Deck 39: Quantum Structure of Atoms, Molecules, and Solids

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

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

A) 0
B) 1
C) 2
D) 3
E) Hold on. All of the above values are allowed.

A) 3
B) 4
C) 5
D) Hold on. All of the above values are allowed.

A) n = 2, $l$ = 2, m = 1.
B) n = 2, $l$ = 1, m = 0.
C) n = 2, $l$ = 1, m = 1.
D) Hold on. All of the above states are permitted.

A) magnitude of the angular momentum.
B) z component of the angular momentum.
C) overall size of the trajectory.
D) Hold on. The principal quantum number contains information about each of these quantities.

A) 55°.
B) 45°.
C) 35°.
D) 25°.

A) the quantum number n.
B) the quantum number $l$
C) the quantum number m.
D) the quantum number m_s.

A) the total energy of the state.
B) the magnitude of the orbital angular momentum.
C) the z component of the orbital angular momentum.
D) the z component of the spin angular momentum.

A) the similarity in the electron configurations.
B) the same z component of the orbital angular momentum.
C) the same value of n for these elements.
D) Hold on. All of the above answers are correct.

A) no two quantum numbers can have the same value.
B) each stationary state consists of the quantum numbers n, l, m, and m_s.
C) each stationary state of quantum numbers n, l, and m can be occupied by no more than two electrons.
D) each stationary state of quantum numbers n, l, m, and m_s can be occupied by no more than two electrons.

A) one electron.
B) two electrons.
C) a set of electrons, the number of which depends on the quantum numbers.
D) Hold on. None of the above answers is correct.

A) 137 nm.
B) 121 nm.
C) 103 nm.
D) 97 nm.
E) 91 nm.

A) 16
B) 32
C) 60
D) 64

A) 16
B) 32
C) 60
D) 64

A) 37.4 eV.
B) 48.8 eV.
C) 54.4 eV.
D) 60.5 eV.

A) 13.6 eV.
B) 27.2 eV.
C) 40.8 eV.
D) 54.4 eV.

A) 0.24 keV.
B) 0.26 keV.
C) 4.4 keV.
D) 4.9 keV.

A) Bohr.
B) Einstein.
C) Heisenberg.
D) Pauli.

A) $4.14 \times 10 ^ { - 22 } \mathrm {~J}$
B) $8.28 \times 10 ^ { - 22 } \mathrm {~J}$
C) $12.4 \times 10 ^ { - 22 } \mathrm {~J}$
D) $20.7 \times 10 ^ { - 22 } \mathrm {~J}$
E) $37.3 \times 10 ^ { - 22 } \mathrm {~J}$

A) $1.0 \times 10 ^ { - 47 } \mathrm {~kg} \cdot \mathrm { m } ^ { 2 }$
B) $$1.3 \times 10 ^ { - 47 } \mathrm {~kg} \cdot \mathrm { m } ^ { 2 }$$
C) $2.3 \times 10 ^ { - 47 } \mathrm {~kg} \cdot \mathrm { m } ^ { 2 }$
D) $4.3 \times 10 ^ { - 47 } \mathrm {~kg} \cdot \mathrm { m } ^ { 2 }$

A) zero.
B) $4.3 \times 10 ^ { - 22 } \mathrm {~J}$
C) $8.5 \times 10 ^ { - 22 } \mathrm {~J}$
D) $17 \times 10 ^ { - 22 } \mathrm {~J}$

A) ionic.
B) covalent.
C) hydrogen.
D) metallic.

A) ionic.
B) covalent.
C) hydrogen.
D) metallic.

A) electronic, rotational, and vibrational.
B) electronic, vibrational, and rotational.
C) vibrational, electronic, and rotational.
D) rotational, vibrational, and electronic.

A) 1.0 eV.
B) 1.5 eV.
C) 2.0 eV.
D) 2.5 eV.

A) $6.5 \mu \mathrm { m }$
B) $8.3 \mu \mathrm { m }$
C) $65 \mathrm {~nm}$
D) $83 \mathrm {~nm}$

A) 120 N/m.
B) 480 N/m.
C) 780 N/m.
D) 1200 N/m.

A) 0.070 eV.
B) 0.14 eV.
C) 0.21 eV.
D) 0.28 eV.

A) a conductor.
B) an insulator.
C) semiconductors at room temperature.
D) both insulators and cold semiconductors.

A) is completely filled with electrons.
B) is completely filled with holes.
C) is partially filled with electrons.
D) cannot respond to external electric fields.

A) valence band.
B) conduction band.
C) transition band.
D) Hold on. All of the above answers are correct.

A) donor impurities into the lattice of a pure semiconductor.
B) acceptor impurities into the lattice of a pure semiconductor.
C) both acceptor and donor impurities into a lattice of a semiconductor.
D) Hold on. None of the above answers is correct.

A) donor impurities into the lattice of a pure semiconductor.
B) acceptor impurities into the lattice of a pure semiconductor.
C) both acceptor and donor impurities into a lattice of a semiconductor.
D) Hold on. None of the above answers is correct.

A) increases with an increase in temperature.
B) increases with a decrease in temperature.
C) is constant over a wide range of temperatures.
D) is zero at room temperature.

A) the majority charge carriers are produced by donor impurities.
B) the majority charge carriers are produced by acceptor impurities.
C) there are equal numbers of donor and acceptor impurities.
D) no charge carriers present.

A) first band.
B) second band.
C) conduction band.
D) valence band.

A) 68 nm.
B) 125 nm.
C) 255 nm.
D) 354 nm.

A) thermal energy.
B) doping with an acceptor impurity.
C) doping with a donor impurity.
D) recombination.

A) ratio of the n-type to p-type material in the device.
B) amount of current the device is passing.
C) DC voltage applied to the device.
D) Hold on. None of the above answers is correct.

A) increase the current through the device.
B) decrease the current through the device.
C) produce no appreciable change in the current through the device because the current is for all practical purposes zero.
D) produce no appreciable change in the current through the device.

A) increase the voltage across the device.
B) decrease the voltage across the device.
C) produce no appreciable change in the voltage across the device because the current is for all practical purposes zero.
D) produce no appreciable change in the voltage across the device.

A) zero.
B) 0.60 V.
C) 4.4 V.
D) 5.0 V.

A) zero.
B) 0.60 V.
C) 4.4 V.
D) 5.0 V.

A) zero.
B) 0.60 V.
C) 4.4 V.
D) 5.0 V.

A) zero.
B) 0.60 V.
C) 4.4 V.
D) 5.0 V.

A) zero.
B) 12 mA.
C) 44 mA.
D) 50 mA.

A) zero.
B) 12 mA.
C) 44 mA.
D) 50 mA.

A) p-type material.
B) n-type material.
C) both n- and p-type material.
D) pure silicon.

A) when forward-biased.
B) when reverse-biased.
C) only when it switches from forward to reverse bias.
D) continuously regardless of bias.