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Deck 40: Quantum Mechanics

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Question
An electron is in an infinite square well (a box)that is 2.0 nm wide.The electron makes a transition from the <strong>An electron is in an infinite square well (a box)that is 2.0 nm wide.The electron makes a transition from the to the state,what is the wavelength of the emitted photon? ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 880 nm B) 750 nm C) 610 nm D) 1000 nm E) 1100 nm <div style=padding-top: 35px> to the <strong>An electron is in an infinite square well (a box)that is 2.0 nm wide.The electron makes a transition from the to the state,what is the wavelength of the emitted photon? ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 880 nm B) 750 nm C) 610 nm D) 1000 nm E) 1100 nm <div style=padding-top: 35px> state,what is the wavelength of the emitted photon? <strong>An electron is in an infinite square well (a box)that is 2.0 nm wide.The electron makes a transition from the to the state,what is the wavelength of the emitted photon? ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 880 nm B) 750 nm C) 610 nm D) 1000 nm E) 1100 nm <div style=padding-top: 35px> ,mel = 9.11 × 10-31 kg,1 eV = 1.60 × 10-19)

A) 880 nm
B) 750 nm
C) 610 nm
D) 1000 nm
E) 1100 nm
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Question
The square of the wave function of a particle,|ψ(x)|2,gives the probability of finding the particle at the point x.
Question
A particle is confined to a one-dimensional box (an infinite well)on the x-axis between <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 <div style=padding-top: 35px> and <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 <div style=padding-top: 35px> .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 <div style=padding-top: 35px> sin <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 <div style=padding-top: 35px> ,with <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 <div style=padding-top: 35px> .What is the probability of finding the particle between x = 0 and x = L/3?

A) 0.20
B) 0.22
C) 0.24
D) 0.26
E) 0.28
Question
Find the value of A to normalize the wave function ψ(x)= <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) 1/L B) C) 1/L<sup>2</sup> D) 1. E) 1/ <div style=padding-top: 35px> .

A) 1/L
B) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) 1/L B) C) 1/L<sup>2</sup> D) 1. E) 1/ <div style=padding-top: 35px>
C) 1/L2
D) 1. <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) 1/L B) C) 1/L<sup>2</sup> D) 1. E) 1/ <div style=padding-top: 35px>
E) 1/ <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) 1/L B) C) 1/L<sup>2</sup> D) 1. E) 1/ <div style=padding-top: 35px>
Question
An electron is in an infinite square well that is 2.6 nm wide.What is the smallest value of the state quantum number n for which the energy level exceeds 100 eV? <strong>An electron is in an infinite square well that is 2.6 nm wide.What is the smallest value of the state quantum number n for which the energy level exceeds 100 eV? , ,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 43 B) 44 C) 45 D) 42 E) 41 <div style=padding-top: 35px> , <strong>An electron is in an infinite square well that is 2.6 nm wide.What is the smallest value of the state quantum number n for which the energy level exceeds 100 eV? , ,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 43 B) 44 C) 45 D) 42 E) 41 <div style=padding-top: 35px> ,1 eV = 1.60 × 10-19)

A) 43
B) 44
C) 45
D) 42
E) 41
Question
An electron is bound in an infinite square-well potential (a box)on the x-axis.The width of the well is L and the well extends from x = 0.00 nm to <strong>An electron is bound in an infinite square-well potential (a box)on the x-axis.The width of the well is L and the well extends from x = 0.00 nm to In its present state,the normalized wave function of the electron is given by: ψ(x)=<sub> </sub> <sub> </sub> sin (2πx/L).What is the energy of the electron in this state?(h = 6.626 × 10<sup>-34</sup> J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg, </strong> A) 0.10 eV B) 0.052 eV C) 0.13 eV D) 0.078 eV E) 0.026 eV <div style=padding-top: 35px> In its present state,the normalized wave function of the electron is given by: ψ(x)= <strong>An electron is bound in an infinite square-well potential (a box)on the x-axis.The width of the well is L and the well extends from x = 0.00 nm to In its present state,the normalized wave function of the electron is given by: ψ(x)=<sub> </sub> <sub> </sub> sin (2πx/L).What is the energy of the electron in this state?(h = 6.626 × 10<sup>-34</sup> J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg, </strong> A) 0.10 eV B) 0.052 eV C) 0.13 eV D) 0.078 eV E) 0.026 eV <div style=padding-top: 35px> sin (2πx/L).What is the energy of the electron in this state?(h = 6.626 × 10-34 J • s,mel = 9.11 × 10-31 kg, <strong>An electron is bound in an infinite square-well potential (a box)on the x-axis.The width of the well is L and the well extends from x = 0.00 nm to In its present state,the normalized wave function of the electron is given by: ψ(x)=<sub> </sub> <sub> </sub> sin (2πx/L).What is the energy of the electron in this state?(h = 6.626 × 10<sup>-34</sup> J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg, </strong> A) 0.10 eV B) 0.052 eV C) 0.13 eV D) 0.078 eV E) 0.026 eV <div style=padding-top: 35px>

A) 0.10 eV
B) 0.052 eV
C) 0.13 eV
D) 0.078 eV
E) 0.026 eV
Question
The smallest kinetic energy that an electron in a box (an infinite well)can have is zero.
Question
The lowest energy level of a particle confined to a one-dimensional region of space (a box,or infinite well)with fixed length L is E0.If an identical particle is confined to a similar region with fixed length L/6,what is the energy of the lowest energy level that the particles have in common? Express your answer in terms of E0.
Question
A particle trapped in a one-dimensional finite potential well with U0 = 0 in the region <strong>A particle trapped in a one-dimensional finite potential well with U<sub>0 </sub>= 0 in the region ,and finite U<sub>0</sub> everywhere else,has a ground state wavenumber,k.The ground state wavenumber for the same particle in an infinite one-dimensional potential well of width L,would be</strong> A) less than k. B) greater than k. C) equal to k. D) There is not enough information to determine. <div style=padding-top: 35px> ,and finite U0 everywhere else,has a ground state wavenumber,k.The ground state wavenumber for the same particle in an infinite one-dimensional potential well of width L,would be

A) less than k.
B) greater than k.
C) equal to k.
D) There is not enough information to determine.
Question
If an atom in a crystal is acted upon by a restoring force that is directly proportional to the distance of the atom from its equilibrium position in the crystal,then it is impossible for the atom to have zero kinetic energy.
Question
The wave function for a particle must be normalizable because

A) the particle's momentum must be conserved.
B) the particle's angular momentum must be conserved.
C) the particle's charge must be conserved.
D) the particle must be somewhere.
E) the particle cannot be in two places at the same time.
Question
The wave function for an electron that is confined to x ≥ 0 nm is
ψ(x)= The wave function for an electron that is confined to x ≥ 0 nm is ψ(x)= (a)What must be the value of b? (b)What is the probability of finding the electron in a 0.010 nm-wide region centered at ?<div style=padding-top: 35px> (a)What must be the value of b?
(b)What is the probability of finding the electron in a 0.010 nm-wide region centered at The wave function for an electron that is confined to x ≥ 0 nm is ψ(x)= (a)What must be the value of b? (b)What is the probability of finding the electron in a 0.010 nm-wide region centered at ?<div style=padding-top: 35px> ?
Question
The probability density for an electron that has passed through an experimental apparatus is shown in the figure.If 4100 electrons pass through the apparatus,what is the expected number that will land in a 0.10 mm-wide strip centered at x = 0.00 mm? <strong>The probability density for an electron that has passed through an experimental apparatus is shown in the figure.If 4100 electrons pass through the apparatus,what is the expected number that will land in a 0.10 mm-wide strip centered at x = 0.00 mm? </strong> A) 140 B) 1400 C) 450 D) 45 <div style=padding-top: 35px>

A) 140
B) 1400
C) 450
D) 45
Question
A set of five possible wave functions is given below,where L is a positive real number. ψ1(x)= Ae-x,for all x ψ2(x)= A cos x,for all x
Ψ3(x)= <strong>A set of five possible wave functions is given below,where L is a positive real number. ψ<sub>1</sub>(x)= Ae<sup>-</sup><sup>x</sup>,for all x ψ<sub>2</sub>(x)= A cos x,for all x Ψ<sub>3</sub>(x)= ψ<sub>4</sub>(x)= ψ<sub>5</sub>(x)= Which of the five possible wave functions are normalizable? (There may be more than one correct choice.)</strong> A) ψ<sub>1</sub>(x) B) ψ<sub>2</sub>(x) C) ψ<sub>3</sub>(x) D) ψ<sub>4</sub>(x) E) ψ<sub>5</sub>(x) <div style=padding-top: 35px> ψ4(x)= <strong>A set of five possible wave functions is given below,where L is a positive real number. ψ<sub>1</sub>(x)= Ae<sup>-</sup><sup>x</sup>,for all x ψ<sub>2</sub>(x)= A cos x,for all x Ψ<sub>3</sub>(x)= ψ<sub>4</sub>(x)= ψ<sub>5</sub>(x)= Which of the five possible wave functions are normalizable? (There may be more than one correct choice.)</strong> A) ψ<sub>1</sub>(x) B) ψ<sub>2</sub>(x) C) ψ<sub>3</sub>(x) D) ψ<sub>4</sub>(x) E) ψ<sub>5</sub>(x) <div style=padding-top: 35px> ψ5(x)= <strong>A set of five possible wave functions is given below,where L is a positive real number. ψ<sub>1</sub>(x)= Ae<sup>-</sup><sup>x</sup>,for all x ψ<sub>2</sub>(x)= A cos x,for all x Ψ<sub>3</sub>(x)= ψ<sub>4</sub>(x)= ψ<sub>5</sub>(x)= Which of the five possible wave functions are normalizable? (There may be more than one correct choice.)</strong> A) ψ<sub>1</sub>(x) B) ψ<sub>2</sub>(x) C) ψ<sub>3</sub>(x) D) ψ<sub>4</sub>(x) E) ψ<sub>5</sub>(x) <div style=padding-top: 35px> Which of the five possible wave functions are normalizable? (There may be more than one correct choice.)

A) ψ1(x)
B) ψ2(x)
C) ψ3(x)
D) ψ4(x)
E) ψ5(x)
Question
An electron is in an infinite square well (a box)that is 8.9 nm wide.What is the ground state energy of the electron? (h = 6.626 × 10-34 J ∙ s,mel = 9.11 × 10-31 kg, <strong>An electron is in an infinite square well (a box)that is 8.9 nm wide.What is the ground state energy of the electron? (h = 6.626 × 10<sup>-34</sup> J ∙ s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg, </strong> A) 0.0048 eV B) 0.0057 eV C) 0.0066 eV D) 0.0076 eV E) 0.0085 eV <div style=padding-top: 35px>

A) 0.0048 eV
B) 0.0057 eV
C) 0.0066 eV
D) 0.0076 eV
E) 0.0085 eV
Question
Find the value of A to normalize the wave function ψ(x)= <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E) <div style=padding-top: 35px> .

A) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E) <div style=padding-top: 35px>
B) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E) <div style=padding-top: 35px>
C) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E) <div style=padding-top: 35px>
D) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E) <div style=padding-top: 35px>
E) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E) <div style=padding-top: 35px>
Question
The ground state energy of a particle in a one-dimensional infinite potential well of width <strong>The ground state energy of a particle in a one-dimensional infinite potential well of width is .The ground state energy of the same particle in a one-dimensional finite potential well with in the region 0 < x < 1.5 nm,and U<sub>0 </sub>= 50 eV everywhere else, would be</strong> A) less than 20 eV. B) greater than 20 eV. C) equal to 20 eV. D) The particle would not have a ground state. <div style=padding-top: 35px> is <strong>The ground state energy of a particle in a one-dimensional infinite potential well of width is .The ground state energy of the same particle in a one-dimensional finite potential well with in the region 0 < x < 1.5 nm,and U<sub>0 </sub>= 50 eV everywhere else, would be</strong> A) less than 20 eV. B) greater than 20 eV. C) equal to 20 eV. D) The particle would not have a ground state. <div style=padding-top: 35px> .The ground state energy of the same particle in a one-dimensional finite potential well with <strong>The ground state energy of a particle in a one-dimensional infinite potential well of width is .The ground state energy of the same particle in a one-dimensional finite potential well with in the region 0 < x < 1.5 nm,and U<sub>0 </sub>= 50 eV everywhere else, would be</strong> A) less than 20 eV. B) greater than 20 eV. C) equal to 20 eV. D) The particle would not have a ground state. <div style=padding-top: 35px> in the region 0 < x < 1.5 nm,and U0 = 50 eV everywhere else, would be

A) less than 20 eV.
B) greater than 20 eV.
C) equal to 20 eV.
D) The particle would not have a ground state.
Question
The wave function for an electron that is confined to x ≥ 0 nm is
ψ(x)= The wave function for an electron that is confined to x ≥ 0 nm is ψ(x)= (a)What must be the value of A? (b)What is the probability of finding the electron in the interval 1.15 nm ≤ x ≤ 1.84 nm?<div style=padding-top: 35px> (a)What must be the value of A?
(b)What is the probability of finding the electron in the interval 1.15 nm ≤ x ≤ 1.84 nm?
Question
An electron is in the ground state of an infinite well (a box)where its energy is 5.00 eV.In the next higher level,what would its energy be? (1 eV = 1.60 × 10-19 J)

A) 1.25 eV
B) 2.50 eV
C) 10.0 eV
D) 15.0 eV
E) 20.0 eV
Question
A particle is confined to a one-dimensional box (an infinite well)on the x-axis between <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L <div style=padding-top: 35px> and <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L <div style=padding-top: 35px> .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L <div style=padding-top: 35px> sin <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L <div style=padding-top: 35px> ,with <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L <div style=padding-top: 35px> .What is the maximum probability per unit length of finding the particle?

A) 1/ <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L <div style=padding-top: 35px>
B) <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L <div style=padding-top: 35px>
C) 2/ <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L <div style=padding-top: 35px>
D) 1/L
E) 2/L
Question
A particle confined in a rigid one-dimensional box (an infinite well)of length 17.0 fm has an energy level <strong>A particle confined in a rigid one-dimensional box (an infinite well)of length 17.0 fm has an energy level and an adjacent energy level E<sub>n</sub><sub>+1</sub> = 37.5 MeV.What is the value of the ground state energy? (1 eV = 1.60 × 10<sup>-19</sup> J)</strong> A) 1.50 MeV B) 13.5 MeV C) 0.500 MeV D) 4.50 MeV <div style=padding-top: 35px> and an adjacent energy level En+1 = 37.5 MeV.What is the value of the ground state energy? (1 eV = 1.60 × 10-19 J)

A) 1.50 MeV
B) 13.5 MeV
C) 0.500 MeV
D) 4.50 MeV
Question
The atoms in a nickel crystal vibrate as harmonic oscillators with an angular frequency of 2.3 × 1013 rad/s.The mass of a nickel atom is 9.75 × 10-26 kg.What is the difference in energy between adjacent vibrational energy levels of nickel? (h = 6.626 × 10-34 J • s,
H = 1.055 × 10-34 J • s,1 eV = 1.60 × 10-19 J)

A) 0.015 eV
B) 0.019 eV
C) 0.023 eV
D) 0.027 eV
E) 0.031 eV
Question
An electron in an infinite potential well (a box)makes a transition from the n = 3 level to the ground state and in so doing emits a photon of wavelength 20.9 nm.(c = 3.00 × 108 m/s, An electron in an infinite potential well (a box)makes a transition from the n = 3 level to the ground state and in so doing emits a photon of wavelength 20.9 nm.(c = 3.00 × 10<sup>8</sup> m/s, ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) (a)What is the width of this well? (b)What wavelength photon would be required to excite the electron from its original level to the next higher one?<div style=padding-top: 35px> ,mel = 9.11 × 10-31 kg)
(a)What is the width of this well?
(b)What wavelength photon would be required to excite the electron from its original level to the next higher one?
Question
An 80-eV electron impinges upon a potential barrier 100 eV high and 0.20 nm thick.What is the probability the electron will tunnel through the barrier? (1 eV = 1.60 × 10-19 J, <strong>An 80-eV electron impinges upon a potential barrier 100 eV high and 0.20 nm thick.What is the probability the electron will tunnel through the barrier? (1 eV = 1.60 × 10<sup>-19</sup> J, ,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 0.027% B) 2.7% C) 0.27% D) 2.8 × 10<sup>-4</sup> % E) 2.0 × 10<sup>-9</sup> % <div style=padding-top: 35px> ,h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 0.027%
B) 2.7%
C) 0.27%
D) 2.8 × 10-4 %
E) 2.0 × 10-9 %
Question
A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? <strong>A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? </strong> A) 8.0 × J B) 3.2 × J C) 1.3 × J D) zero <div style=padding-top: 35px>

A) 8.0 × <strong>A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? </strong> A) 8.0 × J B) 3.2 × J C) 1.3 × J D) zero <div style=padding-top: 35px> J
B) 3.2 × <strong>A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? </strong> A) 8.0 × J B) 3.2 × J C) 1.3 × J D) zero <div style=padding-top: 35px> J
C) 1.3 × <strong>A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? </strong> A) 8.0 × J B) 3.2 × J C) 1.3 × J D) zero <div style=padding-top: 35px> J
D) zero
Question
The lowest energy level of a certain quantum harmonic oscillator is 5.00 eV.What is the energy of the next higher level?

A) 7.50 eV
B) 10.0 eV
C) 15.0 eV
D) 20.0 eV
E) 50.0 eV
Question
A 3.10-eV electron is incident on a 0.40-nm barrier that is 5.67 eV high.What is the probability that this electron will tunnel through the barrier? (1 eV = 1.60 × 10-19 J, <strong>A 3.10-eV electron is incident on a 0.40-nm barrier that is 5.67 eV high.What is the probability that this electron will tunnel through the barrier? (1 eV = 1.60 × 10<sup>-19</sup> J, ,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 0.56% B) 0.35% C) 0.40% D) 0.25% E) 0.48% <div style=padding-top: 35px> ,h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 0.56%
B) 0.35%
C) 0.40%
D) 0.25%
E) 0.48%
Question
Calculate the ground state energy of a harmonic oscillator with a classical frequency of <strong>Calculate the ground state energy of a harmonic oscillator with a classical frequency of .(1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 7.62 eV B) 15.2 eV C) 11.4 eV D) 5.71 eV <div style=padding-top: 35px> .(1 eV = 1.60 × 10-19 J,h = 1.055 × 10-34 J • s, <strong>Calculate the ground state energy of a harmonic oscillator with a classical frequency of .(1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 7.62 eV B) 15.2 eV C) 11.4 eV D) 5.71 eV <div style=padding-top: 35px>

A) 7.62 eV
B) 15.2 eV
C) 11.4 eV
D) 5.71 eV
Question
Find the wavelength of the photon emitted during the transition from the second EXCITED state to the ground state in a harmonic oscillator with a classical frequency of <strong>Find the wavelength of the photon emitted during the transition from the second EXCITED state to the ground state in a harmonic oscillator with a classical frequency of (c = 3.00 × 10<sup>8</sup> m/s,1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 4.03 μm B) 2.26 μm C) 2.98 μm D) 5.24 μm <div style=padding-top: 35px> (c = 3.00 × 108 m/s,1 eV = 1.60 × 10-19 J,h = 1.055 × 10-34 J • s, <strong>Find the wavelength of the photon emitted during the transition from the second EXCITED state to the ground state in a harmonic oscillator with a classical frequency of (c = 3.00 × 10<sup>8</sup> m/s,1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 4.03 μm B) 2.26 μm C) 2.98 μm D) 5.24 μm <div style=padding-top: 35px>

A) 4.03 μm
B) 2.26 μm
C) 2.98 μm
D) 5.24 μm
Question
A lithium atom,mass 1.17 × 10-26 kg,vibrates with simple harmonic motion in a crystal lattice,where the effective force constant of the forces on the atom is k = A lithium atom,mass 1.17 × 10<sup>-26</sup> kg,vibrates with simple harmonic motion in a crystal lattice,where the effective force constant of the forces on the atom is k = ,h = 6.626 × 10<sup>-34</sup> J • s,h = 1.055 × 10<sup>-34</sup> J • s, (a)What is the ground state energy of this system,in eV? (b)What is the wavelength of the photon that could excite this system from the ground state to the first excited state?<div style=padding-top: 35px> A lithium atom,mass 1.17 × 10<sup>-26</sup> kg,vibrates with simple harmonic motion in a crystal lattice,where the effective force constant of the forces on the atom is k = ,h = 6.626 × 10<sup>-34</sup> J • s,h = 1.055 × 10<sup>-34</sup> J • s, (a)What is the ground state energy of this system,in eV? (b)What is the wavelength of the photon that could excite this system from the ground state to the first excited state?<div style=padding-top: 35px> ,h = 6.626 × 10-34 J • s,h = 1.055 × 10-34 J • s, A lithium atom,mass 1.17 × 10<sup>-26</sup> kg,vibrates with simple harmonic motion in a crystal lattice,where the effective force constant of the forces on the atom is k = ,h = 6.626 × 10<sup>-34</sup> J • s,h = 1.055 × 10<sup>-34</sup> J • s, (a)What is the ground state energy of this system,in eV? (b)What is the wavelength of the photon that could excite this system from the ground state to the first excited state?<div style=padding-top: 35px> (a)What is the ground state energy of this system,in eV?
(b)What is the wavelength of the photon that could excite this system from the ground state to the first excited state?
Question
The energy of a particle in the second EXCITED state of a harmonic oscillator potential is <strong>The energy of a particle in the second EXCITED state of a harmonic oscillator potential is What is the classical angular frequency of oscillation of this particle? ,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 3.31 × 10<sup>15</sup> rad/s B) 2.08 × 10<sup>16</sup> rad/s C) 4.96 × 10<sup>15</sup> rad/s D) 6.95 × 10<sup>15</sup> rad/s <div style=padding-top: 35px> What is the classical angular frequency of oscillation of this particle? <strong>The energy of a particle in the second EXCITED state of a harmonic oscillator potential is What is the classical angular frequency of oscillation of this particle? ,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 3.31 × 10<sup>15</sup> rad/s B) 2.08 × 10<sup>16</sup> rad/s C) 4.96 × 10<sup>15</sup> rad/s D) 6.95 × 10<sup>15</sup> rad/s <div style=padding-top: 35px> ,h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 3.31 × 1015 rad/s
B) 2.08 × 1016 rad/s
C) 4.96 × 1015 rad/s
D) 6.95 × 1015 rad/s
Question
You want to have an electron in an energy level where its speed is no more than 66 m/s.What is the length of the smallest box (an infinite well)in which you can do this? <strong>You want to have an electron in an energy level where its speed is no more than 66 m/s.What is the length of the smallest box (an infinite well)in which you can do this? ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg)</strong> A) 5.5 µm B) 11 µm C) 2.8 µm D) 1.4 µm <div style=padding-top: 35px> ,mel = 9.11 × 10-31 kg)

A) 5.5 µm
B) 11 µm
C) 2.8 µm
D) 1.4 µm
Question
The energy of a proton is 1.0 MeV below the top of a 1.2-MeV-high energy barrier that is 6.8 fm wide.What is the probability that the proton will tunnel through the barrier? <strong>The energy of a proton is 1.0 MeV below the top of a 1.2-MeV-high energy barrier that is 6.8 fm wide.What is the probability that the proton will tunnel through the barrier? ,m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 11% B) 9.1% C) 14% D) 7.5% <div style=padding-top: 35px> ,mproton = 1.67 × 10-27 kg,h = 1.055 × 10-34 J • s, <strong>The energy of a proton is 1.0 MeV below the top of a 1.2-MeV-high energy barrier that is 6.8 fm wide.What is the probability that the proton will tunnel through the barrier? ,m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 11% B) 9.1% C) 14% D) 7.5% <div style=padding-top: 35px>

A) 11%
B) 9.1%
C) 14%
D) 7.5%
Question
The wave function of an electron in a rigid box (infinite well)is shown in the figure.If the electron energy 98.0 eV,what is the energy of the electron's ground state? <strong>The wave function of an electron in a rigid box (infinite well)is shown in the figure.If the electron energy 98.0 eV,what is the energy of the electron's ground state? </strong> A) 6.13 eV B) 3.92 eV C) 10.9 eV D) 24.5 eV <div style=padding-top: 35px> <strong>The wave function of an electron in a rigid box (infinite well)is shown in the figure.If the electron energy 98.0 eV,what is the energy of the electron's ground state? </strong> A) 6.13 eV B) 3.92 eV C) 10.9 eV D) 24.5 eV <div style=padding-top: 35px>

A) 6.13 eV
B) 3.92 eV
C) 10.9 eV
D) 24.5 eV
Question
An electron is confined in a one-dimensional box (an infinite well).Two adjacent allowed energies of the electron are 1.068 × 10-18 J and 1.352 × 10-18 J.What is the length of the box? (h = 6.626 × 10-34 J • s,mel = 9.11 × 10-31 kg)

A) 1.9 nm
B) 0.93 nm
C) 1.1 nm
D) 2.3 nm
Question
An electron is trapped in an infinite square well (a box)of width <strong>An electron is trapped in an infinite square well (a box)of width Find the wavelength of photons emitted when the electron drops from the n = 5 state to the in this system.(c = 3.00 × 10<sup>8</sup> m/s,h = 6.626 × 10<sup>-34</sup>J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg)</strong> A) 6.49 μm B) 5.45 μm C) 5.91 μm D) 7.07 μm <div style=padding-top: 35px> Find the wavelength of photons emitted when the electron drops from the n = 5 state to the <strong>An electron is trapped in an infinite square well (a box)of width Find the wavelength of photons emitted when the electron drops from the n = 5 state to the in this system.(c = 3.00 × 10<sup>8</sup> m/s,h = 6.626 × 10<sup>-34</sup>J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg)</strong> A) 6.49 μm B) 5.45 μm C) 5.91 μm D) 7.07 μm <div style=padding-top: 35px> in this system.(c = 3.00 × 108 m/s,h = 6.626 × 10-34J • s,mel = 9.11 × 10-31 kg)

A) 6.49 μm
B) 5.45 μm
C) 5.91 μm
D) 7.07 μm
Question
An electron is bound in an infinite well (a box)of width 0.10 nm.If the electron is initially in the n = 8 state and falls to the n = 7 state,find the wavelength of the emitted photon. An electron is bound in an infinite well (a box)of width 0.10 nm.If the electron is initially in the n = 8 state and falls to the n = 7 state,find the wavelength of the emitted photon. ,h = 6.626 × 10<sup>-34</sup> J ∙ s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg)<div style=padding-top: 35px> ,h = 6.626 × 10-34 J ∙ s,mel = 9.11 × 10-31 kg)
Question
One fairly crude method of determining the size of a molecule is to treat the molecule as an infinite square well (a box)with an electron trapped inside,and to measure the wavelengths of emitted photons.If the photon emitted during the n = 2 to n = 1 transition has wavelength 1940 nm,what is the width of the molecule? (c = 3.00 × 108 m/s, <strong>One fairly crude method of determining the size of a molecule is to treat the molecule as an infinite square well (a box)with an electron trapped inside,and to measure the wavelengths of emitted photons.If the photon emitted during the n = 2 to n = 1 transition has wavelength 1940 nm,what is the width of the molecule? (c = 3.00 × 10<sup>8</sup> m/s, , </strong> A) 1.33 nm B) 1.12 nm C) 1.21 nm D) 1.45 nm <div style=padding-top: 35px> , <strong>One fairly crude method of determining the size of a molecule is to treat the molecule as an infinite square well (a box)with an electron trapped inside,and to measure the wavelengths of emitted photons.If the photon emitted during the n = 2 to n = 1 transition has wavelength 1940 nm,what is the width of the molecule? (c = 3.00 × 10<sup>8</sup> m/s, , </strong> A) 1.33 nm B) 1.12 nm C) 1.21 nm D) 1.45 nm <div style=padding-top: 35px>

A) 1.33 nm
B) 1.12 nm
C) 1.21 nm
D) 1.45 nm
Question
An electron with kinetic energy 2.80 eV encounters a potential barrier of height 4.70 eV.If the barrier width is 0.40 nm,what is the probability that the electron will tunnel through the barrier? (1 eV = 1.60 × 10-19 J,mel = 9.11 × 10-31 kg,h = 6.626 × 10-34 J • s)

A) 1.4 × 10-2
B) 2.8 × 10-2
C) 5.5 × 10-2
D) 1.1 × 10-2
E) 1.4 × 10-1
Question
You want to confine an electron in a box (an infinite well)so that its ground state energy is 5.0 × 10-18 J.What should be the length of the box? (h = 6.626 × 10-34 J • s, <strong>You want to confine an electron in a box (an infinite well)so that its ground state energy is 5.0 × 10<sup>-18</sup> J.What should be the length of the box? (h = 6.626 × 10<sup>-34</sup> J • s, </strong> A) 0.11 nm B) 0.22 nm C) 0.15 nm D) 0.18 nm <div style=padding-top: 35px>

A) 0.11 nm
B) 0.22 nm
C) 0.15 nm
D) 0.18 nm
Question
A one-dimensional finite potential well has potential energy U0 = 0 in the region 0 < x < .2 nm,and <strong>A one-dimensional finite potential well has potential energy U<sub>0 </sub>= 0 in the region 0 < x < .2 nm,and everywhere else.A particle with which of the energies listed below would be localized (trapped)within the potential well? (Select all correct answers.)</strong> A) 5 eV B) 20 eV C) 16 eV D) 7 eV E) None of the above <div style=padding-top: 35px> everywhere else.A particle with which of the energies listed below would be localized (trapped)within the potential well? (Select all correct answers.)

A) 5 eV
B) 20 eV
C) 16 eV
D) 7 eV
E) None of the above
Question
An electron is confined in a harmonic oscillator potential well.A photon is emitted when the electron undergoes a 3→1 quantum jump.What is the wavelength of the emission if the net force on the electron behaves as though it has a spring constant of <strong>An electron is confined in a harmonic oscillator potential well.A photon is emitted when the electron undergoes a 3→1 quantum jump.What is the wavelength of the emission if the net force on the electron behaves as though it has a spring constant of , c = 3.00 × 10<sup>8</sup> m/s,1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 290 nm B) 150 nm C) 190 nm D) 580 nm <div style=padding-top: 35px> <strong>An electron is confined in a harmonic oscillator potential well.A photon is emitted when the electron undergoes a 3→1 quantum jump.What is the wavelength of the emission if the net force on the electron behaves as though it has a spring constant of , c = 3.00 × 10<sup>8</sup> m/s,1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 290 nm B) 150 nm C) 190 nm D) 580 nm <div style=padding-top: 35px> , c = 3.00 × 108 m/s,1 eV = 1.60 × 10-19 J,h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 290 nm
B) 150 nm
C) 190 nm
D) 580 nm
Question
An electron is confined in a harmonic oscillator potential well.What is the longest wavelength of light that the electron can absorb if the net force on the electron behaves as though it has a spring constant of 74 N/m? (mel = 9.11 × 10-31 kg,c = 3.00 × 108 m/s, <strong>An electron is confined in a harmonic oscillator potential well.What is the longest wavelength of light that the electron can absorb if the net force on the electron behaves as though it has a spring constant of 74 N/m? (m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg,c = 3.00 × 10<sup>8</sup> m/s, h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 210 nm B) 200 nm C) 220 nm D) 230 nm <div style=padding-top: 35px> h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 210 nm
B) 200 nm
C) 220 nm
D) 230 nm
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Deck 40: Quantum Mechanics
1
An electron is in an infinite square well (a box)that is 2.0 nm wide.The electron makes a transition from the <strong>An electron is in an infinite square well (a box)that is 2.0 nm wide.The electron makes a transition from the to the state,what is the wavelength of the emitted photon? ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 880 nm B) 750 nm C) 610 nm D) 1000 nm E) 1100 nm to the <strong>An electron is in an infinite square well (a box)that is 2.0 nm wide.The electron makes a transition from the to the state,what is the wavelength of the emitted photon? ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 880 nm B) 750 nm C) 610 nm D) 1000 nm E) 1100 nm state,what is the wavelength of the emitted photon? <strong>An electron is in an infinite square well (a box)that is 2.0 nm wide.The electron makes a transition from the to the state,what is the wavelength of the emitted photon? ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 880 nm B) 750 nm C) 610 nm D) 1000 nm E) 1100 nm ,mel = 9.11 × 10-31 kg,1 eV = 1.60 × 10-19)

A) 880 nm
B) 750 nm
C) 610 nm
D) 1000 nm
E) 1100 nm
880 nm
2
The square of the wave function of a particle,|ψ(x)|2,gives the probability of finding the particle at the point x.
False
3
A particle is confined to a one-dimensional box (an infinite well)on the x-axis between <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 and <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 sin <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 ,with <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the probability of finding the particle between x = 0 and x = L/3?</strong> A) 0.20 B) 0.22 C) 0.24 D) 0.26 E) 0.28 .What is the probability of finding the particle between x = 0 and x = L/3?

A) 0.20
B) 0.22
C) 0.24
D) 0.26
E) 0.28
0.20
4
Find the value of A to normalize the wave function ψ(x)= <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) 1/L B) C) 1/L<sup>2</sup> D) 1. E) 1/ .

A) 1/L
B) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) 1/L B) C) 1/L<sup>2</sup> D) 1. E) 1/
C) 1/L2
D) 1. <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) 1/L B) C) 1/L<sup>2</sup> D) 1. E) 1/
E) 1/ <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) 1/L B) C) 1/L<sup>2</sup> D) 1. E) 1/
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5
An electron is in an infinite square well that is 2.6 nm wide.What is the smallest value of the state quantum number n for which the energy level exceeds 100 eV? <strong>An electron is in an infinite square well that is 2.6 nm wide.What is the smallest value of the state quantum number n for which the energy level exceeds 100 eV? , ,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 43 B) 44 C) 45 D) 42 E) 41 , <strong>An electron is in an infinite square well that is 2.6 nm wide.What is the smallest value of the state quantum number n for which the energy level exceeds 100 eV? , ,1 eV = 1.60 × 10<sup>-19</sup>)</strong> A) 43 B) 44 C) 45 D) 42 E) 41 ,1 eV = 1.60 × 10-19)

A) 43
B) 44
C) 45
D) 42
E) 41
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6
An electron is bound in an infinite square-well potential (a box)on the x-axis.The width of the well is L and the well extends from x = 0.00 nm to <strong>An electron is bound in an infinite square-well potential (a box)on the x-axis.The width of the well is L and the well extends from x = 0.00 nm to In its present state,the normalized wave function of the electron is given by: ψ(x)=<sub> </sub> <sub> </sub> sin (2πx/L).What is the energy of the electron in this state?(h = 6.626 × 10<sup>-34</sup> J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg, </strong> A) 0.10 eV B) 0.052 eV C) 0.13 eV D) 0.078 eV E) 0.026 eV In its present state,the normalized wave function of the electron is given by: ψ(x)= <strong>An electron is bound in an infinite square-well potential (a box)on the x-axis.The width of the well is L and the well extends from x = 0.00 nm to In its present state,the normalized wave function of the electron is given by: ψ(x)=<sub> </sub> <sub> </sub> sin (2πx/L).What is the energy of the electron in this state?(h = 6.626 × 10<sup>-34</sup> J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg, </strong> A) 0.10 eV B) 0.052 eV C) 0.13 eV D) 0.078 eV E) 0.026 eV sin (2πx/L).What is the energy of the electron in this state?(h = 6.626 × 10-34 J • s,mel = 9.11 × 10-31 kg, <strong>An electron is bound in an infinite square-well potential (a box)on the x-axis.The width of the well is L and the well extends from x = 0.00 nm to In its present state,the normalized wave function of the electron is given by: ψ(x)=<sub> </sub> <sub> </sub> sin (2πx/L).What is the energy of the electron in this state?(h = 6.626 × 10<sup>-34</sup> J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg, </strong> A) 0.10 eV B) 0.052 eV C) 0.13 eV D) 0.078 eV E) 0.026 eV

A) 0.10 eV
B) 0.052 eV
C) 0.13 eV
D) 0.078 eV
E) 0.026 eV
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7
The smallest kinetic energy that an electron in a box (an infinite well)can have is zero.
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8
The lowest energy level of a particle confined to a one-dimensional region of space (a box,or infinite well)with fixed length L is E0.If an identical particle is confined to a similar region with fixed length L/6,what is the energy of the lowest energy level that the particles have in common? Express your answer in terms of E0.
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9
A particle trapped in a one-dimensional finite potential well with U0 = 0 in the region <strong>A particle trapped in a one-dimensional finite potential well with U<sub>0 </sub>= 0 in the region ,and finite U<sub>0</sub> everywhere else,has a ground state wavenumber,k.The ground state wavenumber for the same particle in an infinite one-dimensional potential well of width L,would be</strong> A) less than k. B) greater than k. C) equal to k. D) There is not enough information to determine. ,and finite U0 everywhere else,has a ground state wavenumber,k.The ground state wavenumber for the same particle in an infinite one-dimensional potential well of width L,would be

A) less than k.
B) greater than k.
C) equal to k.
D) There is not enough information to determine.
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10
If an atom in a crystal is acted upon by a restoring force that is directly proportional to the distance of the atom from its equilibrium position in the crystal,then it is impossible for the atom to have zero kinetic energy.
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11
The wave function for a particle must be normalizable because

A) the particle's momentum must be conserved.
B) the particle's angular momentum must be conserved.
C) the particle's charge must be conserved.
D) the particle must be somewhere.
E) the particle cannot be in two places at the same time.
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12
The wave function for an electron that is confined to x ≥ 0 nm is
ψ(x)= The wave function for an electron that is confined to x ≥ 0 nm is ψ(x)= (a)What must be the value of b? (b)What is the probability of finding the electron in a 0.010 nm-wide region centered at ? (a)What must be the value of b?
(b)What is the probability of finding the electron in a 0.010 nm-wide region centered at The wave function for an electron that is confined to x ≥ 0 nm is ψ(x)= (a)What must be the value of b? (b)What is the probability of finding the electron in a 0.010 nm-wide region centered at ? ?
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13
The probability density for an electron that has passed through an experimental apparatus is shown in the figure.If 4100 electrons pass through the apparatus,what is the expected number that will land in a 0.10 mm-wide strip centered at x = 0.00 mm? <strong>The probability density for an electron that has passed through an experimental apparatus is shown in the figure.If 4100 electrons pass through the apparatus,what is the expected number that will land in a 0.10 mm-wide strip centered at x = 0.00 mm? </strong> A) 140 B) 1400 C) 450 D) 45

A) 140
B) 1400
C) 450
D) 45
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14
A set of five possible wave functions is given below,where L is a positive real number. ψ1(x)= Ae-x,for all x ψ2(x)= A cos x,for all x
Ψ3(x)= <strong>A set of five possible wave functions is given below,where L is a positive real number. ψ<sub>1</sub>(x)= Ae<sup>-</sup><sup>x</sup>,for all x ψ<sub>2</sub>(x)= A cos x,for all x Ψ<sub>3</sub>(x)= ψ<sub>4</sub>(x)= ψ<sub>5</sub>(x)= Which of the five possible wave functions are normalizable? (There may be more than one correct choice.)</strong> A) ψ<sub>1</sub>(x) B) ψ<sub>2</sub>(x) C) ψ<sub>3</sub>(x) D) ψ<sub>4</sub>(x) E) ψ<sub>5</sub>(x) ψ4(x)= <strong>A set of five possible wave functions is given below,where L is a positive real number. ψ<sub>1</sub>(x)= Ae<sup>-</sup><sup>x</sup>,for all x ψ<sub>2</sub>(x)= A cos x,for all x Ψ<sub>3</sub>(x)= ψ<sub>4</sub>(x)= ψ<sub>5</sub>(x)= Which of the five possible wave functions are normalizable? (There may be more than one correct choice.)</strong> A) ψ<sub>1</sub>(x) B) ψ<sub>2</sub>(x) C) ψ<sub>3</sub>(x) D) ψ<sub>4</sub>(x) E) ψ<sub>5</sub>(x) ψ5(x)= <strong>A set of five possible wave functions is given below,where L is a positive real number. ψ<sub>1</sub>(x)= Ae<sup>-</sup><sup>x</sup>,for all x ψ<sub>2</sub>(x)= A cos x,for all x Ψ<sub>3</sub>(x)= ψ<sub>4</sub>(x)= ψ<sub>5</sub>(x)= Which of the five possible wave functions are normalizable? (There may be more than one correct choice.)</strong> A) ψ<sub>1</sub>(x) B) ψ<sub>2</sub>(x) C) ψ<sub>3</sub>(x) D) ψ<sub>4</sub>(x) E) ψ<sub>5</sub>(x) Which of the five possible wave functions are normalizable? (There may be more than one correct choice.)

A) ψ1(x)
B) ψ2(x)
C) ψ3(x)
D) ψ4(x)
E) ψ5(x)
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15
An electron is in an infinite square well (a box)that is 8.9 nm wide.What is the ground state energy of the electron? (h = 6.626 × 10-34 J ∙ s,mel = 9.11 × 10-31 kg, <strong>An electron is in an infinite square well (a box)that is 8.9 nm wide.What is the ground state energy of the electron? (h = 6.626 × 10<sup>-34</sup> J ∙ s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg, </strong> A) 0.0048 eV B) 0.0057 eV C) 0.0066 eV D) 0.0076 eV E) 0.0085 eV

A) 0.0048 eV
B) 0.0057 eV
C) 0.0066 eV
D) 0.0076 eV
E) 0.0085 eV
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16
Find the value of A to normalize the wave function ψ(x)= <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E) .

A) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E)
B) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E)
C) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E)
D) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E)
E) <strong>Find the value of A to normalize the wave function ψ(x)= .</strong> A) B) C) D) E)
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17
The ground state energy of a particle in a one-dimensional infinite potential well of width <strong>The ground state energy of a particle in a one-dimensional infinite potential well of width is .The ground state energy of the same particle in a one-dimensional finite potential well with in the region 0 < x < 1.5 nm,and U<sub>0 </sub>= 50 eV everywhere else, would be</strong> A) less than 20 eV. B) greater than 20 eV. C) equal to 20 eV. D) The particle would not have a ground state. is <strong>The ground state energy of a particle in a one-dimensional infinite potential well of width is .The ground state energy of the same particle in a one-dimensional finite potential well with in the region 0 < x < 1.5 nm,and U<sub>0 </sub>= 50 eV everywhere else, would be</strong> A) less than 20 eV. B) greater than 20 eV. C) equal to 20 eV. D) The particle would not have a ground state. .The ground state energy of the same particle in a one-dimensional finite potential well with <strong>The ground state energy of a particle in a one-dimensional infinite potential well of width is .The ground state energy of the same particle in a one-dimensional finite potential well with in the region 0 < x < 1.5 nm,and U<sub>0 </sub>= 50 eV everywhere else, would be</strong> A) less than 20 eV. B) greater than 20 eV. C) equal to 20 eV. D) The particle would not have a ground state. in the region 0 < x < 1.5 nm,and U0 = 50 eV everywhere else, would be

A) less than 20 eV.
B) greater than 20 eV.
C) equal to 20 eV.
D) The particle would not have a ground state.
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18
The wave function for an electron that is confined to x ≥ 0 nm is
ψ(x)= The wave function for an electron that is confined to x ≥ 0 nm is ψ(x)= (a)What must be the value of A? (b)What is the probability of finding the electron in the interval 1.15 nm ≤ x ≤ 1.84 nm? (a)What must be the value of A?
(b)What is the probability of finding the electron in the interval 1.15 nm ≤ x ≤ 1.84 nm?
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19
An electron is in the ground state of an infinite well (a box)where its energy is 5.00 eV.In the next higher level,what would its energy be? (1 eV = 1.60 × 10-19 J)

A) 1.25 eV
B) 2.50 eV
C) 10.0 eV
D) 15.0 eV
E) 20.0 eV
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20
A particle is confined to a one-dimensional box (an infinite well)on the x-axis between <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L and <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L sin <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L ,with <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L .What is the maximum probability per unit length of finding the particle?

A) 1/ <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L
B) <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L
C) 2/ <strong>A particle is confined to a one-dimensional box (an infinite well)on the x-axis between and .The potential height of the walls of the box is infinite.The normalized wave function of the particle,which is in the ground state,is given by ψ(x)= sin ,with .What is the maximum probability per unit length of finding the particle?</strong> A) 1/ B) C) 2/ D) 1/L E) 2/L
D) 1/L
E) 2/L
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21
A particle confined in a rigid one-dimensional box (an infinite well)of length 17.0 fm has an energy level <strong>A particle confined in a rigid one-dimensional box (an infinite well)of length 17.0 fm has an energy level and an adjacent energy level E<sub>n</sub><sub>+1</sub> = 37.5 MeV.What is the value of the ground state energy? (1 eV = 1.60 × 10<sup>-19</sup> J)</strong> A) 1.50 MeV B) 13.5 MeV C) 0.500 MeV D) 4.50 MeV and an adjacent energy level En+1 = 37.5 MeV.What is the value of the ground state energy? (1 eV = 1.60 × 10-19 J)

A) 1.50 MeV
B) 13.5 MeV
C) 0.500 MeV
D) 4.50 MeV
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22
The atoms in a nickel crystal vibrate as harmonic oscillators with an angular frequency of 2.3 × 1013 rad/s.The mass of a nickel atom is 9.75 × 10-26 kg.What is the difference in energy between adjacent vibrational energy levels of nickel? (h = 6.626 × 10-34 J • s,
H = 1.055 × 10-34 J • s,1 eV = 1.60 × 10-19 J)

A) 0.015 eV
B) 0.019 eV
C) 0.023 eV
D) 0.027 eV
E) 0.031 eV
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23
An electron in an infinite potential well (a box)makes a transition from the n = 3 level to the ground state and in so doing emits a photon of wavelength 20.9 nm.(c = 3.00 × 108 m/s, An electron in an infinite potential well (a box)makes a transition from the n = 3 level to the ground state and in so doing emits a photon of wavelength 20.9 nm.(c = 3.00 × 10<sup>8</sup> m/s, ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) (a)What is the width of this well? (b)What wavelength photon would be required to excite the electron from its original level to the next higher one? ,mel = 9.11 × 10-31 kg)
(a)What is the width of this well?
(b)What wavelength photon would be required to excite the electron from its original level to the next higher one?
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24
An 80-eV electron impinges upon a potential barrier 100 eV high and 0.20 nm thick.What is the probability the electron will tunnel through the barrier? (1 eV = 1.60 × 10-19 J, <strong>An 80-eV electron impinges upon a potential barrier 100 eV high and 0.20 nm thick.What is the probability the electron will tunnel through the barrier? (1 eV = 1.60 × 10<sup>-19</sup> J, ,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 0.027% B) 2.7% C) 0.27% D) 2.8 × 10<sup>-4</sup> % E) 2.0 × 10<sup>-9</sup> % ,h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 0.027%
B) 2.7%
C) 0.27%
D) 2.8 × 10-4 %
E) 2.0 × 10-9 %
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25
A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? <strong>A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? </strong> A) 8.0 × J B) 3.2 × J C) 1.3 × J D) zero

A) 8.0 × <strong>A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? </strong> A) 8.0 × J B) 3.2 × J C) 1.3 × J D) zero J
B) 3.2 × <strong>A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? </strong> A) 8.0 × J B) 3.2 × J C) 1.3 × J D) zero J
C) 1.3 × <strong>A 10.0-g bouncy ball is confined in a 8.3-cm-long box (an infinite well).If we model the ball as a point particle,what is the minimum kinetic energy of the ball? </strong> A) 8.0 × J B) 3.2 × J C) 1.3 × J D) zero J
D) zero
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26
The lowest energy level of a certain quantum harmonic oscillator is 5.00 eV.What is the energy of the next higher level?

A) 7.50 eV
B) 10.0 eV
C) 15.0 eV
D) 20.0 eV
E) 50.0 eV
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27
A 3.10-eV electron is incident on a 0.40-nm barrier that is 5.67 eV high.What is the probability that this electron will tunnel through the barrier? (1 eV = 1.60 × 10-19 J, <strong>A 3.10-eV electron is incident on a 0.40-nm barrier that is 5.67 eV high.What is the probability that this electron will tunnel through the barrier? (1 eV = 1.60 × 10<sup>-19</sup> J, ,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 0.56% B) 0.35% C) 0.40% D) 0.25% E) 0.48% ,h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 0.56%
B) 0.35%
C) 0.40%
D) 0.25%
E) 0.48%
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28
Calculate the ground state energy of a harmonic oscillator with a classical frequency of <strong>Calculate the ground state energy of a harmonic oscillator with a classical frequency of .(1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 7.62 eV B) 15.2 eV C) 11.4 eV D) 5.71 eV .(1 eV = 1.60 × 10-19 J,h = 1.055 × 10-34 J • s, <strong>Calculate the ground state energy of a harmonic oscillator with a classical frequency of .(1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 7.62 eV B) 15.2 eV C) 11.4 eV D) 5.71 eV

A) 7.62 eV
B) 15.2 eV
C) 11.4 eV
D) 5.71 eV
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29
Find the wavelength of the photon emitted during the transition from the second EXCITED state to the ground state in a harmonic oscillator with a classical frequency of <strong>Find the wavelength of the photon emitted during the transition from the second EXCITED state to the ground state in a harmonic oscillator with a classical frequency of (c = 3.00 × 10<sup>8</sup> m/s,1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 4.03 μm B) 2.26 μm C) 2.98 μm D) 5.24 μm (c = 3.00 × 108 m/s,1 eV = 1.60 × 10-19 J,h = 1.055 × 10-34 J • s, <strong>Find the wavelength of the photon emitted during the transition from the second EXCITED state to the ground state in a harmonic oscillator with a classical frequency of (c = 3.00 × 10<sup>8</sup> m/s,1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 4.03 μm B) 2.26 μm C) 2.98 μm D) 5.24 μm

A) 4.03 μm
B) 2.26 μm
C) 2.98 μm
D) 5.24 μm
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30
A lithium atom,mass 1.17 × 10-26 kg,vibrates with simple harmonic motion in a crystal lattice,where the effective force constant of the forces on the atom is k = A lithium atom,mass 1.17 × 10<sup>-26</sup> kg,vibrates with simple harmonic motion in a crystal lattice,where the effective force constant of the forces on the atom is k = ,h = 6.626 × 10<sup>-34</sup> J • s,h = 1.055 × 10<sup>-34</sup> J • s, (a)What is the ground state energy of this system,in eV? (b)What is the wavelength of the photon that could excite this system from the ground state to the first excited state? A lithium atom,mass 1.17 × 10<sup>-26</sup> kg,vibrates with simple harmonic motion in a crystal lattice,where the effective force constant of the forces on the atom is k = ,h = 6.626 × 10<sup>-34</sup> J • s,h = 1.055 × 10<sup>-34</sup> J • s, (a)What is the ground state energy of this system,in eV? (b)What is the wavelength of the photon that could excite this system from the ground state to the first excited state? ,h = 6.626 × 10-34 J • s,h = 1.055 × 10-34 J • s, A lithium atom,mass 1.17 × 10<sup>-26</sup> kg,vibrates with simple harmonic motion in a crystal lattice,where the effective force constant of the forces on the atom is k = ,h = 6.626 × 10<sup>-34</sup> J • s,h = 1.055 × 10<sup>-34</sup> J • s, (a)What is the ground state energy of this system,in eV? (b)What is the wavelength of the photon that could excite this system from the ground state to the first excited state? (a)What is the ground state energy of this system,in eV?
(b)What is the wavelength of the photon that could excite this system from the ground state to the first excited state?
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31
The energy of a particle in the second EXCITED state of a harmonic oscillator potential is <strong>The energy of a particle in the second EXCITED state of a harmonic oscillator potential is What is the classical angular frequency of oscillation of this particle? ,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 3.31 × 10<sup>15</sup> rad/s B) 2.08 × 10<sup>16</sup> rad/s C) 4.96 × 10<sup>15</sup> rad/s D) 6.95 × 10<sup>15</sup> rad/s What is the classical angular frequency of oscillation of this particle? <strong>The energy of a particle in the second EXCITED state of a harmonic oscillator potential is What is the classical angular frequency of oscillation of this particle? ,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 3.31 × 10<sup>15</sup> rad/s B) 2.08 × 10<sup>16</sup> rad/s C) 4.96 × 10<sup>15</sup> rad/s D) 6.95 × 10<sup>15</sup> rad/s ,h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 3.31 × 1015 rad/s
B) 2.08 × 1016 rad/s
C) 4.96 × 1015 rad/s
D) 6.95 × 1015 rad/s
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32
You want to have an electron in an energy level where its speed is no more than 66 m/s.What is the length of the smallest box (an infinite well)in which you can do this? <strong>You want to have an electron in an energy level where its speed is no more than 66 m/s.What is the length of the smallest box (an infinite well)in which you can do this? ,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg)</strong> A) 5.5 µm B) 11 µm C) 2.8 µm D) 1.4 µm ,mel = 9.11 × 10-31 kg)

A) 5.5 µm
B) 11 µm
C) 2.8 µm
D) 1.4 µm
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33
The energy of a proton is 1.0 MeV below the top of a 1.2-MeV-high energy barrier that is 6.8 fm wide.What is the probability that the proton will tunnel through the barrier? <strong>The energy of a proton is 1.0 MeV below the top of a 1.2-MeV-high energy barrier that is 6.8 fm wide.What is the probability that the proton will tunnel through the barrier? ,m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 11% B) 9.1% C) 14% D) 7.5% ,mproton = 1.67 × 10-27 kg,h = 1.055 × 10-34 J • s, <strong>The energy of a proton is 1.0 MeV below the top of a 1.2-MeV-high energy barrier that is 6.8 fm wide.What is the probability that the proton will tunnel through the barrier? ,m<sub>proton</sub> = 1.67 × 10<sup>-27</sup> kg,h = 1.055 × 10<sup>-34</sup> J • s, </strong> A) 11% B) 9.1% C) 14% D) 7.5%

A) 11%
B) 9.1%
C) 14%
D) 7.5%
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34
The wave function of an electron in a rigid box (infinite well)is shown in the figure.If the electron energy 98.0 eV,what is the energy of the electron's ground state? <strong>The wave function of an electron in a rigid box (infinite well)is shown in the figure.If the electron energy 98.0 eV,what is the energy of the electron's ground state? </strong> A) 6.13 eV B) 3.92 eV C) 10.9 eV D) 24.5 eV <strong>The wave function of an electron in a rigid box (infinite well)is shown in the figure.If the electron energy 98.0 eV,what is the energy of the electron's ground state? </strong> A) 6.13 eV B) 3.92 eV C) 10.9 eV D) 24.5 eV

A) 6.13 eV
B) 3.92 eV
C) 10.9 eV
D) 24.5 eV
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35
An electron is confined in a one-dimensional box (an infinite well).Two adjacent allowed energies of the electron are 1.068 × 10-18 J and 1.352 × 10-18 J.What is the length of the box? (h = 6.626 × 10-34 J • s,mel = 9.11 × 10-31 kg)

A) 1.9 nm
B) 0.93 nm
C) 1.1 nm
D) 2.3 nm
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36
An electron is trapped in an infinite square well (a box)of width <strong>An electron is trapped in an infinite square well (a box)of width Find the wavelength of photons emitted when the electron drops from the n = 5 state to the in this system.(c = 3.00 × 10<sup>8</sup> m/s,h = 6.626 × 10<sup>-34</sup>J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg)</strong> A) 6.49 μm B) 5.45 μm C) 5.91 μm D) 7.07 μm Find the wavelength of photons emitted when the electron drops from the n = 5 state to the <strong>An electron is trapped in an infinite square well (a box)of width Find the wavelength of photons emitted when the electron drops from the n = 5 state to the in this system.(c = 3.00 × 10<sup>8</sup> m/s,h = 6.626 × 10<sup>-34</sup>J • s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg)</strong> A) 6.49 μm B) 5.45 μm C) 5.91 μm D) 7.07 μm in this system.(c = 3.00 × 108 m/s,h = 6.626 × 10-34J • s,mel = 9.11 × 10-31 kg)

A) 6.49 μm
B) 5.45 μm
C) 5.91 μm
D) 7.07 μm
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37
An electron is bound in an infinite well (a box)of width 0.10 nm.If the electron is initially in the n = 8 state and falls to the n = 7 state,find the wavelength of the emitted photon. An electron is bound in an infinite well (a box)of width 0.10 nm.If the electron is initially in the n = 8 state and falls to the n = 7 state,find the wavelength of the emitted photon. ,h = 6.626 × 10<sup>-34</sup> J ∙ s,m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg) ,h = 6.626 × 10-34 J ∙ s,mel = 9.11 × 10-31 kg)
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38
One fairly crude method of determining the size of a molecule is to treat the molecule as an infinite square well (a box)with an electron trapped inside,and to measure the wavelengths of emitted photons.If the photon emitted during the n = 2 to n = 1 transition has wavelength 1940 nm,what is the width of the molecule? (c = 3.00 × 108 m/s, <strong>One fairly crude method of determining the size of a molecule is to treat the molecule as an infinite square well (a box)with an electron trapped inside,and to measure the wavelengths of emitted photons.If the photon emitted during the n = 2 to n = 1 transition has wavelength 1940 nm,what is the width of the molecule? (c = 3.00 × 10<sup>8</sup> m/s, , </strong> A) 1.33 nm B) 1.12 nm C) 1.21 nm D) 1.45 nm , <strong>One fairly crude method of determining the size of a molecule is to treat the molecule as an infinite square well (a box)with an electron trapped inside,and to measure the wavelengths of emitted photons.If the photon emitted during the n = 2 to n = 1 transition has wavelength 1940 nm,what is the width of the molecule? (c = 3.00 × 10<sup>8</sup> m/s, , </strong> A) 1.33 nm B) 1.12 nm C) 1.21 nm D) 1.45 nm

A) 1.33 nm
B) 1.12 nm
C) 1.21 nm
D) 1.45 nm
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39
An electron with kinetic energy 2.80 eV encounters a potential barrier of height 4.70 eV.If the barrier width is 0.40 nm,what is the probability that the electron will tunnel through the barrier? (1 eV = 1.60 × 10-19 J,mel = 9.11 × 10-31 kg,h = 6.626 × 10-34 J • s)

A) 1.4 × 10-2
B) 2.8 × 10-2
C) 5.5 × 10-2
D) 1.1 × 10-2
E) 1.4 × 10-1
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40
You want to confine an electron in a box (an infinite well)so that its ground state energy is 5.0 × 10-18 J.What should be the length of the box? (h = 6.626 × 10-34 J • s, <strong>You want to confine an electron in a box (an infinite well)so that its ground state energy is 5.0 × 10<sup>-18</sup> J.What should be the length of the box? (h = 6.626 × 10<sup>-34</sup> J • s, </strong> A) 0.11 nm B) 0.22 nm C) 0.15 nm D) 0.18 nm

A) 0.11 nm
B) 0.22 nm
C) 0.15 nm
D) 0.18 nm
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41
A one-dimensional finite potential well has potential energy U0 = 0 in the region 0 < x < .2 nm,and <strong>A one-dimensional finite potential well has potential energy U<sub>0 </sub>= 0 in the region 0 < x < .2 nm,and everywhere else.A particle with which of the energies listed below would be localized (trapped)within the potential well? (Select all correct answers.)</strong> A) 5 eV B) 20 eV C) 16 eV D) 7 eV E) None of the above everywhere else.A particle with which of the energies listed below would be localized (trapped)within the potential well? (Select all correct answers.)

A) 5 eV
B) 20 eV
C) 16 eV
D) 7 eV
E) None of the above
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42
An electron is confined in a harmonic oscillator potential well.A photon is emitted when the electron undergoes a 3→1 quantum jump.What is the wavelength of the emission if the net force on the electron behaves as though it has a spring constant of <strong>An electron is confined in a harmonic oscillator potential well.A photon is emitted when the electron undergoes a 3→1 quantum jump.What is the wavelength of the emission if the net force on the electron behaves as though it has a spring constant of , c = 3.00 × 10<sup>8</sup> m/s,1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 290 nm B) 150 nm C) 190 nm D) 580 nm <strong>An electron is confined in a harmonic oscillator potential well.A photon is emitted when the electron undergoes a 3→1 quantum jump.What is the wavelength of the emission if the net force on the electron behaves as though it has a spring constant of , c = 3.00 × 10<sup>8</sup> m/s,1 eV = 1.60 × 10<sup>-19</sup> J,h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 290 nm B) 150 nm C) 190 nm D) 580 nm , c = 3.00 × 108 m/s,1 eV = 1.60 × 10-19 J,h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 290 nm
B) 150 nm
C) 190 nm
D) 580 nm
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43
An electron is confined in a harmonic oscillator potential well.What is the longest wavelength of light that the electron can absorb if the net force on the electron behaves as though it has a spring constant of 74 N/m? (mel = 9.11 × 10-31 kg,c = 3.00 × 108 m/s, <strong>An electron is confined in a harmonic oscillator potential well.What is the longest wavelength of light that the electron can absorb if the net force on the electron behaves as though it has a spring constant of 74 N/m? (m<sub>el</sub> = 9.11 × 10<sup>-31</sup> kg,c = 3.00 × 10<sup>8</sup> m/s, h = 1.055 × 10<sup>-34</sup> J • s,h = 6.626 × 10<sup>-34</sup> J • s)</strong> A) 210 nm B) 200 nm C) 220 nm D) 230 nm h = 1.055 × 10-34 J • s,h = 6.626 × 10-34 J • s)

A) 210 nm
B) 200 nm
C) 220 nm
D) 230 nm
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