Fundamentals of Physics Extended
10th Edition
ISBN: 9781118230725
Author: David Halliday, Robert Resnick, Jearl Walker
Publisher: Wiley, John & Sons, Incorporated
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Chapter 22, Problem 53P
GO Two large parallel copper plates are 5.0 cm apart and have a uniform electric field between them as depicted in Fig. 22-60. An electron is released from the negative plate at the same time that a proton is released from the positive plate. Neglect the force of the particles on each other and find their distance from the positive plate when they pass each other. (Does it surprise you that you need not know the electric field to solve this problem?)
Figure 22-60 Problem 53.
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Students have asked these similar questions
84 In Fig. 22-68, a uniform, upward
electric field E of magnitude 2.00 x
10° N/C has been set up between two
horizontal plates by charging the
lower plate positively and the upper
plate negatively. The plates have Figure 22-68 Problem 84.
length L = 10.0 cm and separation d
= 2.00 cm. An electron is then shot
between the plates from the left edge of the lower plate. The initial
velocity vo of the electron makes an angle e = 45.0° with the lower
plate and has a magnitude of 6.00 x 10° m/s. (a) Will the electron
strike one of the plates? (b) If so, which plate and how far horizon-
tally from the left edge will the electron strike?
7.
1:0
54 o In Fig. 22-61, an electron is
shot at an initial speed of
Detecting
screen
Vo = 2.00 x 10° m/s, at angle 6 =
40.0° from an x axis. It moves
through a uniform electric field
E = (5.00 N/C)j. A screen for de-
tecting electrons is positioned par-
allel to the y axis, at distance x = 3.00 m. In unit-vector notation,
what is the velocity of the electron when it hits the screen?
Figure 22-61 Problem 54.
*61. ssm A cube is located with one corner situated at the origin of an x, y,
z coordinate system. One of the cube's faces lies in the x, y plane, another
in the y, z plane, and another in the x, z plane. In other words, the cube is in
the first octant of the coordinate system. The edges of the cube are 0.20 m
long. A uniform electric field is parallel to the x, y plane and points in the
direction of the +y axis. The magnitude of the field is 1500 N/C. (a) Using
the outward normal for each face of the cube, find the electric flux through
each of the six faces. (b) Add the six values obtained in part (a) to show that
the electric flux through the cubical surface is zero, as Gauss' law predicts,
since there is no net charge within the cube.
Chapter 22 Solutions
Fundamentals of Physics Extended
Ch. 22 - Figure 22-22 shows three arrangements of electric...Ch. 22 - Figure 22-23 shows two square arrays of charged...Ch. 22 - In Fig. 22-24, two particles of charge q are...Ch. 22 - Figure 22-25 shows four situations in which four...Ch. 22 - Figure 22-26 shows two charged particles fixed in...Ch. 22 - In Fig. 22-27, two identical circular...Ch. 22 - The potential energies associated with four...Ch. 22 - a In Checkpoint 4, if the dipole rotates from...Ch. 22 - Figure 22-28 shows two disks and a flat ring, each...Ch. 22 - In Fig. 22-29, an electron e travels through a...
Ch. 22 - In Fig. 22-30a, a circular plastic rod with...Ch. 22 - When three electric dipoles ire near each other,...Ch. 22 - Figure 22-32 shows three rods, each with the same...Ch. 22 - Figure 22-33 shows five protons that are launched...Ch. 22 - Sketch qualitatively the electric field lines both...Ch. 22 - In Fig. 22-34 the electric field lines on the left...Ch. 22 - SSM The nucleus of a plutonium-239 atom contains...Ch. 22 - Two charged particles are attached to an x axis:...Ch. 22 - SSM A charged particle produces an electric Held...Ch. 22 - What is the magnitude of a point charge that would...Ch. 22 - SSM ILW WWW In Fig. 22-35, the four particles form...Ch. 22 - GO In Fig. 22-36, the four particles are fixed in...Ch. 22 - GO Figure 22-37 shows two charged particles on an...Ch. 22 - GO Figure 22-38a shows two charged particles fixed...Ch. 22 - SSM Two charged particles are fixed to x axis:...Ch. 22 - GO Figure 22-39 shows an uneven arrangement of...Ch. 22 - GO Figure 22-40 shows a proton on the central...Ch. 22 - In Fig. 22-41, particle 1 of charge q1 = 5.00q and...Ch. 22 - In Fig. 22-42, the three particles are fixed in...Ch. 22 - Figure 22-43 shows a plastic ring of radius R =...Ch. 22 - Two charged beads are on the plastic ring in Fig....Ch. 22 - The electric field of an electric dipole along the...Ch. 22 - Figure 22-45 shows an electric dipole. What are...Ch. 22 - Equations 22-8 and 22-9 are approximations of the...Ch. 22 - SSM Electric quadrupole. Figure 22-46 shows a...Ch. 22 - Density, density, density. a A charge 300e is...Ch. 22 - Figure 22-47 shows two parallel nonconducting...Ch. 22 - A thin nonconducting rod with a uniform...Ch. 22 - Figure 22-49 shows three circular arcs centered on...Ch. 22 - GO ILW In Fig. 22-50, a thin glass rod forms a...Ch. 22 - GO In Fig, 22-51, two curved plastic rods, one of...Ch. 22 - Charge is uniformly distributed around a ring of...Ch. 22 - GO Figure 22-52a shows a nonconducting rod with a...Ch. 22 - GO Figure 22-53 shows two concentric rings, of...Ch. 22 - SSM ILW WWW In Fig. 22-54, a nonconducting rod of...Ch. 22 - GO In Fig. 22-55, positive charge q = 7.81 pC is...Ch. 22 - GO In Fig. 22-56, a semi-infinite nonconducting...Ch. 22 - A disk of radius 2.5 cm has a surface charge...Ch. 22 - SSM WWW At what distance along the central...Ch. 22 - A circular plastic disk with radius R = 2.00 cm...Ch. 22 - Suppose you design an apparatus in which a...Ch. 22 - Figure 22-58a shows a circular disk that is...Ch. 22 - In Millikans experiment, an oil drop of radius...Ch. 22 - GO An electron with a speed of 5.00 108 cm/s...Ch. 22 - SSM A charged cloud system produces an electric...Ch. 22 - Humid air breaks down its molecules become ionized...Ch. 22 - SSM An electron is released from rest in a uniform...Ch. 22 - An alpha particle the nucleus of a helium atom has...Ch. 22 - ILW An electron on the axis of an electric dipole...Ch. 22 - An electron is accelerated eastward at 1.80 ...Ch. 22 - SSM Beams of high-speed protons can be produced in...Ch. 22 - In Fig. 22-59, an electron e is to be released...Ch. 22 - A 10.0 g block with a charge of 8.00 10-5 C is...Ch. 22 - At some instant the velocity components of an...Ch. 22 - Assume that a honeybee is a sphere of diameter...Ch. 22 - An electron eaters a region of uniform electric...Ch. 22 - GO Two large parallel copper plates are 5.0 cm...Ch. 22 - GO In Fig. 22-61, an electron is shot at an...Ch. 22 - ILW A uniform electric field exists in a region...Ch. 22 - An electric dipole consists of charges 2e and -2e...Ch. 22 - SSM An electric dipole consisting of charges of...Ch. 22 - A certain electric dipole is placed in a uniform...Ch. 22 - How much work is required to turn an electric...Ch. 22 - A certain electric dipole is placed in a uniform...Ch. 22 - Find an expression for the oscillation frequency...Ch. 22 - a What is the magnitude of an electrons...Ch. 22 - A spherical water drop 1.20 m in diameter is...Ch. 22 - Three particles, each with positive charge Q, form...Ch. 22 - In Fig. 22-64a, a particle of charge Q produces an...Ch. 22 - A proton and an electron form two comers of an...Ch. 22 - A charge uniform linear density = 9.0 nC/m lies on...Ch. 22 - In Fig. 22-65, eight particles form a square in...Ch. 22 - Two particles, each with a charge of magnitude 12...Ch. 22 - The following table gives the charge seen by...Ch. 22 - A charge of 20 nC is uniformly distributed along a...Ch. 22 - An electron is constrained to the central axis of...Ch. 22 - SSM The electric field in an xy plane produced by...Ch. 22 - a What total excess charge q must the disk in Fig....Ch. 22 - In Fig. 22-66, particle 1 of charge 1.00 C,...Ch. 22 - In Fig. 22-67, an electric dipole swings from an...Ch. 22 - A particle of charge q1 is at the origin of an x...Ch. 22 - Two particles, each of positive charge q, are...Ch. 22 - A clock face has negative point charges q, 2q,...Ch. 22 - Calculate the electric dipole moment of an...Ch. 22 - An electric field E with an average magnitude of...Ch. 22 - A circular rod has a radius of curvature R = 9.00...Ch. 22 - SSM An electric dipole with dipole moment p= 3.00 ...Ch. 22 - In Fig. 22-68, a uniform, upward electric field E...Ch. 22 - For the data of Problem 70, assume that the charge...Ch. 22 - In Fig. 22-66, particle 1 of charge 2.00 pC,...Ch. 22 - In Fig. 22-69, particle 1 of charge q1 = 1.00pC...
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