EVALUATE: This value is similar to that for good metallic conductors in Table 25.1. (b) IDENTIFY and SET UP: Use V = EL to calculate E and then Ohm's law gives I. EXECUTE: V = EL = (1.28 V/m )(14.0 m ) = 17.9 V
V 17.9 V = = 172 A R 0.104 EVALUATE: We could do the calculation another way: E 1.28 V/m = 3.51 107 A/m 2 E = J so J = = 3.65 10-8 m I=
I = JA = ( 3.51107 A/m 2 ) (1.25 10 -3 m ) = 172 A, which checks
2
(c) IDENTIFY and SET UP: Calculate J = I / A or J = E / and then use Eq. (25.3) for the target variable vd . EXECUTE:
vd = J = n q vd = nevd J 3.51 107 A/m 2 = = 2.58 10-3 m/s = 2.58 mm/s ne ( 8.5 1028 m -3 )(1.602 10-19 C )
25.58.
Even for this very large current the drift speed is small. L IDENTIFY: Use R = to calculate the resistance of the silver tube. Then I = V / R. A SET UP: For silver, = 1.47 10 -8 m. The silver tube is sketched in Figure 25.58. Since the thickness T = 0.100 mm is much smaller than the radius, r = 2.00 cm , the cross section area of the silver is 2 rT . The length of the tube is l = 25.0 m. V V VA V (2 rT ) (12 V)(2 )(2.00 10-2 m)(0.100 10 -3 m) = = = = 410 A EXECUTE: I = = R l A l l (1.47 10 -8 m)(25.0 m) EVALUATE: The resistance is small, R = 0.0292 , so 12.0 V produces a large current.
EVALUATE:
Figure 25.58 25.59. IDENTIFY and SET UP: With the voltmeter connected across the terminals of the battery there is no current through the battery and the voltmeter reading is the battery emf; E = 12.6 V. With a wire of resistance R connected to the battery current I flows and E - Ir - IR = 0, where r is the internal resistance of the battery. Apply this equation to each piece of wire to get two equations in the two unknowns. EXECUTE: Call the resistance of the 20.0-m piece R1; then the resistance of the 40.0-m piece is R2 = 2 R1.
E - I1r - I1R1 = 0; E - I 2 r - I 2 ( 2 R1 ) = 0; 12.6 V - ( 7.00 A ) r - ( 7.00 A ) R1 = 0 12.6 V - ( 4.20 A ) r - ( 4.20 A )( 2 R1 ) = 0
Solving these two equations in two unknowns gives R1 = 1.20 . This is the resistance of 20.0 m, so the resistance of one meter is 1.20 / ( 20.0 m ) (1.00 m ) = 0.060 EVALUATE: We can also solve for r and we get r = 0.600 . When measuring small resistances, the internal resistance of the battery has a large effect. IDENTIFY: Conservation of charge requires that the current is the same in both sections. The voltage drops across each section add, so R = RCu + RAg . The total resistance is the sum of the resistances of each section. E = J =
SET UP:
25.60.
I
IR , so E = , where R is the resistance of a section and L is its length. A L For copper, Cu = 1.72 10 -8 m . For silver, Ag = 1.47 10-8 m.
25-14
Chapter 25
EXECUTE:
(a) I =
L (1.72 10-8 m)(0.8 m) V V = 0.049 and = . RCu = Cu Cu = ( /4)(6.0 10-4 m) 2 ACu R RCu + RAg
RAg =
Ag LAg
AAg
=
(1.47 10-8 m)(1.2 m) 5.0 V = 45 A. = 0.062 . This gives I = -4 2 ( /4)(6.0 10 m) 0.049 + 0.062
The current in the copper wire is 45 A. (b) The current in the silver wire is 45 A, the same as that in the copper wire or else charge would build up at their interface. (45 A)(0.049 ) IR (c) ECu = J Cu = Cu = = 2.76 V m. 0.8 m LCu
(d) EAg = J Ag =
IRAg LAg
=
(45 A)(0.062 ) = 2.33 V m. 1.2 m
(e) VAg = IRAg = (45 A)(0.062 ) = 2.79 V. EVALUATE: 25.61.
For the copper section, VCu = IRCu = 2.21 V. Note that VCu + VAg = 5.0 V, the voltage applied across
the ends of the composite wire. IDENTIFY: Conservation of charge requires that the current be the same in both sections of the wire. EA L I E = J = . For each section, V = IR = JAR = = EL. The voltages across each section add. A A
SET UP: A = ( / 4) D 2 , where D is the diameter. EXECUTE: (a) The current must be the same in both sections of the wire, so the current in the thin end is 2.5 mA. I (1.72 10-8 m)(2.5 10-3 A) = = 2.14 10 -5 V/m. (b) E1.6mm = J = A ( 4)(1.6 10-3 m) 2 (c) E0.8mm = J =
I
A
=
(1.72 10-8 m)(2.5 10 -3 A) = 8.55 10 -5 V/m . This is 4E1.6mm . ( 4)(0.80 10 -3 m) 2
(d) V = E1.6mm L1.6 mm + E0.8 mm L0.8 mm . V = (2.14 10-5 V/m)(1.20 m) + (8.55 10-5 V/m)(1.80 m) = 1.80 10 -4 V. EVALUATE: The currents are the same but the current density is larger in the thinner section and the electric field is larger there. IDENTIFY: I = JA. SET UP: From Example 25.1, an 18-gauge wire has A = 8.17 10-3 cm 2 . EXECUTE: (a) I = JA = (1.0 105 A/cm 2 )(8.17 10-3 cm 2 ) = 820 A (b) A = I / J = (1000 A) (1.0 106 A/cm 2 ) = 1.0 10-3 cm 2 . A = r 2 so
25.62.
25.63.
r = A = (1.0 10 -3 cm 2 ) = 0.0178 cm and d = 2r = 0.36 mm . EVALUATE: These wires can carry very large currents. (a) IDENTIFY: Apply Eq. (25.10) to calculate the resistance of each thin disk and then integrate over the truncated cone to find the total resistance. SET UP: EXECUTE: The radius of a truncated cone a distance y above the bottom is given by r = r2 + ( y / h )( r1 - r2 ) = r2 + y
with = ( r1 - r2 ) / h
Figure 25.63
Consider a thin slice a distance y above the bottom. The slice has thickness dy and radius r. The resistance of the slice is dy dy dy dR = = 2 = 2 A r ( r2 + y ) The total resistance of the cone if obtained by integrating over these thin slices:
R = dR =
h dy 1 1 1 -1 = - ( r2 + y ) = - - 0 ( r2 + y )2 r2 + h r2 0
h
Current, Resistance, and Electromotive Force
25-15
But r2 + h = r1 1 1 h r1 - r2 h = - = r2 r1 r1 - r2 r1r2 r1r2 (b) EVALUATE: Let r1 = r2 = r. Then R = h / r 2 = L / A where A = r 2 and L = h. This agrees with Eq. (25.10). IDENTIFY: Divide the region into thin spherical shells of radius r and thickness dr. The total resistance is the sum of the resistances of the thin shells and can be obtained by integration. SET UP: I = V / R and J = I / 4 r 2 , where 4 r 2 is the surface area of a shell of radius r.
R=
25.64.
EXECUTE: (b) I =
(a) dR =
dr b dr 1 1 1 b-a R= 2 r 2 = - 4 r a = 4 a - b = 4 ab . 4 r 4 a
b
Vab Vab 4 ab I Vab 4 ab Vab ab = and J = = = . 2 (b - a) r 2 A (b - a)4 r R (b - a)
(c) If the thickness of the shells is small, then 4 ab 4 a 2 is the surface area of the conducting material. 1 1 (b - a) L L R= = , where L = b - a. - = 4 a b 4 ab 4 a 2 A 25.65. EVALUATE: The current density in the material is proportional to 1/ r 2 . IDENTIFY and SET UP: Use E = J to calculate the current density between the plates. Let A be the area of each plate; then I = JA. E Q EXECUTE: J = and E = = K P0 KAP0
Thus J =
Q Q and I = JA = , as was to be shown. KAP0 K P0
25.66.
EVALUATE: C = K P0 A / d and V = Q / C = Qd / K P0 A so the result can also be written as I = VA / d . The resistance of the dielectric is R = V / I = d / A, which agrees with Eq. (25.10). IDENTIFY: As the resistance R varies, the current in the circuit also varies, which causes the potential drop across the internal resistance of the battery to vary. SET UP: The largest current will occur when R = 0, and the smallest current will occur when R . The largest terminal voltage will occur when the current is zero (R ) and the smallest terminal voltage will be when the current is a maximum (R = 0). EXECUTE: (a) As R , I 0, so Vab E = 15.0 V, which is the largest reading of the voltmeter. When R = 0, the current is largest at (15.0 V)/(4.00 ) = 3.75 A, so the smallest terminal voltage is Vab = E rI = 15.0 V (4.00 )(3.75 A) = 0. (b) From part (a), the maximum current is 3.75 A when R = 0, and the minimum current is 0.00 A when R . (c) The graphs are sketched in Figure 25.66. EVALUATE: Increasing the resistance R increases the terminal voltage, but at the same time it decreases the current in the circuit.
Figure 25.66 25.67. IDENTIFY: SET UP: EXECUTE:
. A For mercury at 20C , = 9.5 10-7 m , = 0.00088 (C) -1 and = 18 10-5 (C) -1.
(a) R =
Apply R =
L
L
A
=
(9.5 10-7 m)(0.12 m) = 0.057 . ( 4)(0.0016 m) 2
25-16
Chapter 25
(b) (T ) = 0 (1 + T ) gives (60 C) = (9.5 10-7 m)(1 + (0.00088 (C) -1 )(40 C) = 9.83 10-7 m, so
= 3.34 10 -8 m.
(c) V = V0T gives AL = A ( L0T ) . Therefore
L = L0 T = (18 10-5 (C) -1 )(0.12 m)(40 C) = 8.64 10 -4 m = 0.86 mm. The cross sectional area of the mercury remains constant because the diameter of the glass tube doesn't change. All of the change in volume of the mercury must be accommodated by a change in length of the mercury column. L L L (d) R = gives R = . + A A A (3.34 10-8 m)(0.12 m) (95 10 -8 m)(0.86 10-3 m) R = + = 2.40 10-3 . ( /4)(0.0016 m) 2 ( /4)(0.0016 m) 2 EVALUATE: (e) From Equation (25.12), (0.057 + 2.40 10-3 ) - 1 = 1.1 10-3 (C) -1. = 1 R - 1 = 1 T R0 40 C 0.057 This value is 25% greater than the temperature coefficient of resistivity and the length increase is important. IDENTIFY: Consider the potential changes around the circuit. For a complete loop the sum of the potential changes is zero. SET UP: There is a potential drop of IR when you pass through a resistor in the direction of the current. 8.0 V - 4.0 V EXECUTE: (a) I = = 0.167 A . Vd + 8.00 V - I (0.50 + 8.00 ) = Va , so 24.0
25.68.
Vad = 8.00 V - (0.167 A) (8.50 ) = 6.58 V.
(b) The terminal voltage is Vbc = Vb - Vc . Vc + 4.00 V + I (0.50 ) = Vb and
Vbc = + 4.00 V + (0.167 A) (0.50 ) = + 4.08 V. (c) Adding another battery at point d in the opposite sense to the 8.0 V battery produces a counterclockwise current 10.3 V - 8.0 V + 4.0 V with magnitude I = = 0.257 A . Then Vc + 4.00 V - I (0.50 ) = Vb and 24.5 Vbc = 4.00 V - (0.257 A) (0.50 ) = 3.87 V. EVALUATE: When current enters the battery at its negative terminal, as in part (c), the terminal voltage is less than its emf. When current enters the battery at the positive terminal, as in part (b), the terminal voltage is greater than its emf. IDENTIFY: In each case write the terminal voltage in terms of E , I, and r. Since I is known, this gives two equations in the two unknowns E and r. SET UP: The battery with the 1.50 A current is sketched in Figure 25.69a. Vab = 8.4 V Vab = E - Ir
E - (1.50 A ) r = 8.4 V
25.69.
Figure 25.69a
The battery with the 3.50 A current is sketched in Figure 25.69b. Vab = 9.4 V Vab = E + Ir
E + ( 3.5 A ) r = 9.4 V
Figure 25.69b EXECUTE: (a) Solve the first equation for E and use that result in the second equation: E = 8.4 V + (1.50 A ) r
8.4 V + (1.50 A ) r + ( 3.50 A ) r = 9.4 V
( 5.00 A ) r = 1.0 V so r =
1.0 V = 0.20 5.00 A
Current, Resistance, and Electromotive Force
25-17
(b) Then E = 8.4 V + (1.50 A ) r = 8.4 V + (1.50 A )( 0.20 ) = 8.7 V EVALUATE: When the current passes through the emf in the direction from - to +, the terminal voltage is less than the emf and when it passes through from + to -, the terminal voltage is greater than the emf. 25.70. IDENTIFY: V = IR . P = I 2 R. SET UP: The total resistance is the resistance of the person plus the internal resistance of the power supply. V 14 103 V = = 1.17 A EXECUTE: (a) I = Rtot 10 103 + 2000 (b) P = I 2 R = (1.17 A) 2 (10 103 ) = 1.37 104 J = 13.7 kJ
25.71.
V 14 103 V = = 14 106 . The resistance of the power supply would need to be I 1.00 10 -3 A 14 106 - 10 103 = 14 106 = 14 M. EVALUATE: The current through the body in part (a) is large enough to be fatal. L IDENTIFY: R = . V = IR . P = I 2 R. A SET UP: The area of the end of a cylinder of radius r is r 2 . (5.0 m)(1.6 m) EXECUTE: (a) R = = 1.0 103 (0.050 m) 2
(c) Rtot = (b) V = IR = (100 10-3 A)(1.0 103 ) = 100 V (c) P = I 2 R = (100 10 -3 A) 2 (1.0 103 ) = 10 W EVALUATE: The resistance between the hands when the skin is wet is about a factor of ten less than when the skin is dry (Problem 25.70). IDENTIFY: The cost of operating an appliance is proportional to the amount of energy consumed. The energy depends on the power the item consumes and the length of time for which it is operated. SET UP: At a constant power, the energy is equal to Pt, and the total cost is the cost per kilowatt-hour (kWh) times the time the energy (in kWh). EXECUTE: (a) Use the fact that 1.00 kWh = (1000 J/s)(3600 s) = 3.60 106 J, and one year contains 3.156 107 s.
25.72.
( 75 J/s ) ( 400 J/s )
3.156 107 s $0.120 = $78.90 6 1 yr 3.60 10 J = $140.27 J
(b) At 8 h/day, the refrigerator runs for 1/3 of a year. Using the same procedure as above gives
1 3.156 107 s $0.120 6 1 yr 3 3.60 10
25.73.
EVALUATE: Electric lights can be a substantial part of the cost of electricity in the home if they are left on for a long time! IDENTIFY: Set the sum of the potential rises and drops around the circuit equal to zero and solve for I. SET UP: The circuit is sketched in Figure 25.73. EXECUTE: E - IR - V = 0 E - IR - I - I 2 = 0
I2 + (R + )I - E = 0
Figure 25.73
2 The quadratic formula gives I = (1/ 2 ) - ( R + ) ( R + ) + 4 E I must be positive, so take the + sign 2 I = (1/ 2 ) - ( R + ) + ( R + ) + 4 E I = -2.692 A + 4.116 A = 1.42 A EVALUATE: For this I the voltage across the thermistor is 8.0 V. The voltage across the resistor must then be 12.6 V - 8.0 V = 4.6 V, and this agrees with Ohm's law for the resistor.
25-18
Chapter 25
25.74.
(a) IDENTIFY: The rate of heating (power) in the cable depends on the potential difference across the cable and the resistance of the cable. SET UP: The power is P = V2/R and the resistance is R = L/A. The diameter D of the cable is twice its radius. V2 V2 AV 2 r 2V 2 P= = = = . The electric field in the cable is equal to the potential difference across its R ( L / A) L L
ends divided by the length of the cable: E = V/L. EXECUTE: Solving for r and using the resistivity of copper gives
r=
(50.0 W) (1.72 10-8 m ) (1500 m) P L = = 9.21 105 m. D = 2r = 0.184 mm V 2 (220.0 V) 2
25.75.
(b) SET UP: E = V/L EXECUTE: E = (220 V)/(1500 m) = 0.147 V/m EVALUATE: This would be an extremely thin (and hence fragile) cable. IDENTIFY: The ammeter acts as a resistance in the circuit loop. Set the sum of the potential rises and drops around the circuit equal to zero. (a) SET UP: The circuit with the ammeter is sketched in Figure 25.75a. EXECUTE: E IA = r + R + RA
E = I A ( r + R + RA )
Figure 25.75a SET UP:
The circuit with the ammeter removed is sketched in Figure 25.75b.
EXECUTE: E I= R+r
Figure 25.75b
Combining the two equations gives RA 1 I = I A ( r + R + RA ) = I A 1 + R+r r+R (b) Want I A = 0.990 I . Use this in the result for part (a). R I = 0.990 I 1 + A r+R R 0.010 = 0.990 A r+R
RA = ( r + R )( 0.010 / 0.990 ) = ( 0.45 + 3.80 )( 0.010 / 0.990 ) = 0.0429
(c) I - I A =
E E - r + R r + R + RA
r + R + RA - r - R ER A . I - IA = E = ( r + R )( r + R + R ) ( r + R )( r + R + R ) A A EVALUATE: The difference between I and I A increases as RA increases. If RA is larger than the value
25.76.
calculated in part (b) then I A differs from I by more than 1.0%. IDENTIFY: Since the resistivity is a function of the position along the length of the cylinder, we must integrate to find the resistance. (a) SET UP: The resistance of a cross-section of thickness dx is dR = dx/A. EXECUTE: Using the given function for the resistivity and integrating gives
R=
dx
A
=
L
0
( a + bx ) dx = aL + bL / 3.
2 3
r
2
r
2
Current, Resistance, and Electromotive Force
25-19
Now get the constants a and b: (0) = a = 2.25 10 -8 m and ( L) = a + bL2 gives 8.50 10 -8 m = 2.25 10 -8 m + b(1.50 m)2 which gives b = 2.78 10 -8 /m. Now use the above result to find R.
(0.0110 m) 2
(b) IDENTIFY: Use the definition of resistivity to find the electric field at the midpoint of the cylinder, where x = L/2. SET UP: E = J. Evaluate the resistivity, using the given formula, for x = L/2. 2 I a + b ( L / 2) I = EXECUTE: At the midpoint, x = L/2, giving E = . 2 2 r r
2.25 10-8 m + ( 2.78 10-8 / m ) (0.750 m) 2 (1.75 A) = 1.76 10 -4 V/m E= (0.0110 m) 2
(c) IDENTIFY: For the first segment, the result is the same as in part (a) except that the upper limit of the integral is L/2 instead of L. SET UP: EXECUTE:
Integrating using the upper limit of L/2 gives R1 = Substituting the numbers gives
-8
a ( L / 2 ) + (b / 3) ( L3 / 8 )
r2
.
R1 =
( 2.25 10
m ) (0.750 m) + (2.78 10 -8 / m)/3 ( (1.50 m)3 / 8 )
(0.0110 m) 2
= 5.47 10-5
25.77.
The resistance R2 of the second half is equal to the total resistance minus the resistance of the first half. R2 = R R1 = 1.71 10 -4 5.47 10 -5 = 1.16 10 -4 EVALUATE: The second half has a greater resistance than the first half because the resistance increases with distance along the cylinder. IDENTIFY: The power supplied to the house is P = VI . The rate at which electrical energy is dissipated in the L wires is I 2 R, where R = . A SET UP: For copper, = 1.72 10 -8 m. EXECUTE: (a) The line voltage, current to be drawn, and wire diameter are what must be considered in household wiring. P 4200 W (b) P = VI gives I = = = 35 A, so the 8-gauge wire is necessary, since it can carry up to 40 A. V 120 V
(c) P = I 2 R =
I 2 L (35 A) 2 (1.72 10-8 m) (42.0 m) = = 106 W. A ( 4) (0.00326 m) 2
I 2 L (35 A) 2 (1.72 10-8 m) (42 m) = = 66 W . The decrease in energy A ( 4) ) (0.00412 m) 2 consumption is E = Pt = (40 W) (365 days/yr) (12 h/day) = 175 kWh/yr and the savings is
(d) If 6-gauge wire is used, P =
25.78.
(175 kWh/yr) ($0.11 kWh) = $19.25 per year. EVALUATE: The cost of the 4200 W used by the appliances is $2020. The savings is about 1%. V IDENTIFY: RT = R0 (1 + [T - T0 ]) . R = . P = VI . I SET UP: When the temperature increases the resistance increases and the current decreases. V V EXECUTE: (a) = (1 + [T - T0 ]) . I 0 = IT (1 + [T - T0 ]) . IT I 0 I 0 - IT 1.35 A - 1.23 A = = 217 C . T = 20C + 217C = 237C (1.23 A)(4.5 10-4 (C) -1 ) IT (b) (i) P = VI = (120 V)(1.35 A) = 162 W (ii) P = (120 V)(1.23 A) = 148 W T - T0 =
25.79.
EVALUATE: P = V 2 / R shows that the power dissipated decreases when the resistance increases. (a) IDENTIFY: Set the sum of the potential rises and drops around the circuit equal to zero and solve for the resulting equation for the current I. Apply Eq. (25.17) to each circuit element to find the power associated with it.
R=
( 2.25 10
-8
m ) (1.50 m) + ( 2.78 10 -8 / m ) (1.50 m)3 / 3
= 1.71 104
= 171
25-20
Chapter 25
SET UP:
The circuit is sketched in Figure 25.79.
EXECUTE: E1 - E2 - I ( r1 + r2 + R ) = 0 I= I=
E1 - E2 r1 + r2 + R
12.0 V - 8.0 V 1.0 + 1.0 + 8.0 I = 0.40 A
Figure 25.79 (b) P = I 2 R + I 2r1 + I 2 r2 = I 2 ( R + r1 + r2 ) = ( 0.40 A ) ( 8.0 + 1.0 + 1.0 )
2
P = 1.6 W (c) Chemical energy is converted to electrical energy in a battery when the current goes through the battery from the negative to the positive terminal, so the electrical energy of the charges increases as the current passes through. This happens in the 12.0 V battery, and the rate of production of electrical energy is P = E1I = (12.0 V )( 0.40 A ) = 4.8 W. (d) Electrical energy is converted to chemical energy in a battery when the current goes through the battery from the positive to the negative terminal, so the electrical energy of the charges decreases as the current passes through. This happens in the 8.0 V battery, and the rate of consumption of electrical energy is P = E2 I = ( 8.0 V )( 0.40 V ) = 3.2 W. (e) EVALUATE: Total rate of production of electrical energy = 4.8 W. Total rate of consumption of electrical energy = 1.6 W + 3.2 W = 4.8 W, which equals the rate of production, as it must. L IDENTIFY: Apply R = for each material. The total resistance is the sum of the resistances of the rod and the A wire. The rate at which energy is dissipated is I 2 R. SET UP: For steel, = 2.0 10-7 m . For copper, = 1.72 10 -8 m. EXECUTE: RCu = (a) Rsteel =
-8
25.80.
L
A
=
(2.0 10-7 m) (2.0 m) = 1.57 10-3 and ( 4) (0.018 m) 2
L
A
=
(1.72 10 m) (35 m) = 0.012 . This gives ( 4) (0.008 m) 2
V = IR = I ( Rsteel + RCu ) = (15000 A) (1.57 10-3 + 0.012 ) = 204 V.
(b) E = Pt = I 2 Rt = (15000 A) 2 (0.0136 ) (65 10-6 s) = 199 J. EVALUATE: I 2 R is large but t is very small, so the energy deposited is small. The wire and rod each have a mass of about 1 kg, so their temperature rise due to the deposited energy will be small. IDENTIFY and SET UP: The terminal voltage is Vab = - Ir = IR , where R is the resistance connected to the
25.81.
battery. During the charging the terminal voltage is Vab = + Ir . P = VI and energy is E = Pt . I 2 r is the rate at which energy is dissipated in the internal resistance of the battery. EXECUTE: (a) Vab = + Ir = 12.0 V + (10.0 A) (0.24 ) = 14.4 V.
(b) E = Pt = IVt = (10 A) (14.4 V) (5) (3600 s) = 2.59 106 J. (c) Ediss = Pdisst = I 2 rt = (10 A) 2 (0.24 ) (5) (3600 s) = 4.32 105 J. (d) Discharged at 10 A: I =
E
r+R
R=
E - Ir 12.0 V - (10 A) (0.24 ) = = 0.96 . 10 A I
(e) E = Pt = IVt = (10 A) (9.6 V) (5) (3600 s) = 1.73 106 J. (f) Since the current through the internal resistance is the same as before, there is the same energy dissipated as in (c): Ediss = 4.32 105 J. (g) Part of the energy originally supplied was stored in the battery and part was lost in the internal resistance. So the stored energy was less than what was supplied during charging. Then when discharging, even more energy is lost in the internal resistance, and only what is left is dissipated by the external resistor.
Current, Resistance, and Electromotive Force
25-21
25.82.
IDENTIFY and SET UP:
battery. During the charging the terminal voltage is Vab = + Ir. P = VI and energy is E = Pt . I 2 r is the rate at which energy is dissipated in the internal resistance of the battery. EXECUTE: (a) Vab = E + Ir = 12.0 V + ( 30 A) (0.24 ) = 19.2 V.
(b) E = Pt = IVt = (30 A) (19.2 V) (1.7) (3600 s) = 3.53 106 J. (c) Ediss = Pdisst = I 2 Rt = (30 A) 2 (0.24 ) (1.7) (3600 s) = 1.32 106 J. (d) Discharged at 30 A: I =
The terminal voltage is Vab = - Ir = IR, where R is the resistance connected to the
E E - Ir 12.0 V - (30 A) (0.24 ) = = 0.16 . gives R = 30 A I r+R
25.83.
25.84.
(e) E = Pt = I 2 Rt = (30 A) 2 (0.16 ) (1.7) (3600 s) = 8.81 105 J. (f) Since the current through the internal resistance is the same as before, there is the same energy dissipated as in (c): Ediss = 1.32 106 J. (g) Again, part of the energy originally supplied was stored in the battery and part was lost in the internal resistance. So the stored energy was less than what was supplied during charging. Then when discharging, even more energy is lost in the internal resistance, and what is left is dissipated over the external resistor. This time, at a higher current, much more energy is lost in the internal resistance. Slow charging and discharging is more energy efficient. IDENTIFY and SET UP: Follow the steps specified in the problem. |q| a EXECUTE: (a) F = ma = q E gives = . m E | q | aL (b) If the electric field is constant, Vbc = EL and = m Vbc (c) The free charges are "left behind" so the left end of the rod is negatively charged, while the right end is positively charged. Thus the right end, point c, is at the higher potential. V | q | (1.0 10-3 V) (1.6 10-19 C) = = 3.5 108 m/s 2 . (d) a = bc (9.11 10-31 kg) (0.50 m) mL EVALUATE: (e) Performing the experiment in a rotational way enables one to keep the experimental apparatus in a localized area--whereas an acceleration like that obtained in (d), if linear, would quickly have the apparatus moving at high speeds and large distances. Also, the rotating spool of thin wire can have many turns of wire and the total potential is the sum of the potentials in each turn, the potential in each turn times the number of turns. IDENTIFY: E - IR - V = 0 e SET UP: With T = 293 K , = 39.6 V -1. kT EXECUTE: (a) E = IR + V gives 2.00 V = I (1.0 ) + V . Dropping units and using the expression given in the
problem for I, this becomes 2.00 = IS [exp(eV kT ) - 1] + V.
(b) For IS = 1.50 10-3 A and T = 293 K, 1333 = exp [39.6 V ] - 1 + 667V . Trial and error shows that the right-hand side (rhs) above, for specific V values, equals 1333 V when V = 0.179 V. The current then is
just I = I S[exp(39.6 V ) - 1] = (1.5 10-3 A) ( exp([39.6][0.179]) - 1]) = 1.80 A.
25.85.
The voltage across the resistor R is 1.80 V. The diode does not obey Ohm's law. L IDENTIFY: Apply R = to find the resistance of a thin slice of the rod and integrate to find the total R. A V = IR . Also find R ( x), the resistance of a length x of the rod. SET UP: E ( x) = ( x) J
EVALUATE: EXECUTE: (a) dR =
dx
A
=
0 exp[- x L] dx
A
so
R=
0
A
exp [- x
0
L
L] dx =
0
A
L [- L exp[ - x L]]0 =
0 L
A
-x/ L
(1 - e -1 ) and I =
V0 V0 A = . With an upper limit of x R 0 L(1 - e -1 )
rather than L in the integration, R( x ) =
(b) E ( x) = ( x ) J =
0 L
A
(1 - e ) .
I 0e - x L V e- x L = 0 -1 . A L (1 - e )
25-22
Chapter 25
-x/ L 0 L V0 A - -1 -x/ L (c) V = V0 - IR ( x) . V = V0 - ) = V0 (e(1 - e-e) ) (1 - e -1 1 0 L[1 - e ] A (d) Graphs of resistivity, electric field and potential from x = 0 to L are given in Figure 25.85. Each quantity is given in terms of the indicated unit. EVALUATE: The current is the same at all points in the rod. Where the resistivity is larger the electric field must be larger, in order to produce the same current density.
Figure 25.85 25.86. IDENTIFY: SET UP: EXECUTE:
The power output of the source is VI = (E - Ir ) I . The short-circuit current is I short circuit = E / r.
(a) P = EI - I 2 r , so
dP 1E 1 = E - 2 Ir = 0 for maximum power output and I P max = = I short circuit . dI 2r 2 E 1E = (b) For the maximum power output of part (a), I = . r + R = 2r and R = r. r+R 2r
25.87.
E2 E Then, P = I 2 R = r = . 4r 2r EVALUATE: When R is smaller than r, I is large and the I 2 r losses in the battery are large. When R is larger than r, I is small and the power output EI of the battery emf is small. 1 d IDENTIFY: Use = - n / T in = to get a separable differential equation that can be integrated. dT
SET UP: EXECUTE:
2
For carbon, = 3.5 10-5 m and = -5 10-4 (K) -1.
(a) =
1 d n ndT d a = ln (T - n ) = ln( ) = n . =- dT T T T
(b) n = -T = - ( - 5 10 -4 (K) -1 ) (293 K) = 0.15.
a a = T n = (3.5 10 -5 m) (293 K) 0.15 = 8.0 10-5 m K 0.15 . Tn 8.0 10-5 = 4.3 10 -5 m. (c) T = - 196C = 77 K : = (77 K) 0.15
=
T = - 300C = 573 K : =
EVALUATE: temperatures.
8.0 10-5 = 3.2 10-5 m. (573 K) 0.15 is negative and decreases as T decreases, so changes more rapidly with temperature at lower
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UCLA - MAE - 162D
DIRECT-CURRENT CIRCUITS26 26.1.26.2.26.3.IDENTIFY: The newly-formed wire is a combination of series and parallel resistors. SET UP: Each of the three linear segments has resistance R/3. The circle is two R/6 resistors in parallel. EXECUTE: The resis
UCLA - MAE - 162D
MAGNETIC FIELD AND MAGNETIC FORCES2727.1.IDENTIFY and SET UP: Apply Eq.(27.2) to calculate F . Use the cross products of unit vectors from Section 1.10. ^ j EXECUTE: v = ( +4.19 10 4 m/s ) i + ( -3.85 10 4 m/s ) ^^ (a) B = (1.40 T ) i ^ ^ F = qv B = (
UCLA - MAE - 162D
SOURCES OF MAGNETIC FIELD2828.1.IDENTIFY and SET UP: Use Eq.(28.2) to calculate B at each point. ^ qv r 0 qv r r ^ = B= 0 , since r = . 4 r 2 4 r 3 r 6 ^ and r is the vector from the charge to the point where the field is calculated. v = ( 8.00 10 m/s
UCLA - MAE - 162D
ELECTROMAGNETIC INDUCTION2929.1.29.2.IDENTIFY: Altering the orientation of a coil relative to a magnetic field changes the magnetic flux through the coil. This change then induces an emf in the coil. SET UP: The flux through a coil of N turns is = NBA
UCLA - MAE - 162D
INDUCTANCE30E1 = M30.1.IDENTIFY and SET UP: Apply Eq.(30.4). di EXECUTE: (a) E2 = M 1 = (3.25 10 -4 H)(830 A/s) = 0.270 V; yes, it is constant. dtdi2 ; M is a property of the pair of coils so is the same as in part (a). Thus E1 = 0.270 V. dt EVALUATE
UCLA - MAE - 162D
ALTERNATING CURRENT3131.1.IDENTIFY:i = I cos t and I rms = I/ 2.SET UP: The specified value is the root-mean-square current; I rms = 0.34 A. EXECUTE: (a) I rms = 0.34 A (b) I = 2 I rms = 2(0.34 A) = 0.48 A. (c) Since the current is positive half of t
UCLA - MAE - 162D
ELECTROMAGNETIC WAVES3232.1.IDENTIFY: Since the speed is constant, distance x = ct. SET UP: The speed of light is c = 3.00 108 m/s . 1 yr = 3.156 107 s.32.2.x 3.84 108 m = = 1.28 s c 3.00 108 m/s (b) x = ct = (3.00 108 m/s)(8.61 yr)(3.156 107 s/yr) =
UCLA - MAE - 162D
THE NATURE AND PROPAGATION OF LIGHT3333.1.IDENTIFY: For reflection, r = a . SET UP: The desired path of the ray is sketched in Figure 33.1. 14.0 cm , so = 50.6 . r = 90 - = 39.4 and r = a = 39.4 . EXECUTE: tan = 11.5 cm EVALUATE: The angle of incidence
UCLA - MAE - 162D
GEOMETRIC OPTICS34y = 4.85 cm34.1.IDENTIFY and SET UP: Plane mirror: s = - s (Eq.34.1) and m = y / y = - s / s = +1 (Eq.34.2). We are given s and y and are asked to find s and y. EXECUTE: The object and image are shown in Figure 34.1. s = - s = -39.2
UCLA - MAE - 162D
INTERFERENCE3535.1.35.2.IDENTIFY: Compare the path difference to the wavelength. SET UP: The separation between sources is 5.00 m, so for points between the sources the largest possible path difference is 5.00 m. EXECUTE: (a) For constructive interfer
UCLA - MAE - 162D
DIFFRACTION3636.1.IDENTIFY: Use y = x tan to calculate the angular position of the first minimum. The minima are located by m , m = 1, 2,. First minimum means m = 1 and sin 1 = / a and = a sin 1. Use this Eq.(36.2): sin = a equation to calculate . SET
UCLA - MAE - 162D
RELATIVITY37Figure 37.137.1.IDENTIFY and SET UP: Consider the distance A to O and B to O as observed by an observer on the ground (Figure 37.1).(b) d = vt = (0.900) (3.00 108 m s) (5.05 10-6 s) = 1.36 103 m = 1.36 km. 37.3.1 IDENTIFY and SET UP: The
UCLA - MAE - 162D
PHOTONS, ELECTRONS, AND ATOMS38h f - . The e e38.1.IDENTIFY and SET UP: The stopping potential V0 is related to the frequency of the light by V0 = slope of V0 versus f is h/e. The value fth of f when V0 = 0 is related to by = hf th .EXECUTE: (a) From
UCLA - MAE - 162D
THE WAVE NATURE OF PARTICLES39hc39.1.IDENTIFY and SET UP: EXECUTE: (a) ==h h = . For an electron, m = 9.11 10 -31 kg . For a proton, m = 1.67 10 -27 kg . p mv6.63 10-34 J s = 1.55 10-10 m = 0.155 nm (9.11 10-31 kg)(4.70 106 m/s)m 9.11 10 -31 kg 1
UCLA - MAE - 162D
QUANTUM MECHANICS40n2h 2 . 8mL240.1.IDENTIFY and SET UP: The energy levels for a particle in a box are given by En = EXECUTE: (a) The lowest level is for n = 1, and E1 =(1)(6.626 10-34 J s) 2 = 1.2 10-67 J. 8(0.20 kg)(1.5 m) 21 2E 2(1.2 10-67 J) (b)
UCLA - MAE - 162D
ATOMIC STRUCTURE41L = l (l + 1) . Lz = ml . l = 0, 1, 2,., n - 1. ml = 0, 1, 2,., l . cos = Lz / L .41.1.IDENTIFY and SET UP:EXECUTE: (a) l = 0 : L = 0 , Lz = 0 . l = 1: L = 2 , Lz = ,0, - . l = 2 : L = 6 , Lz = 2 , ,0, - , -2 . (b) In each case cos
UCLA - MAE - 162D
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UCLA - MAE - 162D
NUCLEAR PHYSICS4343.1.(a) (b) (c)28 14 85 37Si has 14 protons and 14 neutrons. Rb has 37 protons and 48 neutrons. Tl has 81 protons and 124 neutrons.205 8143.2.(a) Using R = (1.2 fm)A1 3 , the radii are roughly 3.6 fm, 5.3 fm, and 7.1 fm. (b) Usin
SUNY Stony Brook - BUS - 220
BUS 220 Introduction to Decision ScienceSpring 2012Assignment 3 due on Thursday, 3/29, 2012NOTE: The assignment could be done jointly by (at most) 2 students. (Of course, it can bedone by a single person.) In any case, the cover page indicating only s
Columbia - IEOR - 4703
IEOR 4703: Homework 5This assignment will help you understand how variance reduction works in real applications. For our first problem: You will estimate the price of a European call option, even though we know the price exactly via Black-Scholes option
Columbia - IEOR - 4703
IEOR 4703: Homework 51. SOLUTION: %Naive Monte Carlo method for K=34, N=300 clear all K=34; S0=35; r=0.05; sigma=0.04; mu=r-sigma^2/2; T=4; N=300; B=randn(1,N); X=mu*T*ones(1,N)+sqrt(T)*sigma*B; S=S0*exp(X); payoff=max(0,S-K*ones(1,N); X_bar=mean(payoff)
Columbia - IEOR - 4703
IEOR 4703: Homework 6Refer to the Lecture Notes 8 (Importance Sampling) (and Class Lecture 7) for the basics needed for this assignment. (Only Problems 3(c)(d) requires programming/simulating.) 1. Consider the random walk Rk = 1 + +k , R0 = 0, in which t
Columbia - IEOR - 4703
IEOR 4703: Solutions to Homework 6Refer to the Lecture Notes 8 (Importance Sampling) (and Class Lecture 7) for the basics needed for this assignment. (Only Problems 3(c)(d) requires programming/simulating.) 1. Consider the random walk Rk = 1 + +k , R0 =
Columbia - IEOR - 4703
IEOR 4703: Homework 71. Consider the problem of estimating(x) = E[eZIcfw_Zx ] Zfor x 1 and where Z N(0, 1). Let X := eIcfw_Zx .(a) Show that (x) (1 - (x)e x where (.) is the CDF of a standard normal random variable. (b) Show that E[X 2 ] (1 - (x)e
Columbia - IEOR - 4703
IEOR 4703: Solutions to Homework 71. Consider the problem of estimating(x) = E[eZIcfw_Zx ] Zfor x 1 and where Z N(0, 1). Let X := eIcfw_Zx .(a) Show that (x) (1 - (x)e x where (.) is the CDF of a standard normal random variable. SOLUTION: Observe
Columbia - IEOR - 4703
IEOR 4703: Homework 8Given a stochastic differential equation (SDE) for a diffusion, dX(t) = a(X(t)dt + b(X(t)dB(t), X(0) = X0 , where cfw_B(t) : t 0 denotes a standard BM, the Euler method for approximating the sample paths of X = cfw_X(t) : 0 t T is g
Columbia - IEOR - 4703
IEOR 4703: Solutions to Homework 81. SOLUTION: clear all close all r=0.05; sigma=0.04; mu=r-sigma^2/2; S0=35; t=4; %Exact Simulation (for your reference) M=10000; X=mu+sigma*randn(t,M); X=tril(ones(t,t)*X; S1=S0*exp(X); Y1=exp(-r*t)*max(0,mean(S1)-40); o
Columbia - IEOR - 4703
IEOR 4703: Homework 91. Gibbs sampler for a closed Jackson queueing network: (READ LECTURE NOTES 10 FOR REFERENCE HERE; SECTION 2.2) Consider a closed queueing network with c = 10 nodes (single-server FIFO queues), and M = 50 customers, in which the 10 1
Columbia - IEOR - 4703
IEOR 4703: Solutions to Homework 9rho=1/10*(1:9); M=50; x=5*ones(1,9); n=10000 N=zeros(9,n); N(:,1)=x; for k=1:n-1 N(:,k+1)=N(:,k); i=ceil(rand*9); B=M-sum(N(:,k)+N(i,k); y=floor(log(rand)/log(rho(i); while (y>B) y=floor(log(rand)/log(rho(i); end N(i,k+1
Columbia - IEOR - 4703
IEOR 4701: Solutions to review of probability problems1. (a) f (x) =xe-x , if x 0; 0, if x < 0.F (x) =0 -x dx 0 xef (y)dy = 1 - e-x , x 0E(X) = = 1/ via integration by parts (U = x, dV = e-x dx). Via integrating the tail, P (X > x) = 1 - F (x) = e-
Columbia - IEOR - 4703
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Columbia - IEOR - 4703
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Columbia - IEOR - 4703
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Columbia - IEOR - 4703
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Georgia Tech - CHEM - 2311
IR Spectroscopy Details of Interest1. Alkanesa. Pretty boring landscape throughoutb. Sharp C-H stretch just below 3000 down to around 2850 or soc. Notable C-H scissoring at 1470 and methyl rock 13832. Alkenesa. =C-H Stretch 3100-3000 (not necessaril
Columbia - IEOR - 4703
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Columbia - IEOR - 4703
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Columbia - IEOR - 4703
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Columbia - IEOR - 4703
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Columbia - IEOR - 4703
IEOR E4703: Practice Midterm Exam, Fall 2010. Professor Sigman. 1. X1 and X2 are two independent random variables distributed as: P (X1 = 0) = 0.30, P (X1 = 1) = 0.50, P (X1 = 2) = 0.20 and P (X2 = 1) = 0.40, P (X2 = 3) = 0.60 (a) Give an algorithm for ge
Columbia - IEOR - 4703
IEOR E4703: Practice Midterm Exam With Solutions, Fall 2010. Professor Sigman. 1. X1 and X2 are two independent random variables distributed as: P (X1 = 0) = 0.30, P (X1 = 1) = 0.50, P (X1 = 2) = 0.20 and P (X2 = 1) = 0.40, P (X2 = 3) = 0.60 (a) Give an a
Columbia - IEOR - 4703
Copyright c 2010 by Karl Sigman1Coupling from the past for Markov chainsGiven a discrete-time Markov chain (MC) cfw_Xn : n 0, with state space S (assumed here to be discrete), and transition matrix P = (Pij ) that is known to have a unique stationary (
Columbia - IEOR - 4703
Copyright c 2010 by Karl Sigman1Rare event simulation and importance samplingSuppose we wish to use Monte Carlo simulation to estimate a probability p = P (A) when the event A is "rare" (e.g., when p is very small). An example would be p = P (Mk > b) w
Columbia - IEOR - 4703
Copyright c 2010 by Karl Sigman1Rare event simulation and importance samplingSuppose we wish to use Monte Carlo simulation to estimate a probability p = P (A) when the event A is "rare" (e.g., when p is very small). An example would be p = P (Mk > b) w
Columbia - IEOR - 4703
Copyright c 2010 by Karl Sigman1Markov Chain Monte Carlo Methods (MCMC)There are many applications in which it is desirable to simulate from a probability distribution (say) in which all specifics of the distribution (cdf, density, etc.) are not known
Columbia - IEOR - 4703
Copyright c 2007 by Karl Sigman1Estimating sensitivitiesWhen estimating the Greeks, such as the , the general problem involves a random variable Y = Y () (such as a discounted payoff) that depends on a parameter of interest (such as initial def price S
Columbia - IEOR - 4706
Columbia University Instructor: Rama CONT Assignment 1. Bond pricing. Assignments should be done individually.M.S. in Financial Engineering Summer 2011.IEOR 4706: Foundations of Financial EngineeringThe table below shows the term structure of (annually
Columbia - IEOR - 4706
Columbia UniversityIEOR 4706: Foundations of Financial EngineeringM.S. in Financial Engineering Summer 2011.Instructor: Rama CONT TA: Jinbeom Kim Assignment 1. Bond pricing.Assignments should be done individually. The table below shows the term struct
Columbia - IEOR - 4706
Columbia - IEOR - 4706
Columbia University Instructor: Rama CONTM.S. in Financial Engineering Summer 2011.IEOR 4706: Foundations of Financial EngineeringSolution for Assignment 3. Arbitrage relations. Part I: Consider an arbitrage-free market in which investors can trade in
Columbia - IEOR - 4706
Columbia - IEOR - 4706
Columbia - IEOR - 4500
IEOR 4500 Introduction to Portfolio OptimizationReferences: The classical reference is Portfolio Selection: Efficient Diversification of Investments, by Harry Markowitz. A more modern reference is: Modern Portfolio Theory and Investment Analysis, by Elto
Columbia - IEOR - 4731
IEOR E4731: Credit Risk and Credit DerivativesLecture 01: Default risk, credit risk and the risk structure of interest ratesNotes originally written by Prof. Rama ContInstructor: Xuedong HeSpring, 20121 / 23The term structure of interest rates1$ at
Columbia - IEOR - 4731
IEOR E4731: Credit Risk and Credit DerivativesLecture 02: Market for credit riskNotes originally written by Prof. Rama ContInstructor: Xuedong HeSpring, 20121 / 28Credit derivativesDerivative instruments with payoffs linked to the occurrence of a c
Columbia - IEOR - 4731
IEOR E4731: Credit Risk and Credit DerivativesLecture 03: Risk Neutral Pricing. Basic arbitrage relations.Notes originally written by Prof. Rama ContInstructor: Xuedong HeSpring, 20121 / 28Single-name credit derivativesSingle-name credit derivative
Columbia - IEOR - 4731
IEOR E4731: Credit Risk and Credit DerivativesLecture 04: Structural models of default.Notes originally written by Prof. Rama ContInstructor: Xuedong HeSpring, 20121 / 46Capital structure of a firmThe structural approach to default modeling was ini
Columbia - IEOR - 4731
IEOR E4731: Credit Risk and Credit DerivativesLecture 05: Reduced form models.Notes originally written by Prof. Rama ContInstructor: Xuedong HeSpring, 20121 / 40Reduced form modelsStructural models have strong economic meaning but are not applicabl
Columbia - IEOR - 4731
IEOR E4731: Credit Risk and Credit DerivativesLecture 06: Pricing CDSNotes originally written by Prof. Rama ContInstructor: Xuedong HeSpring, 20121 / 32Pricing CDSIn this lecture, we are going to use reduced form models to price CDS We need to deci