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Deck 7: Quantum Theory and Atomic Structure

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Question
The FM station KDUL broadcasts music at 99.1 MHz. Find the wavelength of these waves.

A) 1.88 × 10-2 m
B) 0.330 m
C) 3.03 m
D) 5.33 × 102 m
E) > 103 m
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Question
Contact lenses can focus light due to the ____________ of the waves.

A) diffraction
B) reflection
C) refraction
D) dispersion
E) interference
Question
Who proposed a model that successfully explained the photoelectric effect?

A) Planck
B) Einstein
C) Compton
D) Rydberg
E) Bohr
Question
Who proposed the principle that states that one cannot simultaneously know the exact position and velocity of a particle?

A) Einstein
B) Planck
C) Heisenberg
D) Compton
E) de Broglie
Question
Which scientist first proposed that the electron in the hydrogen atom can have only certain energies?

A) Planck
B) Einstein
C) Bohr
D) Rydberg
E) Heisenberg
Question
Which scientist demonstrated that photons transferred momentum during collisions with matter?

A) Bohr
B) de Broglie
C) Planck
D) Compton
E) Billiard
Question
Select the arrangement of electromagnetic radiation which starts with the lowest energy and increases to greatest energy.

A) radio, visible, infrared, ultraviolet
B) infrared, visible, ultraviolet, microwave
C) visible, ultraviolet, infrared, gamma rays
D) X-radiation, visible, infrared, microwave
E) microwave, infrared, visible, ultraviolet
Question
Which of the following frequencies of electromagnetic radiation has the shortest wavelength?

A) 1 kilohertz
B) 1 terahertz
C) 1 dekahertz
D) 1 gigahertz
E) 1 megahertz
Question
Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?

A) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px> = 1/ <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px>
B) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px> = <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px>
C) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px> = <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px> / <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px>
D) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px> = <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px> × <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px>
E) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px> = <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px> / <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / <div style=padding-top: 35px>
Question
Which word best describes the phenomenon which gives rise to a rainbow?

A) reflection
B) dispersion
C) diffraction
D) interference
E) deflection
Question
Who developed an empirical equation from which the wavelengths of lines in the spectrum of hydrogen atoms can be calculated?

A) Planck
B) de Broglie
C) Bohr
D) Rutherford
E) Rydberg
Question
Who was the first scientist to propose that an object could emit only certain amounts of energy?

A) Planck
B) Einstein
C) Bohr
D) Rydberg
E) de Broglie
Question
Interference of light waves

A) separates light into its component colors.
B) creates a pattern of light and dark regions.
C) focuses a broad beam of light into a point.
D) bends light as it passes the edge of an object.
E) creates a laser beam.
Question
The AM station KBOR plays your favorite music from the 20's and 30's at 1290 kHz. Find the wavelength of these waves.

A) 4.30 × 10-2 m
B) 0.144 m
C) 6.94 m
D) 232 m
E) > 103 m
Question
Which scientist first proposed that particles of matter could have wave properties?

A) Einstein
B) Planck
C) de Broglie
D) Compton
E) Heisenberg
Question
The interference pattern seen when light passes through narrow, closely spaced slits, is due to

A) diffraction.
B) reflection.
C) refraction.
D) dispersion.
E) deflection.
Question
Select the arrangement of electromagnetic radiation which starts with the lowest wavelength and increases greatest wavelength.

A) radio, infrared, ultraviolet, gamma rays
B) radio, ultraviolet, infrared, gamma rays
C) gamma rays, radio, ultraviolet, infrared
D) gamma rays, infrared, radio, ultraviolet
E) gamma rays, ultraviolet, infrared, radio
Question
Electromagnetic radiation of 500 nm wavelength lies in the __________ region of the spectrum.

A) infrared
B) visible
C) ultraviolet
D) X-ray
E) <strong>Electromagnetic radiation of 500 nm wavelength lies in the __________ region of the spectrum.</strong> A) infrared B) visible C) ultraviolet D) X-ray E) -ray <div style=padding-top: 35px> -ray
Question
Who was the first scientist to propose that the atom had a dense nucleus that occupied only a small fraction of the volume of the atom?

A) Planck
B) Bohr
C) Rydberg
D) Rutherford
E) Thomson
Question
Select the arrangement of electromagnetic radiation which starts with the lowest energy and increases to greatest energy.

A) radio, infrared, ultraviolet, gamma rays
B) radio, ultraviolet, infrared, gamma rays
C) gamma rays, infrared, radio, ultraviolet
D) gamma rays, ultraviolet, infrared, radio
E) infrared, ultraviolet, radio, gamma rays
Question
The Bohr theory of the hydrogen atom predicts the energy difference (in J) between the n = 3 and the n = 5 state to be

A) 8.72 × 10-20 J.
B) 1.36 × 10-19 J.
C) 2.42 × 10-19 J.
D) 1.55 × 10-19 J.
E) 1.09 × 10-18 J.
Question
Consider the following adjectives used to describe types of spectrum: Continuous line atomic emission absorption
How many of them are appropriate to describe the spectrum of radiation absorbed by a sample of mercury vapor?

A) one
B) two
C) three
D) four
E) five
Question
Green light has a wavelength of 5200 Å. Calculate the energy of one photon of green light.

A) 3.4 × 10-40 J
B) 3.4 × 10-30 J
C) 3.8 × 10-29 J
D) 3.4 × 10-27 J
E) 3.8 × 10-19 J
Question
Use the Rydberg equation to calculate the frequency of a photon absorbed when the hydrogen atom undergoes a transition from n1 = 2 to n2 = 4. (R = 1.096776 × 107 m-1)

A) 2.056 × 106 s-1
B) 2.742 × 106 s-1
C) 6.165 × 1014 s-1
D) 8.226 × 1014 s-1
E) > 1015 s-1
Question
An infrared wave has a wavelength of 6.5 × 10-4 cm. What is this distance in angstroms, Å?

A) 6.5 × 10-4 Å
B) 2.2 × 10-4 Å
C) 4.6 × 103 Å
D) 6.5 × 104 Å
E) 6.5 × 106 Å
Question
For potassium metal, the work function <strong>For potassium metal, the work function (the minimum energy needed to eject an electron from the metal surface) is 3.68 × 10<sup>-19</sup> J. Which is the longest wavelength of the following which could excite photoelectrons?</strong> A) 550. nm B) 500. nm C) 450. nm D) 400. nm E) 350. nm <div style=padding-top: 35px> (the minimum energy needed to eject an electron from the metal surface) is 3.68 × 10-19 J. Which is the longest wavelength of the following which could excite photoelectrons?

A) 550. nm
B) 500. nm
C) 450. nm
D) 400. nm
E) 350. nm
Question
An electron in the n = 6 level emits a photon with a wavelength of 410.2 nm. To what energy level does the electron move?

A) n = 1
B) n = 2
C) n = 3
D) n = 4
E) n = 5
Question
Consider the following adjectives used to describe types of spectrum: continuous line atomic emission absorption How many of them are appropriate to describe the spectrum of radiation given off by a black body?

A) none
B) one
C) two
D) three
E) four
Question
According to the Rydberg equation, the line with the shortest wavelength in the emission spectrum of atomic hydrogen is predicted to lie at a wavelength (in nm) of

A) 91.2 nm.
B) 1.10 × 10-2 nm.
C) 1.10 × 102 nm.
D) 1.10 × 1016 nm.
E) None of these choices are correct.
Question
Line spectra from all regions of the electromagnetic spectrum, including the Paschen series of infrared lines for hydrogen, are used by astronomers to identify elements present in the atmospheres of stars. Calculate the wavelength of the photon emitted when the hydrogen atom undergoes a transition from n = 5 to n = 3. (R = 1.096776 × 107 m-1)

A) 205.1 nm
B) 384.6 nm
C) 683.8 nm
D) 1282 nm
E) > 1500 nm
Question
What type of spectrum, if any, would be produced if the light radiated by a heated atomic gas were to be dispersed through a prism?

A) a continuous band of color
B) a continuous band of color with some dark lines (missing wavelengths)
C) only blue light
D) only red light
E) discrete lines of different colors
Question
Platinum, which is widely used as a catalyst, has a work function <strong>Platinum, which is widely used as a catalyst, has a work function (the minimum energy needed to eject an electron from the metal surface) of 9.05 × 10-<sup>19</sup> J. What is the longest wavelength of light which will cause electrons to be emitted?</strong> A) 2.196 × 10<sup>-7</sup> m B) 4.553 × 10<sup>-6</sup> m C) 5.654 × 10<sup>2</sup> m D) 1.370 × 10<sup>15</sup> m E) > 10<sup>6</sup> m <div style=padding-top: 35px> (the minimum energy needed to eject an electron from the metal surface) of 9.05 × 10-19 J. What is the longest wavelength of light which will cause electrons to be emitted?

A) 2.196 × 10-7 m
B) 4.553 × 10-6 m
C) 5.654 × 102 m
D) 1.370 × 1015 m
E) > 106 m
Question
If the energy of a photon is 1.32 × 10-18 J, what is its wavelength in nm?

A) 1.50 × 10-7 nm
B) 150. nm
C) 1.99 × 1015 nm
D) 1.99 × 1024 nm
E) None of these choices are correct.
Question
A modern compact fluorescent lamp contains 1.4 mg of mercury. If each mercury atom in the lamp were to emit a single photon of wavelength 254 nm, how many joules of energy would be emitted?

A) 7.8 × 10-19 J
B) 3.3 J
C) 6.6 × 102 J
D) 3.3 × 103 J
E) 4.2 × 1018 J
Question
Infrared radiation from the sun has a wavelength of 6200 nm. Calculate the energy of one photon of that radiation.

A) 4.l × 10-39 J
B) 4.l × 10-30 J
C) 3.2 × 10-29 J
D) 3.2 × 10-26 J
E) between 10-20 and 10-19 J
Question
According to the Rydberg equation, the longest wavelength (in nm) in the series of H-atom lines with n1 = 3 is

A) 1875 nm.
B) 1458 nm.
C) 820. nm.
D) 656 nm.
E) 365 nm.
Question
A photon has an energy of 5.53 × 10-17 J. What is its frequency in s-1?

A) 3.66 × 10-50 s-1
B) 1.20 × 10-17 s-1
C) 3.59 × 10-9 s-1
D) 2.78 × 108 s-1
E) 8.35 × 1016 s-1
Question
A radio wave has a frequency of 8.6 × 108 Hz. What is the energy of one photon of this radiation?

A) 7.7 × 10-43 J
B) 2.3 × 10-34 J
C) 5.7 × 10-25 J
D) 1.7 × 10-16 J
E) > 10-15 J
Question
In the photoelectric effect, a photon with an energy of 5.3 × 10-19 J strikes an electron in a metal. Of this energy, 3.6 × 10-19 J is the minimum energy required for the electron to escape from the metal. The remaining energy appears as kinetic energy of the photoelectron. What is the velocity of the photoelectron, assuming it was initially at rest?

A) 3.7 × 1014 m/s
B) 3.7 × 1011 m/s
C) 1.9 × 106 m/s
D) 6.1 × 105 m/s
E) 1.7 × 10-19 m/s
Question
Excited hydrogen atoms radiate energy in the

A) infrared region only.
B) visible region only.
C) ultraviolet region only.
D) visible and ultraviolet regions only.
E) infrared, visible, and ultraviolet regions.
Question
Atomic orbitals developed using quantum mechanics

A) describe regions of space in which one is most likely to find an electron.
B) describe exact paths for electron motion.
C) give a description of the atomic structure which is essentially the same as the Bohr model.
D) allow scientists to calculate an exact volume for the hydrogen atom.
E) are in conflict with the Heisenberg Uncertainty Principle.
Question
According to the Bohr theory of the hydrogen atom, the minimum energy (in J) needed to ionize a hydrogen atom from the n = 2 state is

A) 2.18 × 10-18 J.
B) 1.64 × 10-18 J.
C) 5.45 × 10-19 J.
D) 3.03 × 10-19 J.
E) None of these choices are correct.
Question
For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ <div style=padding-top: 35px> ?

A) L = <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ <div style=padding-top: 35px> /2
B) L = <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ <div style=padding-top: 35px>
C) L = n <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ <div style=padding-top: 35px> /2 where n is a positive integer
D) L = n <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ <div style=padding-top: 35px> where n is a positive integer
E) L = 1/ <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ <div style=padding-top: 35px>
Question
The shape of an atomic orbital is associated with

A) the principal quantum number (n).
B) the angular momentum quantum number (l).
C) the magnetic quantum number (ml).
D) the spin quantum number (ms).
E) the magnetic and spin quantum numbers, together.
Question
The ionization energy is the energy needed to remove an electron from an atom. In the Bohr model of the hydrogen atom, this means exciting the electron to the n = ∞ state. What is the ionization energy in kJ/mol, for hydrogen atoms initially in the n = 2 energy level?

A) 290 kJ/mol
B) 328 kJ/mol
C) 656 kJ/mol
D) 983 kJ/mol
E) 1311 kJ/mol
Question
The size of an atomic orbital is associated with

A) the principal quantum number (n).
B) the angular momentum quantum number (l).
C) the magnetic quantum number (ml).
D) the spin quantum number (ms).
E) the angular momentum and magnetic quantum numbers, together.
Question
A sprinter must average 24.0 mi/h to win a 100-m dash in 9.30 s. What is his wavelength at this speed if his mass is 84.5 kg?

A) 7.29 × 10-37 m
B) 3.26 × 10-37 m
C) 5.08 × 10-30 m
D) 1.34 × 10-30 m
E) None of these choices are correct.
Question
Which of the following is a correct set of quantum numbers for an electron in a 5f orbital?

A) n = 5, l = 3, ml = +1
B) n = 5, l = 2, ml = +3
C) n = 4, l = 3, ml = 0
D) n = 4, l = 2, ml = +1
E) n = 5, l = 4, ml = 3
Question
The orientation in space of an atomic orbital is associated with

A) the principal quantum number (n).
B) the angular momentum quantum number (l).
C) the magnetic quantum number (ml).
D) the spin quantum number (ms).
E) None of these choices are correct.
Question
Continuous spectra are characteristic of heated solids.
Question
As the frequency of electromagnetic radiation increases, its wavelength also increases.
Question
Which of the following is a correct set of quantum numbers for an electron in a 3d orbital?

A) n = 3, l = 0, ml = -1
B) n = 3, l = 1, ml = +3
C) n = 3, l = 2, ml = 3
D) n = 3, l = 3, ml = +2
E) n = 3, l = 2, ml = -2
Question
In an atom, the square of an electron's wave function

A) becomes zero at the nucleus.
B) is smallest near the nucleus.
C) is largest near the nucleus.
D) may be zero at more than one point.
E) tends to infinity at large distances from the nucleus.
Question
The energy of an electron in the hydrogen atom is determined by

A) the principal quantum number (n) only.
B) the angular momentum quantum number (l) only.
C) the principal and angular momentum quantum numbers (n & l ).
D) the principal and magnetic quantum numbers (n & ml).
E) the principal, angular momentum and magnetic quantum numbers.
Question
Line spectra are characteristic of atoms in the gas phase.
Question
In the quantum mechanical treatment of the hydrogen atom, which one of the following combinations of quantum numbers is not allowed? <strong>In the quantum mechanical treatment of the hydrogen atom, which one of the following combinations of quantum numbers is not allowed? </strong> A) A B) B C) C D) D E) E <div style=padding-top: 35px>

A) A
B) B
C) C
D) D
E) E
Question
According to the Heisenberg uncertainty principle, if the uncertainty in the speed of an electron is 3.5 × 103 m/s, the uncertainty in its position (in m) is at least

A) 1.7 × 10-8 m.
B) 6.6 × 10-8 m.
C) 17 m.
D) 66 m.
E) None of these choices are correct.
Question
The de Broglie equation predicts that the wavelength (in m) of a proton moving at 1000. m/s is

A) 3.96 × 10-10 m.
B) 3.96 × 10-7 m.
C) 2.52 × 106 m.
D) 2.52 × 109 m.
E) > 1010 m.
Question
Which one of the following sets of quantum numbers can correctly represent a 3p orbital?

A) n = 3 l = 1 ml = 2
B) n = 1 l = 3 ml = 3
C) n = 3 l = 2 ml = 1
D) n = 3 l = 1 ml = -1
E) n = 3 l = 0 ml = 1
Question
The energy of a photon is directly proportional to the wavelength of the radiation.
Question
In the Bohr model of the hydrogen atom, the electron moves in a circular path which Bohr referred to as an orbital.
Question
In the quantum mechanical treatment of the hydrogen atom, the energy depends on the principal quantum number n but not on the values of l or ml.
Question
Other factors being constant, a heavy object will have a longer de Broglie wavelength than a light object.
Question
The Rydberg equation, giving the wavelengths of lines in the spectrum of the hydrogen atom, was obtained by assuming that energy is quantized.
Question
The Rydberg equation is an example of an empirical equation.
Question
A wave function for an electron is called an atomic orbital.
Question
Continuous spectra are characteristic of molecules in the gas phase.
Question
In the quantum mechanical treatment of the hydrogen atom, the probability of finding an electron at any point is proportional to the wave functionIn the quantum mechanical treatment of the hydrogen atom, the probability of finding an electron at any point is proportional to the wave function .<div style=padding-top: 35px> .
Question
In the Rydberg equation, for a fixed value of n1, the longest wavelength line has n2 =∞.
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Deck 7: Quantum Theory and Atomic Structure
1
The FM station KDUL broadcasts music at 99.1 MHz. Find the wavelength of these waves.

A) 1.88 × 10-2 m
B) 0.330 m
C) 3.03 m
D) 5.33 × 102 m
E) > 103 m
3.03 m
2
Contact lenses can focus light due to the ____________ of the waves.

A) diffraction
B) reflection
C) refraction
D) dispersion
E) interference
refraction
3
Who proposed a model that successfully explained the photoelectric effect?

A) Planck
B) Einstein
C) Compton
D) Rydberg
E) Bohr
Einstein
4
Who proposed the principle that states that one cannot simultaneously know the exact position and velocity of a particle?

A) Einstein
B) Planck
C) Heisenberg
D) Compton
E) de Broglie
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k this deck
5
Which scientist first proposed that the electron in the hydrogen atom can have only certain energies?

A) Planck
B) Einstein
C) Bohr
D) Rydberg
E) Heisenberg
Unlock Deck
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k this deck
6
Which scientist demonstrated that photons transferred momentum during collisions with matter?

A) Bohr
B) de Broglie
C) Planck
D) Compton
E) Billiard
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k this deck
7
Select the arrangement of electromagnetic radiation which starts with the lowest energy and increases to greatest energy.

A) radio, visible, infrared, ultraviolet
B) infrared, visible, ultraviolet, microwave
C) visible, ultraviolet, infrared, gamma rays
D) X-radiation, visible, infrared, microwave
E) microwave, infrared, visible, ultraviolet
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8
Which of the following frequencies of electromagnetic radiation has the shortest wavelength?

A) 1 kilohertz
B) 1 terahertz
C) 1 dekahertz
D) 1 gigahertz
E) 1 megahertz
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9
Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?

A) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / = 1/ <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = /
B) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / = <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = /
C) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / = <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / / <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = /
D) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / = <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / × <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = /
E) <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / = <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = / / <strong>Electromagnetic radiation can be specified by its wavelength ( ), its frequency ( ) or its period (). The period is the time it takes one complete wavelength to pass a point in space. Based on this information, what is the mathematical relationship between and ?</strong> A) = 1/ B) = C) = / D) = × E) = /
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10
Which word best describes the phenomenon which gives rise to a rainbow?

A) reflection
B) dispersion
C) diffraction
D) interference
E) deflection
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11
Who developed an empirical equation from which the wavelengths of lines in the spectrum of hydrogen atoms can be calculated?

A) Planck
B) de Broglie
C) Bohr
D) Rutherford
E) Rydberg
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12
Who was the first scientist to propose that an object could emit only certain amounts of energy?

A) Planck
B) Einstein
C) Bohr
D) Rydberg
E) de Broglie
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13
Interference of light waves

A) separates light into its component colors.
B) creates a pattern of light and dark regions.
C) focuses a broad beam of light into a point.
D) bends light as it passes the edge of an object.
E) creates a laser beam.
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14
The AM station KBOR plays your favorite music from the 20's and 30's at 1290 kHz. Find the wavelength of these waves.

A) 4.30 × 10-2 m
B) 0.144 m
C) 6.94 m
D) 232 m
E) > 103 m
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15
Which scientist first proposed that particles of matter could have wave properties?

A) Einstein
B) Planck
C) de Broglie
D) Compton
E) Heisenberg
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16
The interference pattern seen when light passes through narrow, closely spaced slits, is due to

A) diffraction.
B) reflection.
C) refraction.
D) dispersion.
E) deflection.
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17
Select the arrangement of electromagnetic radiation which starts with the lowest wavelength and increases greatest wavelength.

A) radio, infrared, ultraviolet, gamma rays
B) radio, ultraviolet, infrared, gamma rays
C) gamma rays, radio, ultraviolet, infrared
D) gamma rays, infrared, radio, ultraviolet
E) gamma rays, ultraviolet, infrared, radio
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18
Electromagnetic radiation of 500 nm wavelength lies in the __________ region of the spectrum.

A) infrared
B) visible
C) ultraviolet
D) X-ray
E) <strong>Electromagnetic radiation of 500 nm wavelength lies in the __________ region of the spectrum.</strong> A) infrared B) visible C) ultraviolet D) X-ray E) -ray -ray
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19
Who was the first scientist to propose that the atom had a dense nucleus that occupied only a small fraction of the volume of the atom?

A) Planck
B) Bohr
C) Rydberg
D) Rutherford
E) Thomson
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20
Select the arrangement of electromagnetic radiation which starts with the lowest energy and increases to greatest energy.

A) radio, infrared, ultraviolet, gamma rays
B) radio, ultraviolet, infrared, gamma rays
C) gamma rays, infrared, radio, ultraviolet
D) gamma rays, ultraviolet, infrared, radio
E) infrared, ultraviolet, radio, gamma rays
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21
The Bohr theory of the hydrogen atom predicts the energy difference (in J) between the n = 3 and the n = 5 state to be

A) 8.72 × 10-20 J.
B) 1.36 × 10-19 J.
C) 2.42 × 10-19 J.
D) 1.55 × 10-19 J.
E) 1.09 × 10-18 J.
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22
Consider the following adjectives used to describe types of spectrum: Continuous line atomic emission absorption
How many of them are appropriate to describe the spectrum of radiation absorbed by a sample of mercury vapor?

A) one
B) two
C) three
D) four
E) five
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23
Green light has a wavelength of 5200 Å. Calculate the energy of one photon of green light.

A) 3.4 × 10-40 J
B) 3.4 × 10-30 J
C) 3.8 × 10-29 J
D) 3.4 × 10-27 J
E) 3.8 × 10-19 J
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24
Use the Rydberg equation to calculate the frequency of a photon absorbed when the hydrogen atom undergoes a transition from n1 = 2 to n2 = 4. (R = 1.096776 × 107 m-1)

A) 2.056 × 106 s-1
B) 2.742 × 106 s-1
C) 6.165 × 1014 s-1
D) 8.226 × 1014 s-1
E) > 1015 s-1
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25
An infrared wave has a wavelength of 6.5 × 10-4 cm. What is this distance in angstroms, Å?

A) 6.5 × 10-4 Å
B) 2.2 × 10-4 Å
C) 4.6 × 103 Å
D) 6.5 × 104 Å
E) 6.5 × 106 Å
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26
For potassium metal, the work function <strong>For potassium metal, the work function (the minimum energy needed to eject an electron from the metal surface) is 3.68 × 10<sup>-19</sup> J. Which is the longest wavelength of the following which could excite photoelectrons?</strong> A) 550. nm B) 500. nm C) 450. nm D) 400. nm E) 350. nm (the minimum energy needed to eject an electron from the metal surface) is 3.68 × 10-19 J. Which is the longest wavelength of the following which could excite photoelectrons?

A) 550. nm
B) 500. nm
C) 450. nm
D) 400. nm
E) 350. nm
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27
An electron in the n = 6 level emits a photon with a wavelength of 410.2 nm. To what energy level does the electron move?

A) n = 1
B) n = 2
C) n = 3
D) n = 4
E) n = 5
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28
Consider the following adjectives used to describe types of spectrum: continuous line atomic emission absorption How many of them are appropriate to describe the spectrum of radiation given off by a black body?

A) none
B) one
C) two
D) three
E) four
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29
According to the Rydberg equation, the line with the shortest wavelength in the emission spectrum of atomic hydrogen is predicted to lie at a wavelength (in nm) of

A) 91.2 nm.
B) 1.10 × 10-2 nm.
C) 1.10 × 102 nm.
D) 1.10 × 1016 nm.
E) None of these choices are correct.
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30
Line spectra from all regions of the electromagnetic spectrum, including the Paschen series of infrared lines for hydrogen, are used by astronomers to identify elements present in the atmospheres of stars. Calculate the wavelength of the photon emitted when the hydrogen atom undergoes a transition from n = 5 to n = 3. (R = 1.096776 × 107 m-1)

A) 205.1 nm
B) 384.6 nm
C) 683.8 nm
D) 1282 nm
E) > 1500 nm
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31
What type of spectrum, if any, would be produced if the light radiated by a heated atomic gas were to be dispersed through a prism?

A) a continuous band of color
B) a continuous band of color with some dark lines (missing wavelengths)
C) only blue light
D) only red light
E) discrete lines of different colors
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32
Platinum, which is widely used as a catalyst, has a work function <strong>Platinum, which is widely used as a catalyst, has a work function (the minimum energy needed to eject an electron from the metal surface) of 9.05 × 10-<sup>19</sup> J. What is the longest wavelength of light which will cause electrons to be emitted?</strong> A) 2.196 × 10<sup>-7</sup> m B) 4.553 × 10<sup>-6</sup> m C) 5.654 × 10<sup>2</sup> m D) 1.370 × 10<sup>15</sup> m E) > 10<sup>6</sup> m (the minimum energy needed to eject an electron from the metal surface) of 9.05 × 10-19 J. What is the longest wavelength of light which will cause electrons to be emitted?

A) 2.196 × 10-7 m
B) 4.553 × 10-6 m
C) 5.654 × 102 m
D) 1.370 × 1015 m
E) > 106 m
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33
If the energy of a photon is 1.32 × 10-18 J, what is its wavelength in nm?

A) 1.50 × 10-7 nm
B) 150. nm
C) 1.99 × 1015 nm
D) 1.99 × 1024 nm
E) None of these choices are correct.
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34
A modern compact fluorescent lamp contains 1.4 mg of mercury. If each mercury atom in the lamp were to emit a single photon of wavelength 254 nm, how many joules of energy would be emitted?

A) 7.8 × 10-19 J
B) 3.3 J
C) 6.6 × 102 J
D) 3.3 × 103 J
E) 4.2 × 1018 J
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35
Infrared radiation from the sun has a wavelength of 6200 nm. Calculate the energy of one photon of that radiation.

A) 4.l × 10-39 J
B) 4.l × 10-30 J
C) 3.2 × 10-29 J
D) 3.2 × 10-26 J
E) between 10-20 and 10-19 J
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36
According to the Rydberg equation, the longest wavelength (in nm) in the series of H-atom lines with n1 = 3 is

A) 1875 nm.
B) 1458 nm.
C) 820. nm.
D) 656 nm.
E) 365 nm.
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37
A photon has an energy of 5.53 × 10-17 J. What is its frequency in s-1?

A) 3.66 × 10-50 s-1
B) 1.20 × 10-17 s-1
C) 3.59 × 10-9 s-1
D) 2.78 × 108 s-1
E) 8.35 × 1016 s-1
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38
A radio wave has a frequency of 8.6 × 108 Hz. What is the energy of one photon of this radiation?

A) 7.7 × 10-43 J
B) 2.3 × 10-34 J
C) 5.7 × 10-25 J
D) 1.7 × 10-16 J
E) > 10-15 J
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39
In the photoelectric effect, a photon with an energy of 5.3 × 10-19 J strikes an electron in a metal. Of this energy, 3.6 × 10-19 J is the minimum energy required for the electron to escape from the metal. The remaining energy appears as kinetic energy of the photoelectron. What is the velocity of the photoelectron, assuming it was initially at rest?

A) 3.7 × 1014 m/s
B) 3.7 × 1011 m/s
C) 1.9 × 106 m/s
D) 6.1 × 105 m/s
E) 1.7 × 10-19 m/s
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40
Excited hydrogen atoms radiate energy in the

A) infrared region only.
B) visible region only.
C) ultraviolet region only.
D) visible and ultraviolet regions only.
E) infrared, visible, and ultraviolet regions.
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41
Atomic orbitals developed using quantum mechanics

A) describe regions of space in which one is most likely to find an electron.
B) describe exact paths for electron motion.
C) give a description of the atomic structure which is essentially the same as the Bohr model.
D) allow scientists to calculate an exact volume for the hydrogen atom.
E) are in conflict with the Heisenberg Uncertainty Principle.
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42
According to the Bohr theory of the hydrogen atom, the minimum energy (in J) needed to ionize a hydrogen atom from the n = 2 state is

A) 2.18 × 10-18 J.
B) 1.64 × 10-18 J.
C) 5.45 × 10-19 J.
D) 3.03 × 10-19 J.
E) None of these choices are correct.
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43
For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ ?

A) L = <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ /2
B) L = <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/
C) L = n <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ /2 where n is a positive integer
D) L = n <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/ where n is a positive integer
E) L = 1/ <strong>For all the allowed vibration(s) (wavelength(s)) of a plucked guitar string, what is the correct relationship between the length of the string, L, and the wavelength, ?</strong> A) L = /2 B) L = C) L = n /2 where n is a positive integer D) L = n where n is a positive integer E) L = 1/
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44
The shape of an atomic orbital is associated with

A) the principal quantum number (n).
B) the angular momentum quantum number (l).
C) the magnetic quantum number (ml).
D) the spin quantum number (ms).
E) the magnetic and spin quantum numbers, together.
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45
The ionization energy is the energy needed to remove an electron from an atom. In the Bohr model of the hydrogen atom, this means exciting the electron to the n = ∞ state. What is the ionization energy in kJ/mol, for hydrogen atoms initially in the n = 2 energy level?

A) 290 kJ/mol
B) 328 kJ/mol
C) 656 kJ/mol
D) 983 kJ/mol
E) 1311 kJ/mol
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46
The size of an atomic orbital is associated with

A) the principal quantum number (n).
B) the angular momentum quantum number (l).
C) the magnetic quantum number (ml).
D) the spin quantum number (ms).
E) the angular momentum and magnetic quantum numbers, together.
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47
A sprinter must average 24.0 mi/h to win a 100-m dash in 9.30 s. What is his wavelength at this speed if his mass is 84.5 kg?

A) 7.29 × 10-37 m
B) 3.26 × 10-37 m
C) 5.08 × 10-30 m
D) 1.34 × 10-30 m
E) None of these choices are correct.
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48
Which of the following is a correct set of quantum numbers for an electron in a 5f orbital?

A) n = 5, l = 3, ml = +1
B) n = 5, l = 2, ml = +3
C) n = 4, l = 3, ml = 0
D) n = 4, l = 2, ml = +1
E) n = 5, l = 4, ml = 3
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49
The orientation in space of an atomic orbital is associated with

A) the principal quantum number (n).
B) the angular momentum quantum number (l).
C) the magnetic quantum number (ml).
D) the spin quantum number (ms).
E) None of these choices are correct.
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50
Continuous spectra are characteristic of heated solids.
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51
As the frequency of electromagnetic radiation increases, its wavelength also increases.
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52
Which of the following is a correct set of quantum numbers for an electron in a 3d orbital?

A) n = 3, l = 0, ml = -1
B) n = 3, l = 1, ml = +3
C) n = 3, l = 2, ml = 3
D) n = 3, l = 3, ml = +2
E) n = 3, l = 2, ml = -2
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53
In an atom, the square of an electron's wave function

A) becomes zero at the nucleus.
B) is smallest near the nucleus.
C) is largest near the nucleus.
D) may be zero at more than one point.
E) tends to infinity at large distances from the nucleus.
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54
The energy of an electron in the hydrogen atom is determined by

A) the principal quantum number (n) only.
B) the angular momentum quantum number (l) only.
C) the principal and angular momentum quantum numbers (n & l ).
D) the principal and magnetic quantum numbers (n & ml).
E) the principal, angular momentum and magnetic quantum numbers.
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55
Line spectra are characteristic of atoms in the gas phase.
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56
In the quantum mechanical treatment of the hydrogen atom, which one of the following combinations of quantum numbers is not allowed? <strong>In the quantum mechanical treatment of the hydrogen atom, which one of the following combinations of quantum numbers is not allowed? </strong> A) A B) B C) C D) D E) E

A) A
B) B
C) C
D) D
E) E
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57
According to the Heisenberg uncertainty principle, if the uncertainty in the speed of an electron is 3.5 × 103 m/s, the uncertainty in its position (in m) is at least

A) 1.7 × 10-8 m.
B) 6.6 × 10-8 m.
C) 17 m.
D) 66 m.
E) None of these choices are correct.
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58
The de Broglie equation predicts that the wavelength (in m) of a proton moving at 1000. m/s is

A) 3.96 × 10-10 m.
B) 3.96 × 10-7 m.
C) 2.52 × 106 m.
D) 2.52 × 109 m.
E) > 1010 m.
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59
Which one of the following sets of quantum numbers can correctly represent a 3p orbital?

A) n = 3 l = 1 ml = 2
B) n = 1 l = 3 ml = 3
C) n = 3 l = 2 ml = 1
D) n = 3 l = 1 ml = -1
E) n = 3 l = 0 ml = 1
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60
The energy of a photon is directly proportional to the wavelength of the radiation.
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61
In the Bohr model of the hydrogen atom, the electron moves in a circular path which Bohr referred to as an orbital.
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62
In the quantum mechanical treatment of the hydrogen atom, the energy depends on the principal quantum number n but not on the values of l or ml.
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63
Other factors being constant, a heavy object will have a longer de Broglie wavelength than a light object.
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64
The Rydberg equation, giving the wavelengths of lines in the spectrum of the hydrogen atom, was obtained by assuming that energy is quantized.
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65
The Rydberg equation is an example of an empirical equation.
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66
A wave function for an electron is called an atomic orbital.
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67
Continuous spectra are characteristic of molecules in the gas phase.
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68
In the quantum mechanical treatment of the hydrogen atom, the probability of finding an electron at any point is proportional to the wave functionIn the quantum mechanical treatment of the hydrogen atom, the probability of finding an electron at any point is proportional to the wave function . .
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69
In the Rydberg equation, for a fixed value of n1, the longest wavelength line has n2 =∞.
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