- 31.31.1: How do fields transform?
- 31.31.2: What is Maxwells theory of electromagnetism?
- 31.31.3: What are electromagnetic waves?
- 31.31.4: What is polarization?
- 31.31.5: A laboratory experimenter has created the parallel electric and mag...
- 31.31.6: The first diagram shows electric and magnetic fields in reference f...
- 31.31.7: The 1.0 T field of a large laboratory magnet points straight up. A ...
- 31.31.8: The electric field in four identical capacitors is shown as a funct...
- 31.31.9: A 2.0-cm-diameter parallel-plate capacitor with a 1.0 mm spacing is...
- 31.31.10: An electromagnetic wave is propagating in the positive x-direction....
- 31.31.11: A digital cell phone broadcasts a 0.60 W signal at a frequency of 1...
- 31.31.12: An electromagnetic wave is traveling in the positive y-direction. T...
- 31.31.13: A low-cost way of sending spacecraft to other planets would be to u...
- 31.31.14: The amplitude of the oscillating electric field at your cell phone ...
- 31.31.15: Unpolarized light of equal intensity is incident on four pairs of p...
- 31.31.16: Future space rockets might propel themselves by firing laser beams,...
- 31.31.17: Andre is flying his spaceship to the left through the laboratory ma...
- 31.31.18: Sharon drives her rocket through the magnetic field of FIGURE Q31.2...
- 31.31.19: If you curl the fingers of your right hand as shown, are the electr...
- 31.31.20: What is the current through surface S in FIGURE Q31.4 if you curl y...
- 31.31.21: Is the electric field strength in FIGURE Q31.5 increasing, decreasi...
- 31.31.22: Do the situations in FIGURE Q31.6 represent possible electromagneti...
- 31.31.23: In what directions are the electromagnetic waves traveling in FIGUR...
- 31.31.24: The intensity of an electromagnetic wave is 10 W/m2 . What will the...
- 31.31.25: Older televisions used a loop antenna like the one in FIGURE Q31.9....
- 31.31.26: A vertically polarized electromagnetic wave passes through the five...
- 31.31.27: FIGURE EX31.1 shows the electric and magnetic field in frame A. A r...
- 31.31.28: A rocket cruises past a laboratory at 1.00 * 106 m/s in the positiv...
- 31.31.29: Laboratory scientists have created the electric and magnetic fields...
- 31.31.30: Scientists in the laboratory create a uniform electric field E u =1...
- 31.31.31: A rocket zooms past the earth at v = 2.0 * 106 m/s. Scientists on t...
- 31.31.32: The magnetic field is uniform over each face of the box shown in FI...
- 31.31.33: Show that the quantity P01de/dt2 has units of current.
- 31.31.34: Show that the displacement current inside a parallel-plate capacito...
- 31.31.35: What capacitance, in mF, has its potential difference increasing at...
- 31.31.36: A 5.0-cm-diameter parallel-plate capacitor has a 0.50 mm gap. What ...
- 31.31.37: A 10-cm-diameter parallel-plate capacitor has a 1.0 mm spacing. The...
- 31.31.38: What is the magnetic field amplitude of an electromagnetic wave who...
- 31.31.39: What is the electric field amplitude of an electromagnetic wave who...
- 31.31.40: The magnetic field of an electromagnetic wave in a vacuum is Bz = 1...
- 31.31.41: The electric field of an electromagnetic wave in a vacuum is Ey = 1...
- 31.31.42: a. What is the magnetic field amplitude of an electromagnetic wave ...
- 31.31.43: A radio wave is traveling in the negative y-direction. What is the ...
- 31.31.44: A radio receiver can detect signals with electric field amplitudes ...
- 31.31.45: A helium-neon laser emits a 1.0-mm-diameter laser beam with a power...
- 31.31.46: A radio antenna broadcasts a 1.0 MHz radio wave with 25 kW of power...
- 31.31.47: A 200 MW laser pulse is focused with a lens to a diameter of 2.0 mm...
- 31.31.48: A 1000 W carbon-dioxide laser emits light with a wavelength of 10 m...
- 31.31.49: At what distance from a 10 W point source of electromagnetic waves ...
- 31.31.50: Only 25% of the intensity of a polarized light wave passes through ...
- 31.31.51: FIGURE EX31.25 shows a vertically polarized radio wave of frequency...
- 31.31.52: Unpolarized light with intensity 350 W/m2 passes first through a po...
- 31.31.53: A 200 mW vertically polarized laser beam passes through a polarizin...
- 31.31.54: What are the electric field strength and direction at the position ...
- 31.31.55: What is the force (magnitude and direction) on the proton in FIGURE...
- 31.31.56: What electric field strength and direction will allow the proton in...
- 31.31.57: A proton is fired with a speed of 1.0 * 106 m/s through the paralle...
- 31.31.58: An electron travels with v u = 5.0 * 106 ni m/s through a point in ...
- 31.31.59: In FIGURE P31.33, a circular loop of radius r travels with speed v ...
- 31.31.60: The magnetic field inside a 4.0-cm-diameter superconducting solenoi...
- 31.31.61: A simple series circuit consists of a 150 resistor, a 25 V battery,...
- 31.31.62: A wire with conductivity s carries current I. The current is increa...
- 31.31.63: A 10 A current is charging a 1.0-cm-diameter parallel-plate capacit...
- 31.31.64: FIGURE P31.38 shows the voltage across a 0.10 mF capacitor. Draw a ...
- 31.31.65: FIGURE P31.39 shows the electric field inside a cylinder of radius ...
- 31.31.66: A long, thin superconducting wire carrying a 15 A current passes th...
- 31.31.67: A 1.0 mF capacitor is discharged, starting at t = 0 s. The displace...
- 31.31.68: At one instant, the electric and magnetic fields at one point of an...
- 31.31.69: a. Show that uE and uB, the energy densities of the electric and ma...
- 31.31.70: The intensity of sunlight reaching the earth is 1360 W/m2 . a. What...
- 31.31.71: Assume that a 7.0-cm-diameter, 100 W lightbulb radiates all its ene...
- 31.31.72: The electric field of a 450 MHz radio wave has a maximum rate of ch...
- 31.31.73: When the Voyager 2 spacecraft passed Neptune in 1989, it was 4.5 * ...
- 31.31.74: In reading the instruction manual that came with your garagedoor op...
- 31.31.75: The maximum electric field strength in air is 3.0 MV/m. Stronger el...
- 31.31.76: A LASIK vision-correction system uses a laser that emits 10-ns-long...
- 31.31.77: The intensity of sunlight reaching the earth is 1360 W/m2 . Assumin...
- 31.31.78: For radio and microwaves, the depth of penetration into the human b...
- 31.31.79: A laser beam shines straight up onto a flat, black foil of mass m. ...
- 31.31.80: For a science project, you would like to horizontally suspend an 8....
- 31.31.81: Youve recently read about a chemical laser that generates a 20-cm-d...
- 31.31.82: Unpolarized light of intensity I0 is incident on three polarizing f...
- 31.31.83: Unpolarized light of intensity I0 is incident on two polarizing fil...
- 31.31.84: Unpolarized light of intensity I0 is incident on a stack of 7 polar...
- 31.31.85: A cube of water 10 cm on a side is placed in a microwave beam havin...
- 31.31.86: An 80 kg astronaut has gone outside his space capsule to do some re...
- 31.31.87: An electron travels with v u = 5.0 * 106 ni m/s through a point in ...
- 31.31.88: The radar system at an airport broadcasts 11 GHz microwaves with 15...
- 31.31.89: Large quantities of dust should have been left behind after the cre...
- 31.31.90: Consider current I passing through a resistor of radius r, length L...
Solutions for Chapter 31: Electromagnetic Fields and Waves
Full solutions for Physics for Scientists and Engineers: A Strategic Approach, Standard Edition (Chs 1-36) | 4th Edition
ISBN: 9780134081496
Solutions for Chapter 31
26
4
Chapter 31: Electromagnetic Fields and Waves includes 90 full step-by-step solutions. This textbook survival guide was created for the textbook: Physics for Scientists and Engineers: A Strategic Approach, Standard Edition (Chs 1-36), edition: 4. Since 90 problems in chapter 31: Electromagnetic Fields and Waves have been answered, more than 249539 students have viewed full step-by-step solutions from this chapter. This expansive textbook survival guide covers the following chapters and their solutions. Physics for Scientists and Engineers: A Strategic Approach, Standard Edition (Chs 1-36) was written by and is associated to the ISBN: 9780134081496.
Key Physics Terms and definitions covered in this textbook
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parallel
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any symbol
average (indicated by a bar over a symbol—e.g., v¯ is average velocity)
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°C
Celsius degree
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°F
Fahrenheit degree