Deck 8: Electrons in Atoms

A) 3.8 × 10-18 J
B) 1.7 × 1024 J
C) 5.8 × 10-25 J
D) 1.7 × 10-16 J
E) 5.2 × 10-8 J

A) λ = c ∙ v
B) λ = c/v
C) v = λ/c
D) λ = v/c
E) c = λ/v

A) 1.62 × 1018 photons
B) 4.32 × 1019 photons
C) 6.76 × 1018 photons
D) 2.31 × 1018 photons
E) 9.63 × 1019 photons

A) 6.81 × 1014 s-1
B) 6.81 × 105 s-1
C) 1.51 × 10-27 s-1
D) 4.95 × 10-12 s-1
E) 2.02 × 10-11 s-1

A) 2.02 × 107 photons
B) 8.46 × 107 photons
C) 4.17 × 1018 photons
D) 1.02 × 1027 photons
E) 4.25 × 1027 photons

A) 840 nm
B) 2.8 × 104 nm
C) 299 nm
D) 9.3 × 104 nm
E) 1.1 × 104 nm

A) Infrared light has a longer wavelength than ultraviolet light.
B) The greater the frequency of the electromagnetic radiation, the greater the energy of the radiation.
C) A photon with a wavelength of 5000 Angstroms has one-half as much energy as a photon with a wavelength of 2500 Angstroms.
D) The speed of ultraviolet light rays is faster than X-rays in a vacuum.
E) Electromagnetic radiation is energy transmission in which electric and magnetic fields are propagated as waves.

A) Max Planck
B) Johann Balmer
C) Johannes Rydberg
D) Albert Einstein
E) Robert Bunsen

A) 2.89 × 108 m/s
B) 2.89 × 1017 m/s
C) 1.33 × 1012 m/s
D) 1.33 × 1021 m/s
E) 7.52 × 10-22 m/s

A) 3.64 × 10-18 photons
B) 2.74 × 1020 photons
C) 4.56 × 10-4 photons
D) 1.65 × 1044 photons
E) 3.64 × 10-16 photons

A) 0.59 m
B) 5.9 × 10-31 m
C) 5.9 × 10-35 m
D) 590 m
E) 1.7 × 1034 m

A) Pauli Exclusion Principle
B) The Aufbau Principle
C) Hund's Rule
D) The DeBroglie Relationship
E) Heisenberg Uncertainty Principle

A) 2000. m
B) 2.94 × 10-24 m
C) 7.36 × 10-34 m
D) 7.36 × 10-37 m
E) 1.49 × 10-40 m

A) 4.35 × 10-31 J
B) 3.03 × 10-19 J
C) 1.30 × 10-22 J
D) 3.03 × 10-28 J
E) 1.45 × 10-48 J

A) Another electron goes from a low energy state to a high one.
B) The atom moves faster.
C) Light is given off.
D) This process is not possible.
E) Light is absorbed.

A) 1.09 × 10-6 m
B) 8.22 × 10-7 m
C) 3.28 × 10-6 m
D) 1.83 × 10-7 m
E) 1.65 × 10-11 m

A) 7.26 × 10-19 J
B) 7.36 × 10-35 J
C) -2.42 × 10-19 J
D) 3.33 × 107 J
E) 1.96 × 10-17 J

A) the relationship between wavelengths of spectral lines and the electrons' energies responsible for them
B) the relationship between wavelength and frequency of spectral lines
C) the relationship between frequencies of spectral lines and the energy values associated with them
D) a model for finding the limited numbers of wavelengths associated with atomic spectral lines
E) an explanation for the continuous range of energy values associated with atomic spectra

A) was discovered by Max Planck
B) describes the phenomenon of producing light by shining a beam of electrons by on any metal surface
C) contradicted the view that light energy was dependent upon intensity only
D) is not the same principle used in modern electric eyes and solar calculators
E) results in a beam of electrons which increases in number, but not velocity, as the wavelength of incident light decreases

A) due to an electron losing energy but keeping the same values of its four quantum numbers
B) due to an electron losing energy and changing shells
C) due to an interaction between electrons in two different principal shells
D) due to an electron gaining energy and changing shells
E) due to an increase in the principal quantum number n of an electron

A) 1.53 × 10-27 J
B) 4.58 × 10-28 J
C) 1.04 × 1048 J
D) 4.58 × 10-19 J
E) 9.59 × 10-49 J

A) diffraction of electrons by crystals
B) X-ray diffraction by crystals
C) atomic line spectra
D) experiments on the photoelectric effect
E) visible spectrum

A) 5.52 × 10-22 kJ/mol
B) 5.52 × 10-19 kJ/mol
C) 332 kJ/mol
D) 6.63 × 103 kJ/mol
E) 0.332 kJ/mol

A) the energy of the electrons.
B) the total energy of the atom.
C) the number of electrons in a shell.
D) the shell in which an electron is found.
E) the number of orbits in an atom.

A) It has fluctuating values at all points on the curve.
B) It is a mathematical equation.
C) It is denoted by psi (Ψ).
D) It can describe any particle with wavelike motions.
E) It corresponds to a standing wave within the boundary of the system.

A) 2.76 × 105 J
B) 9.21 × 10-4 J
C) 2.76 × 10-4 J
D) 5.78 × 10-25 J
E) 434 J

A) 1.33 × 10-29 nm
B) 2.65 × 10-29 nm
C) 6.02 × 10-29 nm
D) 7.50 × 103 nm
E) 1.66 × 10-29 nm

A) 243 nm
B) 0.243 nm
C) 412 nm
D) 7.98 × 10-2 nm
E) 12.5 nm

A) 6.59 × 10-37 m
B) 6.59 × 10-34 m
C) 1.07 × 10-30 m
D) 4.12 × 10-37 m
E) 2.42 × 10-11 m

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

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

A) ms denotes the spin quantum number.
B) The value of the spin quantum number can be +1/2 or -1/2.
C) The value of the spin quantum number does not depend on other quantum numbers.
D) The value of the spin quantum number can be indicated by arrows to the right and to the left.
E) The spin quantum number is an indication that electrons generate a magnetic field.

A) principal
B) magnetic
C) spin
D) valence
E) orbital angular momentum

A) It is the lowest energy value of a particle.
B) It's value can be zero.
C) Because the zero-point energy is not zero, the particle cannot be at rest.
D) Zero-point energy corresponds to n = 1.
E) The zero-point energy is an allowable value of the energy of the particle.

A) n = 3, ℓ = 0
B) n = 1, ℓ = 3
C) n = 3, ℓ = 3
D) n = 3, ℓ = 1
E) n = 3, ℓ = 2

A) II only
B) I and II
C) II and III
D) I, II, and III
E) I, II, III, and IV

A) An electron produces a magnetic field.
B) The electron's magnetic field can be oriented in two directions in the presence of an external magnetic field.
C) Paired electrons produced no net magnetic field.
D) An experiment with silver atoms passing through a magnetic field seems to prove that electron spin exists.
E) Electron spin only exists when mℓ = 0.

A) n = 3, ℓ = 2, mℓ = 1
B) n = 3, ℓ = 0, mℓ = 0
C) n = 3, ℓ = 3, mℓ = 1
D) n = 3, ℓ = 2, mℓ = -1
E) n = 3, ℓ = 1, mℓ = -1

A) 2p
B) 4d
C) 5p
D) 3f
E) 2s

A) A 1s orbital is spherical.
B) 2p orbitals have a node at r = 0.
C) There are only two 2p orbitals, each directed along and x or y axis.
D) There are 5 3d orbitals.
E) Four of the 3d orbitals are alike except for the orientation with respect to the axes.

A) dxy, py
B) dyz, px
C) dx2-y2, pz
D) dxy, dz2
E) dxy, dyz

A) the shape of an atom
B) the repulsion of all the electrons among themselves
C) a fixed path that an electron follows around the nucleus of an atom
D) the region of electron density for a covalent bond
E) the region of high probability for an electron around the nucleus of an atom

A) "n" relates the most probable distance from the nucleus.
B) "l" denotes geometric shape.
C) "m" denotes orientation of an orbital with respect to the others.
D) The fourth quantum number refers to electron spin.
E) The four quantum numbers are derived from wave mechanics.

A) +1/2, -1/2
B) -1, 0, +1
C) -1
D) 0
E) 1

A) 3s
B) 2s
C) 2d
D) 2p
E) 3p

A) dxy
B) dx2-y2
C) dxz
D) dyz
E) s

A) I, III, IV
B) I, II, IV
C) I, IV, V
D) I, II, III
E) I, II, III, and IV

A) n = 3, ℓ = 1
B) n = 0, ℓ = 3
C) n = 3, ℓ = 3
D) n = 3, ℓ = 2
E) n = 3, ℓ = 0

A) II and III
B) I and IV
C) I and II
D) II and IV
E) I and III

A) 0
B) 1/2
C) 1
D) 2
E) 3/2

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

A) X-rays < microwave < UV < visible
B) X-ray < microwave < visible < UV
C) microwave < visible < UV < X-rays
D) visible < UV < X-rays < microwave
E) UV < X-rays < microwave < visible

A) 0.218 nm
B) 0.419 nm
C) 157 nm
D) 218 nm
E) 6579 nm

A) 304 nm
B) 30.4 nm
C) 329 nm
D) 535 nm
E) 434 nm

A) the Aufbau Principle
B) Hund's Rule
C) the Bohr Theory
D) the Heisenberg Principle
E) the Pauli Exclusion Principle

A) 30.0 kHz
B) 3.00 × 104 kHz
C) 3.00 × 107 kHz
D) 3.33 × 10-7 kHz
E) 3.33 × 10-2 kHz

A) 18.3 nm
B) 656 nm
C) 547 nm
D) 152 nm
E) 252 nm

A) 365 nm
B) 45.6 nm
C) 205 nm
D) 486 nm
E) 1459 nm

A) 3
B) 4
C) 5
D) 6
E) 7

A) Heisenberg Principle
B) Exclusion Principle
C) Bohr Theory
D) Hund's Rule
E) Aufbau principle

A) 1p5
B) 3s3
C) 3f2
D) 4d11
E) 2p6

A) The link between the table arrangement and quantum theory is electron configuration.
B) Elements in the same group have similar electron configurations.
C) Elements in the same group have the same number of electrons in the outer shell.
D) Elements in the same group have the same principle quantum number.
E) Elements in the same group have the same number of valence electrons.

A) n = 3, ℓ = 2, mℓ = 0, ms = 1/2
B) n = 4, ℓ = 2, mℓ = 0, ms = 1/2
C) n = 3, ℓ = 1, mℓ = 0, ms = 1/2
D) n = 3, ℓ = 2, mℓ = 0, ms = 0
E) n = 3, ℓ = 2, mℓ = 1/2, ms = 1/2

A) Aufbau principle
B) Hund's Rule
C) Heisenberg Principle
D) Pauli Exclusion Principle
E) Rydberg's Principle

A) n = 4, ℓ = 2, mℓ = 1, ms = 1/2
B) n = 4, ℓ = 1, mℓ = 1, ms = 1/2
C) n = 3, ℓ = 1, mℓ = 1, ms = 1/2
D) n = 4, ℓ = 3, mℓ = 1, ms = 1/2
E) n = 4, ℓ = 1, mℓ = 1/2, ms = 0

A) has not yet been found
B) was provided by Uhlenbeck and Goudsmit in 1925
C) came as the result of an experiment with vaporized silver atoms, which was originally designed for another purpose
D) is provided each time we make mirror-image molecules, called left and right-handed isomers
E) is not needed because the concept is only for our convenience

A) 3
B) 4
C) 5
D) 6
E) 7

A) 18.3 nm
B) 656 nm
C) 547 nm
D) 152 nm
E) 252 nm

A) the Bohr Theory
B) Hund's Rule
C) the Aufbau Principle
D) the Pauli Exclusion Principle
E) the Heisenberg Uncertainty Principle