Deck 28: Quantum Mechanics and Atomic Physics

A) was the first to produce X-ray-like diffraction patterns of electrons passing through thin metal foil (1927).
B) developed a wave equation for matter waves (1926).
C) predicted the positron from relativistic quantum mechanics (1928).
D) set the limits on the probability of measurement accuracy (1927).
E) suggested the existence of matter waves (1924).

A) predicted the positron from relativistic quantum mechanics (1928).
B) set the limits on the probability of measurement accuracy (1927).
C) were first to produce diffraction patterns of electrons in crystals (1927).
D) discovered the positron using a cloud chamber (1932).
E) were first to produce X-ray-like diffraction patterns of electrons passing through thin metal foil (1927).

A) remains constant.
B) increases.
C) decreases.
D) could increase or decrease; it depends on other factors.

A) Bohr
B) Planck
C) Schrodinger
D) Einstein
E) de Broglie

A) the coils.
B) the deflector plates.
C) the cathode.
D) the vacuum chamber.

A) transmission electron microscope
B) light microscope
C) scanning electron microscope
D) scanning tunneling microscope

A) its frequency is too small.
B) its energy is too small.
C) its speed is too small.
D) it doesn't have a wavelike nature.
E) its wavelength is too small.

A) frequency.
B) momentum.
C) speed.
D) wavelength.
E) energy.

A) discovered the positron using a cloud chamber (1932).
B) was the first to produce diffraction patterns of electrons in crystals (1927).
C) developed a wave equation for matter waves (1926).
D) suggested the existence of matter waves (1924).
E) set the limits on the probability of measurement accuracy (1927).

A) probability density for finding particle.
B) position of the particle as a function of time.
C) probability of finding the particle.
D) velocity of the particle.

A) The spacing decreases.
B) The spacing increases.
C) The spacing alternately increases and decreases, depending on whether the wave function is a sine or a cosine function.
D) The spacing remains constant.

A) period
B) transition
C) row
D) group

A) MRT.
B) NRA.
C) CT-scan.
D) MRI.
E) CAT.

A) X-rays
B) radio
C) alpha radiation
D) gamma rays
E) beta rays

A) L and s
B) L and m_L
C) n and L
D) m_L and m_s
E) L and m_s

A) 14
B) 4
C) 2
D) 7
E) 10

A) 4s.
B) 6s.
C) 4d.
D) 5p.
E) 5d.

A) 1
B) 9
C) 8
D) 4
E) 5

A) 4f
B) 6p
C) 7s
D) 5p
E) 4d

A) 14
B) 21
C) 4
D) 7
E) 10

A) 3
B) 4
C) 2
D) 5
E) 6

A) improved periodic table.
B) wave equation.
C) uncertainty principle.
D) dirigible.
E) photoelectric theory.

A) predicted the positron from relativistic quantum mechanics (1928).
B) set the limits on the probability of measurement accuracy (1927).
C) developed a wave equation for matter waves (1926).
D) was the first to produce X-ray-like diffraction patterns of electrons passing through thin metal foil (1927).
E) suggested the existence of matter waves (1924).

A) we can never be sure whether a particle is a wave or a particle.
B) the charge on the electron can never be known with absolute accuracy.
C) at times an electron appears to be a particle and at other times it appears to be a photon.
D) all measurements are to some extent inaccurate, no matter how good the instrument used.
E) we cannot in principle know simultaneously the position and momentum of a particle with absolute certainty.

A) Schrodinger wave equation.
B) Pauli exclusion principle.
C) uncertainty principle.
D) de Broglie wave length.
E) quantum numbers.

A) set the limits on the probability of measurement accuracy (1927).
B) suggested the existence of matter waves (1924).
C) predicted the positron from relativistic quantum mechanics (1928).
D) discovered the positron using a cloud chamber (1932).
E) developed a wave equation for matter waves (1926).

A) discovered the positron using a cloud chamber (1932).
B) was the first to produce diffraction patterns of electrons in crystals (1927).
C) set the limits on the probability of measurement accuracy (1927).
D) was the first to produce X-ray-like diffraction patterns of electrons passing through thin metal foil (1927).
E) predicted the positron from relativistic quantum mechanics (1928).

A) called a muon.
B) called a positron.
C) not found in nature.
D) called a proton.
E) called a pion.

A) an electron and a positron
B) a proton and an electron
C) a electron and an antiproton
D) a proton and an antiproton
E) an electron and a photon

A) not conserve energy.
B) result in the creation of mass.
C) require photon energies that are not attainable.
D) defy the uncertainty principle.
E) not conserve charge.

A) 2.07 eV/c
B) 2.07 MeV/c
C) 2.07 KeV/c
D) 2.07 N-s
E) 2.07 kN-m

A) 3 m/s
B) 1 m/s
C) 2 m/s
D) 4 m/s
E) 5 m/s

A) 1.1 × 10^-34 m
B) 2.2 × 10^-34 m
C) 6.67 × 10^-27 m
D) 4.5 × 10^-28 m
E) 6.67 × 10^-31 m

A) 20. keV
B) 10. keV
C) 80. keV
D) 40. keV
E) 60. keV

A) 3 × 10⁴⁴.
B) 3 × 10⁴⁴
C) 3 × 10²⁴
D) 3 × 10^-34
E) 3 × 10⁷⁴

A) 2.2 m/s
B) 0.98 km/s
C) 0.60 km/s
D) 1.2 km/s
E) 37. m/s

A) less than 1.24 × 10²⁰ Hz.
B) greater than 1.24 × 10²⁰ Hz.
C) greater than 2.47 × 10²⁰ Hz.
D) less than 2.47 × 10²⁰ Hz.
E) infinite.

A) 0.256 MeV and 0.256 MeV
B) 0.511 MeV and 1.022 MeV
C) 0.225 MeV and 0.285 MeV
D) 0.511 MeV and 0.511 MeV
E) 1.02 GeV and 938. MeV

A) 223. MeV
B) 0.47 GeV
C) 1.88 GeV
D) 1.022 MeV
E) 940. MeV