Deck 38: Spectral Lines, Bohrs Theory, and Quantum Mechanics

A) spectral lines.
B) a blackbody spectrum.
C) gamma rays.
D) whitebody rays.

A) Airy lines.
B) Fraunhofer lines.
C) Rydberg lines.
D) polarization lines.

A) 785 nm.
B) 862 nm.
C) 821 nm.
D) 762 nm.

A) $2.11 \times 10 ^ { - 34 }$ J.s.
B) $1.06 \times 10 ^ { - 34 }$ J.s.
C) $3.17 \times 10 ^ { - 34 }$ J.s.
D) $4.17 \times 10 ^ { - 34 }$ J.s.

A) $a _ { 0 }$
B) $2 a _ { 0 }$
C) $3 a _ { 0 }$
D) $4 a _ { 0 }$

A) -3.4 eV.
B) -6.8 eV.
C) -13.6 eV.
D) -9.2 eV.

A) 412 nm.
B) 318 nm.
C) 103 nm.
D) 285 nm.

A) $6.5 \times 10 ^ { - 34 }$ m.
B) $8.2 \times 10 ^ { - 35 }$ m.
C) $$1.2 \times 10 ^ { - 35 }$$ m.
D) $4.8 \times 10 ^ { - 36 }$ m.

A) $1.5 \times 10 ^ { 15 }$ Hz.
B) $2.5 \times 10 ^ { 16 }$ Hz.
C) $7.4 \times 10 ^ { 15 }$ Hz.
D) $6.6 \times 10 ^ { 16 }$ Hz.

A) the order of magnitude of the frequency of the emitted radiation.
B) the electrical neutrality.
C) the stability.
D) Hold it! There are no exceptions.

A) the order of magnitude of the frequency of the emitted radiation.
B) the electrical neutrality.
C) the stability.
D) Hold it! There are no exceptions.

A) $v \infty \left\{ \left( \frac { 1 } { n _ { 2 } } - \frac { 1 } { n _ { 1 } } \right) \right\}$
B) $\mathcal{v}$ $\infty\left\{\left(\frac{1}{n_{2}}\right)^{2}-\left(\frac{1}{n_{1}}\right)^{2}\right\}$ .

C) $\mathcal{v}$ $\infty\left\{\left(\frac{1}{n_{2}}\right)^{2}-\left(\frac{1}{n_{1}}\right)^{2}\right\}$


D) $\mathcal{v}$ $\infty \left\{ \left( n _ { 2 } \right) ^ { 2 } - \left( n _ { 1 } \right) ^ { 2 } \right\}$

A) energy.
B) charge.
C) angular momentum.
D) radius.

A) -12, -3, -1.
B) -12, -6, -4.
C) -12, -24, -36.
D) -12, -48, -108.

A) 1/4, 1/9.
B) 1/2, 1/3.
C) 2, 3.
D) 4, 9.

A) 1/1000 angstrom.
B) an angstrom.
C) 1000 angstroms.
D) 1,000,000 angstroms.

A) 1/10 electron volt.
B) 1 electron volt.
C) 10 electron volts.
D) 100 electron volts.

A) 1/1000 angstrom.
B) an angstrom.
C) 1000 angstroms.
D) 1,000,000 angstroms.

A) $E _ { \mathrm { He } } = 4 E _ { \mathrm { H } }$
B) $E _ { \mathrm { He } } = 2 E _ { \mathrm { H } }$
C) $E _ { \mathrm { He } } = \left( \frac { 1 } { 2 } \right) E _ { \mathrm { H } }$
D) $E _ { \mathrm { He } } = \left( \frac { 1 } { 4 } \right) E _ { \mathrm { H } }$

A) the charge of the helium nucleus is double that of the hydrogen nucleus.
B) the mass of the helium nucleus is four times that of the hydrogen nucleus.
C) Both of the first two responses are needed to account for the correct answer to the previous question.
D) Neither of the first two responses is needed to account for the correct answer to the previous question.

A) in the limit of large quantum numbers.
B) in the limit of small quantum numbers.
C) if the quantum numbers can be canceled from the equations.
D) Hold it! The correspondence principle does not insist upon agreement under any circumstances.

A) photons.
B) electrons.
C) atoms.
D) all of the above.

A) n².
B) n.
C) $\frac { 1 } { \mathrm { n } }$
D) $\frac { 1 } { n ^ { 2 } }$

A) n²
B) n.
C) $\frac { 1 } { \mathrm { n } }$
D) $\frac { 1 } { n ^ { 2 } }$

A) n².
B) n.
C) $\frac { 1 } { \mathrm { n } }$
D) $\frac { 1 } { n ^ { 2 } }$

A) $E = p \mathrm { c }$ , for a photon.
B) $E = \frac { p ^ { 2 } } { 2 m }$ , for a Newtonian particle in motion.
C) $E ^ { 2 } = ( p c ) ^ { 2 } + \left( m c ^ { 2 } \right) ^ { 2 }$ , for a relativistic particle in motion.
D) $E = m \mathrm { c } ^ { 2 }$ , for a relativistic particle at rest.

A) > the de Broglie wavelength of an electron.
B) $\approx$ the de Broglie wavelength of an electron.
C) < the de Broglie wavelength of an electron.
D) Hold it! No such generalization is valid.

A) > the atomic radius.
B) $\approx$ the atomic radius.
C) < the atomic radius.
D) Hold it! Insufficient information is given to answer this question unambiguously.

A) much faster than the proton.
B) much slower than the proton.
C) at the same speed as the proton.
D) Hold it! Speed is irrelevant; mass is what counts.

A) quadrupled.
B) doubled.
C) halved.
D) quartered.

A) ionized the atoms.
B) caused the atoms to recoil unexpectedly.
C) were themselves deflected through large angles.
D) None of the previous responses is valid.

A) transitional processes.
B) stationary orbits.
C) Both of the first two responses are valid.
D) Neither of the first two responses is valid.

A) energy.
B) angular momentum.
C) radius.
D) Hold it! There are no exceptions.

A) surface of the stars.
B) interior of the stars.
C) Both of the first two responses are valid.
D) Neither of the first two responses is valid.

A) magnetic (m), orbital (l), principal (n), spin (s).
B) principal (n), spin (s), magnetic (m), orbital (l).
C) principal (n), orbital (l), magnetic (m), spin (s).
D) orbital (l), principal (n), magnetic (m), spin (s).

A) l.
B) m.
C) n.
D) s.

A) l.
B) m.
C) n.
D) s.

A) l.
B) m.
C) n.
D) s.

A) l.
B) m.
C) n.
D) s.

A) electron.
B) neutron.
C) photon.
D) proton.

A) 1/2.
B) 1
C) Both of the first two responses are valid.
D) Neither of the first two responses is valid.

A) chemical activity.
B) atomic spectra.
C) atomic size.
D) Hold it! There are no exceptions.

A) number of electrons in the outermost shell.
B) missing number of electrons in the outermost shell.
C) Either of the first two responses may be valid.
D) Neither of the first two responses is valid.

A) almost full.
B) almost empty.
C) Both of the first two responses are valid.
D) Neither of the first two responses is valid.

A) 2 and 8.
B) 8 and 18.
C) 10 and 26.
D) 10 and 28.

A) 4
B) 8
C) 9
D) 18

A) angular momentum and energy.
B) energy and energy.
C) energy and angular momentum.
D) angular momentum and angular momentum.

A) have a single value and have a single value.
B) have a single value and range over a spectrum.
C) range over a spectrum and have a single value.
D) range over a spectrum and range over a spectrum.

A) closer together and closer together.
B) closer together and farther apart.
C) farther apart and closer together.
D) farther apart and farther apart.

A) the production of standing waves.
B) a partial reflection from lattice sites.
C) a partial transmission through lattice sites.
D) Hold it! There are no exceptions.