Deck 27: Early Quantum Physics and the Photon

A) 6.40 $\times$ 10¹⁴ Hz
B) 1.86 $\times$ 10¹⁴ Hz
C) 3.15 $\times$ 10¹⁴ Hz
D) 7.21 $\times$ 10¹⁴ Hz
E) 4.83 $\times$ 10¹⁴ Hz

A) 6.33 $\times$ 10¹⁰
B) 1.27 $\times$ 10¹²
C) 3.18 $\times$ 10¹⁵
D) 4.28 $\times$ 10¹⁶
E) 1.60 $\times$ 10¹⁹

A) no photoelectrons are emitted
B) maximum K(blue) < K(red)
C) maximum K(blue) = K(red)
D) maximum K(blue) > K(red)
E) none of these choices are true

A) no photoelectrons are emitted
B) 2.46 eV
C) 3.30 eV
D) 0.640 eV
E) 0.840 eV

A) 2.46
B) 3.13
C) 3.93
D) 4.08
E) 4.70

A) 1.00 $\times$ 10¹² Hz
B) 1.00 $\times$ 10¹³ Hz
C) 1.00 $\times$ 10¹⁴ Hz
D) 1.00 $\times$ 10¹⁵ Hz
E) 1.00 $\times$ 10¹⁶ Hz

A) 300 nm
B) 400 nm
C) 500 nm
D) 600 nm
E) 700 nm

A) the electron gains energy from the photon so that the scattered photon's wave length is less than $\lambda$ .
B) the electron gives energy to the scattered photon so the photon's frequency is greater than f.
C) momentum is not conserved,but energy is conserved.
D) the photon loses energy so that the scattered photon has a frequency less than f.

A) 200 nm
B) 62.1 pm
C) 32.7 nm
D) 5.73 pm
E) 1.07 nm

A) infrared
B) red
C) yellow
D) blue
E) ultraviolet

A) 6.60 eV
B) 13.2 eV
C) 1.65 eV
D) 0.825 eV
E) 3.96 eV

A) Hertz
B) Planck
C) Einstein
D) Maxwell
E) Bohr

A) 51 mW
B) 67 mW
C) 51 W
D) 75 W
E) 93 W

A) equal to that emitted by the second.
B) greater than that emitted by the second.
C) less than that emitted by the second.
D) dependent on the time interval of the emission.

A) 1.26 eV
B) 1.93 eV
C) 2.11 eV
D) 2.65 eV
E) 3.17 eV

A) charge on an electron.
B) photoelectric effect.
C) gravitational effect.
D) Compton effect.

A) 3.11 $\times$ 10^-19 J
B) 3.50 $\times$ 10^-19 J
C) 3.87 $\times$ 10^-19 J
D) 4.25 $\times$ 10^-19 J
E) 4.97 $\times$ 10^-19 J

A) Hertz's
B) Planck's
C) Einstein's
D) Maxwell's
E) Bohr's

A) 1.0 eV
B) 1.5 eV
C) 2.0 eV
D) 2.5 eV
E) 3.0 eV

A) a single wavelength.
B) all wavelengths from zero up to a maximum.
C) all wavelengths from a minimum to a maximum.
D) only discrete wavelengths.

A) the maximum wavelength depends on V.
B) the wavelength of the characteristic peaks depend on V.
C) the minimum wavelength depends on V.
D) the wavelength of the Bremsstrahlung depends on V.

A) 200 nm
B) 290 nm
C) 689 nm
D) 602 nm
E) 512 nm

A) the photon loses energy so that the scattered photon has frequency less than f.
B) the momentum is not conserved,but the energy is.
C) the electron gives energy to the scattered photon so that the photon's frequency is greater than f.
D) the electron gains energy from the photon so that the scattered photon's wavelength is less than f.

A) 669 pm
B) 508 pm
C) 72.6 pm
D) 13.8 pm
E) 14.3 pm

A) 100 keV
B) 71.8 keV
C) 83.6 keV
D) 28.2 keV
E) 16.4 keV

A) 1.35 $\times$ 10¹⁴ Hz
B) 5.81 $\times$ 10¹⁴ Hz
C) 1.35 $\times$ 10¹⁵ Hz
D) 7.74 $\times$ 10¹⁴ Hz
E) 7.74 $\times$ 10¹⁵ Hz

A) 123 kV
B) 9.22 kV
C) 8.00 kV
D) 10.0 kV
E) 15.0 kV

A) 5.68 pm
B) 7.42 pm
C) 3.28 pm
D) 0.868 pm
E) 2.43 pm

A) 568 keV
B) 59.5 keV
C) 30.1 keV
D) 15.0 keV
E) 10.5 keV

A) continuous
B) discrete
C) blackbody
D) band
E) dark-line

A) conservation of momentum.
B) conservation of energy.
C) conservation of charge.
D) conservation of momentum and charge.
E) conservation of energy and momentum.

A) 1.43 MeV
B) 218 keV
C) 380 keV
D) 117 keV
E) 66.3 keV

A) blackbody radiation
B) photoelectric effect
C) stimulated emission
D) bremsstrahlung
E) Compton effect

A) is proportional to the threshold frequency of the metal.
B) is proportional to the intensity of the incident light.
C) is proportional to the wavelength of the incident light.
D) is proportional to the frequency of the incident light.

A) the stopping potential decreases.
B) the stopping potential increases.
C) the work function decreases.
D) the work function increases.
E) None of these choices are true.

A) 0.5
B) 1
C) 2
D) 4
E) unlimited

A) 31.0 pm
B) 14.9 pm
C) 1.57 pm
D) 17.2 pm
E) 12.8 pm

A) 2.17 $\times$ 10¹⁹ Hz
B) 2.10 $\times$ 10¹⁹ Hz
C) 1.17 $\times$ 10²¹ Hz
D) 9.25 $\times$ 10²¹ Hz
E) 6.20 $\times$ 10¹⁵ Hz

A) 1
B) 2
C) 3
D) 4
E) 5

A) 13.6 eV
B) -13.6 eV
C) 3.40 eV
D) -3.40 eV
E) -1.51 eV

A) 0.0529 nm
B) 0.193 nm
C) 0.0265 nm
D) 0.106 nm
E) 0.212 nm

A) Einstein
B) Bohr
C) Rutherford
D) Planck
E) Feynman

A) 0.511 MeV.
B) 1.022 MeV.
C) 2.044 MeV.
D) 0.256 MeV.
E) any amount more than zero.

A) 323 nm
B) 156 nm
C) 121 nm
D) 103 nm
E) 97.3 nm

A) patterned electron technique.
B) positron emission tomography.
C) proton-electron transmission.
D) penetrating emission technique.
E) None of these choice are correct.

A) 0.000
B) 13.6 eV
C) 6.80 eV
D) 27.2 eV
E) 1.88 eV

A) kinetic energy
B) potential energy
C) total energy
D) linear momentum
E) angular momentum

A) 1.89 eV
B) 3.40 eV
C) 1.51 eV
D) 0.94 eV
E) 0.66 eV

A) 1/3
B) 3
C) 6
D) 9
E) 18

A) 1
B) 2
C) 4
D) 5
E) 6

A) 212 MeV/c²
B) 106 MeV/c²
C) 424 MeV/c²
D) 0.511 MeV/c²
E) 1.02 MeV/c²

A) this cannot happen
B) 20.0 eV
C) 13.6 eV
D) 6.40 eV
E) 33.6 eV

A) 1
B) -1
C) 1/2
D) -1/2
E) 2

A) 0.000
B) -13.6 eV
C) -27.2 eV
D) 13.6 eV
E) 27.2 eV

A) All the photons of the Lyman series are in the ultraviolet.
B) Some of the photons of the Lyman series are in the visible.
C) Some of the photons of the Lyman series are in the infrared.
D) All of the Balmer series are in the visible.
E) All of these statements are false.

A) any energy
B) 13.6 eV
C) 10.2 eV
D) 3.40 eV
E) 1.90 eV

A) -13.6 eV
B) -27.2 eV
C) -54.4 eV
D) -6.80 eV
E) -3.40 eV

A) 15.1 eV
B) 7.56 eV
C) 3.78 eV
D) 2.12 eV
E) 1.89 eV

A) Lyman
B) Balmer
C) Paschen
D) Brackett
E) All of these choices are correct.

A) X-rays being produced having longer wavelength
B) X-rays being produced having higher energy
C) More X-rays produced per unit time
D) Faster X-rays being produced

A) The same number are produced.
B) More are produced.
C) Without knowing more about the wavelengths used,one cannot answer.
D) Fewer are produced.

A) 8.72 $\times$ 10^-8 nm
B) 3.49 $\times$ 10^-7 nm
C) 6.98 $\times$ 10^-7 nm
D) 1.74 $\times$ 10^-7 nm

A) atoms that would produce light of the darkened frequency bands aren't present in the atmosphere.
B) atoms are present in the atmosphere that have electrons that are absorbing photons of those frequencies.
C) atoms are present in the atmosphere that have electrons that are emitting photons of those frequencies
D) atoms that would produce light of the darkened frequency bands are forbidden from doing so because of quantum effects.

A) 960 K
B) 23000 K
C) 9600 K
D) 96000 K
E) 2300 K

A) The same number are produced.
B) Fewer are produced .
C) Without knowing more about the wavelengths used,one cannot answer.
D) More are produced.

A) the spin magnetic quantum number s
B) the radial quantum number n
C) the orbital angular momentum quantum number l
D) the magnetic quantum number m

A) There is a continuous range of wavelengths produced,up to a maximum that depends on the energy of the electron beam used.
B) There is a single wavelength of X-ray produced that depends on the energy of the electron beam used.
C) There are a few specific wavelengths that are produced for a given metal and their wavelength is independent of the energy of the electron beam used.
D) There is a continuous range of wavelengths produced,down to a minimum that depends on the energy of the electron beam used.

A) 16.6 keV
B) 18.5 keV
C) 16.1 keV
D) 17.8 keV

A) manganese ( $\phi$ = 4.1 eV)
B) gadolinium ( $\phi$ = 2.90 eV)
C) cesium ( $\phi$ = 2.14 eV)
D) beryllium ( $\phi$ = 4.98 eV)

A) X-rays being produced having higher energies
B) X-rays having longer wavelengths being produced
C) Faster X-rays being produced
D) More X-rays being produced per unit time

A) There are a few specific wavelengths that are produced for a given metal and their wavelength is independent of the energy of the electron beam used.
B) There is a single wavelength of X-ray produced that depends on the energy of the electron beam used.
C) There is a continuous range of wavelengths produced,down to a minimum that depends on the energy of the electron beam used.
D) There is a continuous range of wavelengths produced,up to a maximum that depends on the energy of the electron beam used.

A) the relationship between orbital radius and energy
B) why alpha particles in Rutherford's experiment deflected at high angles when incident on atomic foils
C) why most alpha particles in Rutherford's experiment passed with little deflection through atomic foils
D) why electrons in atoms don't radiate all their energy away rapidly

A) Fewer electrons per unit time are produced.
B) More electrons per unit time are produced.
C) Nothing changes at all.
D) Electrons with a higher maximum energy are observed.
E) Electrons with lower maximum energy are observed.

A) 0.124 pm
B) 0.118 pm
C) 0.248 pm
D) 0.062 pm
E) need more information

A) 130 $^{\circ}$
B) 80 $^{\circ}$
C) such scattering is impossible
D) 34 $^{\circ}$