FUND PHYS 10TH EXT WILEY PLUS
10th Edition
ISBN: 9781119500100
Author: Halliday
Publisher: MCGRAW-HILL HIGHER EDUCATION
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Textbook Question
Chapter 23, Problem 64P
Equation 23-11 (E = σ/ε0) gives the electric field at points near a charged
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4.4 A man is dragging a trunk up the
loading ramp of a mover's truck. The
ramp has a slope angle of 20.0°, and
the man pulls upward with a force F
whose direction makes an angle of 30.0°
75.0°
with the ramp (Fig. E4.4). (a) How large a force F is necessary for the
component Fx parallel to the ramp to be 90.0 N? (b) How large will the
component Fy perpendicular to the ramp be then?
Figure E4.4
30.0
20.0°
1.
*
A projectile is shot from a launcher at an angle e, with an initial velocity
magnitude v., from a point even with a tabletop. The projectile lands on the tabletop
a horizontal distance R (the "range") away from where it left the launcher. Set this
up as a formal problem, and solve for vo (i.e., determine an expression for Vo in
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Chapter 23 Solutions
FUND PHYS 10TH EXT WILEY PLUS
Ch. 23 - A surface has the area vector A = 2 i 3 j m2....Ch. 23 - Figure 23-22 shows, in cross section, three solid...Ch. 23 - Figure 23-23 shows, in cross section, a central...Ch. 23 - Figure 23-24 shows, in cross section, two Gaussian...Ch. 23 - In Fig. 23-25, an election is released between two...Ch. 23 - Three infinite nonconducting sheets, with uniform...Ch. 23 - Figure 23-26 shows four situations in which four...Ch. 23 - Figure 23-27 shows four solid spheres, each with...Ch. 23 - A small charged ball lies within the hollow of a...Ch. 23 - Rank the situations of Question 9 according to the...
Ch. 23 - Figure 23-28 shows a section of three long charged...Ch. 23 - Figure 23-29 shows four Gaussian surfaces...Ch. 23 - SSM The square surface shown in Fig. 23-30...Ch. 23 - An electric field given by E = 4.0 i 3.0y2 2.0 j...Ch. 23 - The cube in Fig. 23-31 has edge length 1.40 m and...Ch. 23 - In Fig. 23-32, a butterfly net is in a uniform...Ch. 23 - In Fig. 23-33, a proton is a distance d/2 directly...Ch. 23 - At each point on the surface of the cube shown in...Ch. 23 - A particle of charge 1.8 C is at the center of a...Ch. 23 - When a shower is turned on in a dosed bathroom,...Ch. 23 - ILW Fig. 23-31 shows a Gaussian surface in the...Ch. 23 - Figure 23-34 shows a closed Gaussian surface in...Ch. 23 - GO Figure 23-35 shows a dosed Gaussian surface in...Ch. 23 - Figure 23-36 shows two non-conducting spherical...Ch. 23 - SSM The electric field in a certain region of...Ch. 23 - GO Flux and nonconducting shells. A charged...Ch. 23 - A particle of charge q is placed at one corner of...Ch. 23 - GO The box-like Gaussian surface shown in Fig....Ch. 23 - SSM A uniformly charged conducting sphere of 1.2 m...Ch. 23 - The electric field just above the surface of the...Ch. 23 - Space vehicles traveling through Earths radiation...Ch. 23 - GO Flux and conducting shells. A charged particle...Ch. 23 - An isolated conductor has net charge 10 106 C and...Ch. 23 - An electron is released 9.0 cm from a very long...Ch. 23 - a The drum of a photocopying machine has a length...Ch. 23 - Figure 23-40 shows a section of a long,...Ch. 23 - SSM An infinite line of charge produces a field of...Ch. 23 - Figure 23-41a shows a narrow charged solid...Ch. 23 - GO A long, straight wire has fixed negative charge...Ch. 23 - GO A charge of uniform linear density 2.0 nC/m is...Ch. 23 - SSM WWW Figure 23-42 is a section of a conducting...Ch. 23 - In Fig. 23-43, short sections of two very long...Ch. 23 - ILW Two long, charged, thin-walled, concentric...Ch. 23 - GO A long, nonconducting, solid cylinder of radius...Ch. 23 - In Fig. 23-44, two large, thin metal plates are...Ch. 23 - In Fig. 23-45, a small circular hole of radius R =...Ch. 23 - GO Figure 23-46a shows three plastic sheets that...Ch. 23 - Figure 23-47 shows cross sections through two...Ch. 23 - SSM WWW A square metal plate of edge length 8.0 cm...Ch. 23 - GO In Fig. 23-48a, an electron is shot directly...Ch. 23 - SSM In Fig. 23-49, a small, nonconducting ball of...Ch. 23 - Figure 23-50 shows a very large nonconducting...Ch. 23 - GO An electron is shot directly toward the center...Ch. 23 - Two large metal plates of area 1.0 m2 face each...Ch. 23 - GO Figure 23-51 shows a cross section through a...Ch. 23 - Figure 23-52 gives the magnitude of the electric...Ch. 23 - Two charged concentric spherical shells have radii...Ch. 23 - Assume that a ball of charged particles has a...Ch. 23 - SSM An unknown charge sits on a conducting solid...Ch. 23 - GO A charged particle is held at the center of a...Ch. 23 - In Fig, 23-54, a solid sphere of radius a = 2.00...Ch. 23 - GO Figure 23-55 shows two nonconducting spherical...Ch. 23 - SSM WWW In Fig. 23-56, a nonconducting spherical...Ch. 23 - GO Figure 23-57 shows a spherical shell with...Ch. 23 - ILW The volume charge density of a solid...Ch. 23 - Figure 23-58 shows, in cross section, two solid...Ch. 23 - A charge distribution that is spherically...Ch. 23 - The electric field in a particular space is E = x ...Ch. 23 - A thin-walled metal spherical shell has radius...Ch. 23 - A uniform surface charge of density 8.0 nC/m2 is...Ch. 23 - Charge of uniform volume density = 1.2 nC/m3...Ch. 23 - The chocolate crumb mystery. Explosions ignited by...Ch. 23 - SSM A thin-walled metal spherical shell of radius...Ch. 23 - A particle of charge q = 1.0 107 C is at the...Ch. 23 - A proton at speed v = 3.00 105 m/s orbits at...Ch. 23 - Equation 23-11 E = /0 gives the electric field at...Ch. 23 - Charge Q is uniformly distributed in a sphere of...Ch. 23 - A charged particle causes an electric flux of 750...Ch. 23 - SSM The electric field at point P just outside the...Ch. 23 - The net electric flux through each face of a die...Ch. 23 - Figure 23-59 shows, in cross section, three...Ch. 23 - Charge of uniform volume density = 3.2 C/m3 fills...Ch. 23 - A Gaussian surface in the form of a hemisphere of...Ch. 23 - What net charge is enclosed by the Gaussian cube...Ch. 23 - A nonconducting solid sphere has a uniform volume...Ch. 23 - A uniform charge density of 500 nC/m3 is...Ch. 23 - Figure 23-61 shows a Geiger counter, a device used...Ch. 23 - Charge is distributed uniformly throughout the...Ch. 23 - SSM A spherical conducting shell has a charge of...Ch. 23 - A charge of 6.00 pC is spread uniformly throughout...Ch. 23 - Water in an irrigation ditch of width w = 3.22 m...Ch. 23 - Charge of uniform surface density 8.00 nC/m2 is...Ch. 23 - A spherical ball at charged particles has a...
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- 2. A projectile is shot from a launcher at an angle 0,, with an initial velocity magnitude vo, from a point even with a tabletop. The projectile hits an apple atop a child's noggin (see Figure 1). The apple is a height y above the tabletop, and a horizontal distance x from the launcher. Set this up as a formal problem, and solve for x. That is, determine an expression for x in terms of only v₁, o,y and g. Actually, this is quite a long expression. So, if you want, you can determine an expression for x in terms of v., 0., and time t, and determine another expression for timet (in terms of v., 0., y and g) that you will solve and then substitute the value of t into the expression for x. Your final equation(s) will be called Equation 3 (and Equation 4).arrow_forward4.56 ... CALC An object of mass m is at rest in equilibrium at the origin. At t = 0 a new force F(t) is applied that has components Fx(t) = k₁ + k₂y Fy(t) = k3t where k₁, k2, and k3 are constants. Calculate the position (1) and veloc- ity (t) vectors as functions of time.arrow_forward4.14 ⚫ A 2.75 kg cat moves in a straight line (the x-axis). Figure E4.14 shows a graph of the x- component of this cat's velocity as a function of time. (a) Find the maximum net force on this cat. When does this force occur? (b) When is the net force on the cat equal to zero? (c) What is the net force at time 8.5 s? Figure E4.14 V₁ (m/s) 12.0 10.0 8.0 6.0 4.0 2.0 0 t(s) 2.0 4.0 6.0 8.0 10.0arrow_forward
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