Deck 33: Electromagnetic Waves

A) in the +x direction and in phase with the field
B) in the -x direction and in phase with the field
C) in the +x direction and 1/4 wave out of phase with the field
D) in the +z direction and in phase with the field
E) in the +z direction and 1/4 wave out of phase with the field

A) any moving charge
B) any accelerating charge
C) only a charge with changing acceleration
D) only a charge moving in a circle
E) only a charge moving in a straight line

A)
B)
C)
D)
E)

A) an increasing function of frequency
B) a decreasing function of frequency
C) independent of frequency
D) a function of the distance from the source
E) a function of the size of the source

A) 5 * 10¹⁸ Hz
B) 5 * 10¹⁶ Hz
C) 5 * 10¹⁴ Hz
D) 5 * 10¹² Hz
E) 5 *10¹⁰ Hz

A) r, v, i, x, u
B) r, i, v, u, x
C) i, r, v, u, x
D) i, v, r, u, x
E) r, i, v, x, u

A) 1 MHz
B) 9 MHz
C) 100 MHz
D) 10,000 MHz
E) 900 MHz

A) (velocity)²
B) (velocity)^1/2
C) 1/velocity
D) 1/velocity²
E) 1/velocity^1/2

A) 1.3 s
B) 2.5 s
C) 8 s
D) 8 min
E) 1 *10⁶ s

A) just slightly greater than that of red light
B) just slightly less than that of blue light
C) the greatest x-ray frequency
D) none of the above (there is no upper limit)
E) none of the above (but there is an upper limit)

A) ultraviolet light has a longer wavelength than infrared
B) blue light has a higher frequency than x rays
C) radio waves have higher frequency than gamma rays
D) gamma rays have higher frequency than infra-red waves
E) electrons are a type of electromagnetic wave

A) 10^-6 kHz
B) 500 kHz
C) 1 MHz
D) 9 MHz
E) 108 kHz

A) travel slower
B) have a higher frequency
C) travel faster
D) have a lower frequency
E) require a material medium

A) 4.5 * 10¹⁸ s
B) 8 s
C) 8 min
D) 8 hr
E) 8 yr

A) Radio waves
B) Visible light
C) X rays
D) Gamma rays
E) All of these travel at the same speed

A) red light
B) violet light
C) blue light
D) green light
E) none of these (they are equally sensitive to all colors)

A) 1100 ft/s
B) 93* 10⁶ mi/s
C) 6 *10²³ m/s
D) 3 *10¹⁰ cm/s
E) 186,000 mph

A) they consist of changing electric and magnetic fields
B) they travel at different speeds in vacuum, depending on their frequency
C) they transport energy
D) they transport momentum
E) they can be reflected

A) r, y, g, b
B) r, g, y, b
C) g, y, b, r
D) b, g, y, r
E) b, y, g, r

A) 3.3 * 10^-7 T
B) 6.7 * 10^-7 T
C) 0.27 T
D) 8.0 *10⁷ T
E) 3.0*10⁹ T

A) the speed of light
B) an increasing function of frequency
C) a decreasing function of frequency
D)
E)

A) overwhelmingly electrical
B) slightly more electrical than magnetic
C) equally divided between the electric and magnetic fields
D) slightly more magnetic than electrical
E) overwhelmingly magnetic

A) (cB_m)cos(kx - $\omega$ t)
B) -(cB_m/c)cos(kx - $\omega$ t)
C) -(cB_m/c))sin(kx - $\omega$ t)
D) B_mcos(kx - $\omega$ t)
E) (cB_m/c))sin(kx - $\omega$ t)

A) the radiation pressure increases and the radiation force increases
B) the radiation pressure increases and the radiation force decreases
C) the radiation pressure stays the same and the radiation force increases
D) the radiation pressure stays the same and the radiation force decreases
E) the radiation preassure decreases and the radiation force decreases

A) 1.3 mJ
B) 13 mJ
C) 27 mJ
D) 130 mJ
E) 270 mJ

A) 1 kPa
B) 3 * 10¹¹ Pa
C) 1.7 * 10^-6 Pa
D) 3.3 * 10^-6 Pa
E) 6.7 * 10^-6 Pa

A) the tail of a comet points away from the sun
B) electron flow through a wire generates heat
C) a charged particle in a magnetic field moves in a circular orbit
D) heat can be generated by rubbing two sticks together
E) the Doppler effect

A) (E_m/c)cos(kx + $\omega$ t)
B) -(E_m/c)cos(kx + $\omega$ t)
C) -(E_m/c)sin(kx + $\omega$ t)
D) E_mcos(kx + $\omega$ t)
E) (E_m/c)sin(kx + $\omega$ t)

A) 3
B) 9
C) 1/3
D) 1/9
E) 1

A) 1.7* 10^-4 W/m²
B) 13 W/m²
C) 27 W/m²
D) 1.0 *10⁵ W/m²
E) 4.0 * 10¹⁰ W/m²

A) A
B) B
C) C
D) D
E) E

A) 1000 W/m²
B) 100 W/m²
C) 10 W/m²
D) 1 W/m²
E) 0.1 W/m²

A) the direction of the electric field
B) the direction of the magnetic field
C) the direction of wave propagation
D) the direction of the electromagnetic force on a proton
E) the direction of the emf induced by the wave

A) J/m²
B) J/s
C) W/s
D) W/m²
E) J/m³

A) 1 kPa
B) 3 *10¹¹ Pa
C) 1.7 * 10^-6 Pa
D) 3.3*10^-6 Pa
E) 6.7* 10^-6 Pa

A) positive y direction
B) negative y direction
C) positive z direction
D) negative z direction
E) negative x direction

A) 10 W/m²
B) 1.6 W/m²
C) 1 W/m²
D) 0.024W/m²
E) 0.080 W/m²

A) $\partial$ E/ $\partial$ x = $\mu$ ₀ $\varepsilon$ ₀ $\partial$ B/ $\partial$ x
B) $\partial$ E/ $\partial$ x = $\mu$ ₀ $\varepsilon$ ₀ $\partial$ B/ $\partial$ t
C) $\partial$ B/ $\partial$ x = $\mu$ ₀ $\varepsilon$ ₀ $\partial$ E/ $\partial$ x
D) $\partial$ B/ $\partial$ x = $\mu$ ₀ $\varepsilon$ ₀ $\partial$ E/ $\partial$ t
E) $\partial$ B/ $\partial$ x = - $\mu$ ₀ $\varepsilon$ ₀ $\partial$ E/ $\partial$ t

A) Energy is being transported in the positive x direction but half a cycle later, when the electric field is in the opposite direction, it will be transported in the negative x direction
B) Energy is being transported in the positive x direction and half a cycle later, when the electric field is in the opposite direction, it will still be transported in the positive x direction
C) Energy is being transported in the negative x direction but half a cycle later, when the electric field is in the opposite direction, it will be transported in the positive x direction
D) Energy is being transported in the negative x direction and half a cycle later, when the electric field is in the opposite direction, it will still be transported in the negative x direction.
E) None of the above are true.

A) impossible
B) possible, but very expensive
C) inexpensive and already in common use
D) in use by NASA but is not commercially available
E) a breakthrough in high technology

A) m/s
B) s/m
C) radian
D) m/s²
E) none of these

A) 1.0 * 10^-4 N
B) 3.3 * 10^-11 N
C) 1.7 * 10^-10 N
D) 3.3 * 10^-10 N
E) 6.7 * 10^-10 N

A) the speed of light in the substance
B) the angle of refraction
C) the angle of incidence
D) the speed of light in vacuum divided by the speed of light in the substance
E) measured in radians

A) 0
B) 30 $\degree$
C) 45 $\degree$
D) 60 $\degree$
E) 90 $\degree$

A) Gauss' law
B) Snell's law
C) Faraday's law
D) Cole's law
E) law of sines

A) 1:4
B) 1:3
C) 1:2
D) 3:4
E) 3:8

A) a longitudinal wave
B) a stream of particles
C) a transverse wave
D) some type of wave
E) nearly monochromatic

A) perpendicular to both the direction of polarization and the direction of propagation
B) perpendicular to the direction of polarization and parallel to the direction of propagation
C) parallel to the direction of polarization and perpendicular to the direction of propagation
D) parallel to both the direction of polarization and the direction of propagation
E) none of the above

A) sin^-1(1/2)
B)
C) cos^-1(1/2)
D)
E) tan^-1(1/4)

A) 1, 2, 3, 4
B) 4, 2, 1, 3
C) 2, 4, 3, 1
D) 2, 4, 1, 3
E) 3, 1, 4, 2

A) unpolarized
B) plane polarized
C) circularly polarized
D) elliptically polarized
E) monochromatic

A) has no direction at any time
B) rotates rapidly
C) is always parallel to the direction of propagation
D) changes direction randomly and often
E) remains along the same line but reverses direction randomly and often

A) Faraday's law
B) Snell's law
C) Ampere's law
D) Cole's law
E) none of these

A) horizontally
B) in circles around the antenna
C) vertically
D) normal to the antenna in the forward direction
E) none of the above

A) the material of the reflecting surface
B) the angle of incidence
C) the index of the medium
D) the intensity of the wave
E) the wavelength

A) 1/2
B) 1/3
C) 1/4
D) 1/8
E) 0

A) any convenient direction
B) tangent to the interface
C) along the incident ray
D) perpendicular to the electric field vector of the light
E) perpendicular to the interface

A) 1.0 * 10^-4 N
B) 3.3 * 10^-11 N
C) 1.7 * 10^-10 N
D) 3.3 * 10^-10 N
E) 6.7 *10^-10 N

A) 0
B) 30 $\degree$
C) 45 $\degree$
D) 60 $\degree$
E) all angles allow light to pass through

A) occurs whenever the light goes from glass to water
B) occurs whenever the light goes from water to glass
C) may occur when the light goes from glass to water
D) may occur when the light goes from water to glass
E) can never occur at this interface

A) v₁ > v₂ > v₃
B) v₃ > v₂ > v₁
C) v₃ > v₁ > v₂
D) v₂ > v₁ > v₃
E) v₁ > v₃ > v₂

A) 19 $\degree$
B) 22 $\degree$
C) 36 $\degree$
D) 42 $\degree$
E) 48 $\degree$

A) 0.53
B) 0.88
C) 1.9
D) 2.2
E) 3.0

A) both the speed and the frequency decrease
B) both the speed and the frequency increase
C) both the speed and the wavelength decrease
D) both the speed and the wavelength increase
E) both the wavelength and the frequency are unchanged

A) the speed of the light has increased
B) dispersion must occur
C) the second medium has a higher index of refraction
D) no change in speed has occurred
E) refraction has not occurred because refraction means a bending toward the normal

A) 0.50
B) 0.67
C) 0.75
D) 1.00
E) 1.50

A) slightly longer than the shadow of the pole on land
B) much longer than the shadow of the pole on land
C) shorter than the shadow of the pole on land
D) shorter than the shadow of the pole on land if the sun is high and longer if the sun is low
E) the same length as the shadow of the pole on land

A) 1.75
B) 1.67
C) 1.50
D) 1.33
E) 1.25

A) at least 2.0
B) at most 2.0
C) at least 1.15
D) at most 1.15
E) cannot be calculated from the given data

A) sin^-1(1.00)
B) sin^-1(1/n₁)
C) sin^-1(1/n₂)
D) sin^-1(n₁/n₂)
E) sin^-1(n₂/n₁)

A) total internal reflection
B) partial reflection from each surface
C) variation of index of refraction with wavelength
D) a decrease in the speed of light in the glass
E) selective absorption of various colors

A) angle AON is the angle of incidence
B) angle AON = angle BON
C) angle AON must be the critical angle
D) the speed of light in medium II is greater than that in medium I
E) if angle AON were increased, there would still be total internal reflection

A) air and $\theta$ = 25 $\degree$
B) air and $\theta$ > 25 $\degree$
C) air and $\theta$ < 25 $\degree$
D) diamond and $\theta$ < 25 $\degree$
E) diamond and $\theta$ > 25 $\degree$

A) (sin a)/(sin b) = 2.5
B) (sin b)/(sin d) = 2.5
C) (cos a)/(cos c) = 2.5
D) (sin a)/(sin c) = 1/(2.5)
E) a/c = 2.5

A) I
B) II
C) III
D) IV
E) V

A) 56 $\degree$
B) 47 $\degree$
C) 34 $\degree$
D) 22 $\degree$
E) 18 $\degree$

A) toward the normal without changing speed
B) toward the normal and slows down
C) toward the normal and speeds up
D) away from the normal and slows down
E) away from the normal and speeds up

A) is totally internally reflected
B) is bent more toward the normal than the incident ray
C) is bent further away from the normal than the incident ray
D) is parallel to the incident ray but displaced sideways
E) lies on the same straight line as the incident ray