Deck 28: Quantum Physics

A) yes
B) no,because the de Broglie wavelength of the bullet is too large relative to the aperture
C) yes,because the aperture may be a slit or circular aperture
D) no,because the de Broglie wavelength of the bullet is too small relative to the aperture

A) $\lambda$ = C
B) $\pi$$\lambda$ = C
C) 2 $\pi$$\lambda$ = C
D) $\lambda$ = $\pi$ C
E) $\lambda$ = 2 $\pi$ C

A) 5.20 $\times$ 10^-11 m
B) 1.66 $\times$ 10^-10 m
C) 3.32 $\times$ 10^-10 m
D) 6.65 $\times$ 10^-10 m
E) 1.33 $\times$ 10^-9 m

A) 56.4 pm
B) 0.137 pm
C) 0.166 pm
D) 2.83 pm
E) 5.11 pm

A) 37.5 V
B) 75.0 V
C) 150 V
D) 300 V

A) 0.40 kg objects don't have wavelengths
B) 10 m
C) 0.10 m
D) 6.6 $\times$ 10^-35 m
E) 0.53 $\times$ 10^-10 m

A) the electron and neutron have the same kinetic energy but the electron has the higher speed.
B) the electron has a lower speed and smaller kinetic energy.
C) the electron has higher kinetic energy and higher speed.
D) the electron has smaller kinetic energy and higher speed.

A) J. J. Thompson.
B) Louis de Broglie.
C) Neils Bohr.
D) Einstein and Planck.
E) Davisson and Germer.

A) 10.0 keV
B) 101 keV
C) 55.3 keV
D) 5.53 keV
E) 6.77 keV

A) 2.55 $\times$ 10^-9 m
B) 1.23 $\times$ 10^-10 m
C) 0.529 $\times$ 10^-10 m
D) 8.67 $\times$ 10^-9 m
E) 1.20 $\times$ 10^-15 m

A) diffraction
B) interference
C) photoelectric effect
D) refraction

A) $\Psi$ .
B) $\Psi$ $\Delta$ x.
C) $\Psi$ ( $\Delta$ x)².
D) $\Psi$ ² $\Delta$ x.
E) $\Psi$ ² ( $\Delta$ x)².

A) $\lambda$ _n = C_n
B) n $\lambda$ _n = C_n
C) $\lambda$ _n/n= C_n
D) n² $\lambda$ _n = C_n
E) 2 $\pi$$\lambda$ _n = C_n

A) it doubles
B) it halves
C) it slightly more than doubles
D) it becomes slightly less than half
E) it decreases by a factor of 2^-1/2

A) 1.
B) 2.
C) 4.
D) 16.
E) 0.25.

A) photoelectric effect
B) Compton effect
C) diffraction effect
D) pair production

A) 0.707
B) 1.00
C) 1.41
D) 2.00
E) 3.00^1/2

A) 61.2 nm
B) 612 nm
C) 1.20 fm
D) 13.7 pm
E) 12.3 pm

A) 1.15 $\times$ 10¹¹ m
B) 1.23 $\times$ 10¹¹ m
C) 1.12 $\times$ 10¹¹ m
D) 1.14 $\times$ 10¹¹ m

A) Born.
B) Bohr.
C) Einstein.
D) Schrödinger.
E) Planck.

A) The energies are quantized for bound states.
B) The bound-state wave functions at the walls do not have to be zero.
C) The wave function can exist outside the walls.
D) There is the same number of bound states in a finite box as in a box with infinite walls.
E) None of these statements are true.

A) halving
B) quartering
C) doubling
D) quadrupling
E) no change in

A) Einstein.
B) Bohr.
C) Heisenberg.
D) Planck.
E) Dirac.

A) angular momentum
B) charge
C) angle
D) energy
E) wavelength

A) 4.0 eV
B) 16 eV
C) 20 eV
D) 28 eV
E) 26 eV

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

A) An electron with a positive total energy is a bound electron.
B) The orbital angular momentum of an electron in the ground state is zero.
C) An electron in the hydrogen atom is best represented as a traveling wave.
D) An electron in state n can make transitions only to the state n + 1 or n - 1.

A) 9
B) 5
C) 4
D) 3
E) 32

A) 9
B) 7
C) 5
D) 4
E) 3

A) The principal quantum number of the electron in a hydrogen atom does not affect its energy.
B) The orbital angular momentum quantum number of an electron state is always less than the principal quantum number.
C) The electron spin quantum number can take on any one of four different values.
D) The principal quantum number of an electron in its ground state is zero.

A) 1.1 $\times$ 10^-27 kg·m/s
B) 1.8 $\times$ 10^-28 kg·m/s
C) 8.8 $\times$ 10^-29 kg·m/s
D) 1.2 $\times$ 10^-32 kg·m/s
E) 1.8 $\times$ 10^-32 kg·m/s

A) decrease
B) stay the same
C) increase
D) halved

A) Heisenberg
B) Bohr
C) Born
D) Schrödinger
E) de Broglie

A) 10^-2 eV
B) 10^-7 eV
C) 10^-12 eV
D) 10^-15 eV
E) 10^-18 eV

A) L
B) 2L
C) L/2
D) 0.707L
E) 1.414L

A) The spacings do not change.
B) The spacings increase.
C) The spacings decrease.
D) There is insufficient information to answer this question.

A) 20.0 eV
B) 40.0 eV
C) 160 eV
D) 50.0 eV
E) 250 eV

A) 3
B) 3,-3
C) 3,2,1,0
D) 2,1,0,-1,-2
E) 2,-2

A) nothing,it remains at zero
B) it doubles
C) it halves
D) it quadruples
E) it quarters

A) excludes electrons from atomic nuclei.
B) means that no two electrons in an atom can have the same orbit.
C) implies that in an atom no two electrons can have identical sets of quantum numbers.
D) excludes protons from electron orbits.

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

A) 14
B) 10
C) 8
D) 4
E) 3

A) insulator.
B) conductor.
C) resistor.
D) semiconductor.
E) reactor.

A) 4.27 $\times$ 10²¹
B) 5.39 $\times$ 10³⁰
C) 3.17 $\times$ 10¹⁸
D) 5.34 $\times$ 10²³
E) 6.20 $\times$ 10²³

A) 0.00
B) 0.0010 eV
C) 0.025 eV
D) 0.27 eV
E) 1.0 eV

A) a conductor
B) an insulator
C) a semiconductor
D) a p-type semiconductor
E) an n-type semiconductor

A) 5
B) 25
C) 11
D) 2
E) 4

A) B
B) F
C) Ne
D) Al
E) Cr

A) 4 h
B) 3 h
C) $\sqrt{6}$ h
D) $\sqrt{12}$ h
E) $\sqrt{20}$ h

A) Electrons are in the -1/2 state.
B) Excited atoms must be at the top of the laser tube.
C) Excited atoms must be at the bottom of the laser tube.
D) The number of excited states that are to emit photons are in greater number than the lower states at which the transition is ending.
E) The number of lower states are in greater number than the upper states participating in the lasing action.

A) 2.25 eV
B) 1.79 eV
C) 4.04 eV
D) 0.460 eV
E) 1.30 eV

A) s²p⁴
B) s²p⁶
C) d²s²
D) d⁶p²
E) s¹p⁴

A) 10
B) 7
C) 4
D) 3
E) 2

A) laser states.
B) metastable states.
C) amplification states.
D) radiation states.
E) cascading states.

A) the He ground state
B) the Ne ground state
C) the 20.61 eV excited stated of He
D) the 18.70 eV excited state of Ne
E) the 4.660 eV excited state of Ne

A) h
B) g
C) f
D) d
E) p

A) 10
B) 18
C) 20
D) 30
E) More information is needed.

A) yellow argon gold.
B) yearly age group.
C) yttrium assisted gain.
D) yttrium aluminum garnet.
E) yttrium antimony gain.

A) 4
B) 9
C) 16
D) 18
E) 32

A) has the same size.
B) has the same nuclear properties.
C) has the same electron configuration.
D) has the same nuclear charge.

A) the more precisely its momentum can be known.
B) the more precisely its energy can be known.
C) the less precisely its momentum can be known.
D) the shorter its deBroglie wavelength is.

A) Decreases
B) Increases
C) Stays the same

A) 9.1 $\times$ 10^-34 m
B) 5.7 $\times$ 10^-34 m
C) 1.8 $\times$ 10^-34 m
D) 6.3 $\times$ 10^-33 m

A) 18
B) 30
C) 16
D) 32
E) 9

A) 96 V
B) 48 V
C) 24 V
D) 5 V

A) 2
B) 1
C) Any number
D) 4

A) 0.29c
B) 0.10c
C) 0.39c
D) 0.21c

A) position
B) momentum
C) mass
D) physical extent in space

A) $\pi$$\ddot{A}$$\S$ / 2
B) 3 $\pi$$\ddot{A}$$\S$ / 2
C) $\ddot{A}$$\S$
D) $\pi$$\ddot{A}$$\S$

A) 41 MeV
B) 83 MeV
C) 21 MeV
D) 5.2 MeV

A) 155 cm
B) 12 cm
C) 25 cm
D) 50 cm

A) It decreases
B) It stays the same
C) It increases