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Deck 41: Quantum Mechanics

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Question
The ground state energy of a harmonic oscillator is

A) <strong>The ground state energy of a harmonic oscillator is</strong> A) B) C) D)E = 0 E) <div style=padding-top: 35px>
B) <strong>The ground state energy of a harmonic oscillator is</strong> A) B) C) D)E = 0 E) <div style=padding-top: 35px>
C) <strong>The ground state energy of a harmonic oscillator is</strong> A) B) C) D)E = 0 E) <div style=padding-top: 35px>
D)E = 0
E) <strong>The ground state energy of a harmonic oscillator is</strong> A) B) C) D)E = 0 E) <div style=padding-top: 35px>
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Question
A particle is in the ground state of a one-dimensional box of length 1.0 m.What is the minimum value of its momentum (in kg ⋅ m/s)?

A)9.9 × 10−34
B)6.6 × 10−34
C)3.3 × 10−34
D)13 × 10−34
E)cannot be solved unless mass of particle is known.
Question
The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =

A) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
B) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
C) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
D) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
E) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
Question
The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be

A) <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 <div style=padding-top: 35px> ,0
B) <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 <div style=padding-top: 35px> , <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 <div style=padding-top: 35px>
C)0, <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 <div style=padding-top: 35px>
D) <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 <div style=padding-top: 35px> , <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 <div style=padding-top: 35px>
E)2/L,0
Question
The wave function for a particle in a one-dimensional box is <strong>The wave function for a particle in a one-dimensional box is )Which statement is correct?</strong> A)This wavefunction gives the probability of finding the particle at x. B)|Ψ(x)|<sup>2</sup> gives the probability of finding the particle at x. C)|Ψ(x)|<sup>2</sup> Δx gives the probability of finding the particle between x and x + Δx. D) gives the probability of finding the particle at a particular value of x. E) gives the probability of finding the particle between x and x + Δx. <div style=padding-top: 35px>
)Which statement is correct?

A)This wavefunction gives the probability of finding the particle at x.
B)|Ψ(x)|2 gives the probability of finding the particle at x.
C)|Ψ(x)|2 Δx gives the probability of finding the particle between x and x + Δx.
D) <strong>The wave function for a particle in a one-dimensional box is )Which statement is correct?</strong> A)This wavefunction gives the probability of finding the particle at x. B)|Ψ(x)|<sup>2</sup> gives the probability of finding the particle at x. C)|Ψ(x)|<sup>2</sup> Δx gives the probability of finding the particle between x and x + Δx. D) gives the probability of finding the particle at a particular value of x. E) gives the probability of finding the particle between x and x + Δx. <div style=padding-top: 35px> gives the probability of finding the particle at a particular value of x.
E) <strong>The wave function for a particle in a one-dimensional box is )Which statement is correct?</strong> A)This wavefunction gives the probability of finding the particle at x. B)|Ψ(x)|<sup>2</sup> gives the probability of finding the particle at x. C)|Ψ(x)|<sup>2</sup> Δx gives the probability of finding the particle between x and x + Δx. D) gives the probability of finding the particle at a particular value of x. E) gives the probability of finding the particle between x and x + Δx. <div style=padding-top: 35px> gives the probability of finding the particle between x and x + Δx.
Question
A particle is in the first excited state of a one-dimensional box of length 1.0 m.What is the minimum value of its momentum (in kg ⋅ m/s)?

A)3.3 × 10−34
B)6.6 × 10−34
C)9.9 × 10−34
D)13 × 10−34
E)22 × 10−34
Question
The fact that we can only calculate probabilities for values of physical quantities in quantum measurements means that

A)radiation and matter are not described by mathematical relations between measurements.
B)the probabilities cannot be calculated from mathematical relationships.
C)the results of physical measurements bear no relationship to theory.
D)the average values of a large number of measurements correspond to the calculated probabilities.
E)the average of the values calculated in a large number of different theories corresponds to the results of a measurement.
Question
A particle has a total energy that is less than that of a potential barrier.When the particle penetrates the barrier,its wave function is

A)a positive constant.
B)exponentially increasing.
C)oscillatory.
D)exponentially decreasing.
E)none of the above.
Question
Calculate the ground state energy (in eV)for an electron in a box (an infinite well)having a width of 0.050 nm.

A)10
B)75
C)24
D)150
E)54
Question
What is the quantum number n of a particle of mass m confined to a one-dimensional box of length L when its momentum is 4h/L?

A)1
B)4
C)2
D)8
E)16
Question
Classically,the concept of "tunneling" is impossible.Why?

A)The kinetic energy of the particle would be negative.
B)The velocity of the particle would be negative.
C)The total energy of a particle is equal to the kinetic and potential energies.
D)The kinetic energy must be equal to the potential energy.
E)The total energy for the particle would be negative.
Question
What is the quantum number n of a particle of mass m confined to a one-dimensional box of length L when its energy is 2 h2/mL2?

A)2
B)8
C)4
D)1
E)16
Question
When the potential energy of a system is independent of time,the wave function of the system

A)is a constant.
B)is directly proportional to the time.
C)cannot be normalized.
D)depends only on the center of mass, <strong>When the potential energy of a system is independent of time,the wave function of the system</strong> A)is a constant. B)is directly proportional to the time. C)cannot be normalized. D)depends only on the center of mass, ,of the system. E)depends on the vector positions, <sub>i</sub>,of each particle in the system. <div style=padding-top: 35px> ,of the system.
E)depends on the vector positions, <strong>When the potential energy of a system is independent of time,the wave function of the system</strong> A)is a constant. B)is directly proportional to the time. C)cannot be normalized. D)depends only on the center of mass, ,of the system. E)depends on the vector positions, <sub>i</sub>,of each particle in the system. <div style=padding-top: 35px> i,of each particle in the system.
Question
If the interaction of a particle with its environment restricts the particle to a finite region of space,the result is the quantization of ____ of the particle.

A)the momentum
B)the energy
C)the velocity
D)all of the above properties
E)only properties (a)and (b)
Question
When a particle approaching a potential step has a total energy that is greater than the potential step,what is the probability that the particle will be reflected?

A)P < 0.
B)P = 0.
C)P = 1.
D)P > 0.
E)P = ∞.
Question
Find the kinetic energy (in terms of Planck's constant)of a baseball (m = 1 kg)confined to a one-dimensional box that is 25 cm wide if the baseball can be treated as a wave in the ground state.

A)3 h2
B)2 h2
C)h2
D)4h2
E)0.5 h2
Question
A physically reasonable wave function,ψ(x),for a one-dimensional system must

A)be defined at all points in space.
B)be continuous at all points in space.
C)be single-valued.
D)obey all the constraints listed above.
E)obey only (b)and (c)above.
Question
The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =

A) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
B) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
C) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
D) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
E) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
Question
A 15-kg mass,attached to a massless spring whose force constant is 2500 N/m,has an amplitude of 4 cm.Assuming the energy is quantized,find the quantum number of the system,n,if En = nhf.

A)1.5 × 1033
B)3.0 × 1033
C)4.5 × 1033
D)5.4 × 1033
E)1.0 × 1033
Question
A particle is in the second excited state of a one-dimensional box of length 1.0 m.What is its momentum (in kg ⋅ m/s)?

A)6.6 × 10−34
B)3.3 × 10−34
C)9.9 × 10−34
D)13 × 10−34
E)cannot be solved unless mass of particle is known
Question
The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. <div style=padding-top: 35px>

A) <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. <div style=padding-top: 35px> .
B) <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. <div style=padding-top: 35px> .
C) <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. <div style=padding-top: 35px> .
D) <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. <div style=padding-top: 35px> .
E)4.
Question
The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px>

A) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
B) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
C) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
D) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
E)either <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> or <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
Question
The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value

A) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
B) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
C) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
D) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
E) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . <div style=padding-top: 35px> .
Question
The wave function for a particle in a box of length L is given by <strong>The wave function for a particle in a box of length L is given by )If the box extends from x = 0 to x = L,What is the probability of finding the particle between x = 0.60 L and x = 0.70 L?</strong> A)0.10 B)0.20 C)0.25 D)0.05 E)The probability is not given. <div style=padding-top: 35px>
)If the box extends from x = 0 to x = L,What is the probability of finding the particle between x = 0.60 L and x = 0.70 L?

A)0.10
B)0.20
C)0.25
D)0.05
E)The probability is not given.
Question
Quantum tunneling occurs in

A)nuclear fusion.
B)radioactive decay by emission of alpha particles.
C)the scanning tunneling microscope.
D)all of the above.
E)only (b)and (c)above.
Question
A particle in a finite potential well has energy E,as shown below. <strong>A particle in a finite potential well has energy E,as shown below. The wave function in region III where x > L has the form ψ<sub>III</sub> =</strong> A)Ae−Cx. B)Ae<sup>Cx</sup>. C)F sin kx. D)G cos kx. E)F sin kx + G cos kx. <div style=padding-top: 35px>
The wave function in region III where x > L has the form ψIII =

A)Ae−Cx.
B)AeCx.
C)F sin kx.
D)G cos kx.
E)F sin kx + G cos kx.
Question
When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=

A) <strong>When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=</strong> A) . B) . C)Aenπx<sup> / </sup><sup>L</sup>. D) . E) . <div style=padding-top: 35px> .
B) <strong>When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=</strong> A) . B) . C)Aenπx<sup> / </sup><sup>L</sup>. D) . E) . <div style=padding-top: 35px> .
C)Aenπx / L.
D) <strong>When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=</strong> A) . B) . C)Aenπx<sup> / </sup><sup>L</sup>. D) . E) . <div style=padding-top: 35px> .
E) <strong>When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=</strong> A) . B) . C)Aenπx<sup> / </sup><sup>L</sup>. D) . E) . <div style=padding-top: 35px> .
Question
A particle in a finite potential well has energy E,as shown below. <strong>A particle in a finite potential well has energy E,as shown below. The wave function in region II where x > 0 has the form ψ<sub>II</sub> =</strong> A)Ae−Cx. B)Ae<sup>Cx</sup>. C)F sin kx. D)G cos kx. E)F sin kx + G cos kx. <div style=padding-top: 35px>
The wave function in region II where x > 0 has the form ψII =

A)Ae−Cx.
B)AeCx.
C)F sin kx.
D)G cos kx.
E)F sin kx + G cos kx.
Question
The wave function for a particle in a box of length L is given by <strong>The wave function for a particle in a box of length L is given by )If the box extends from x = 0 to x = L,at which of the following positions is the highest probability for finding the particle?</strong> A)x = 0.33 L B)x = 0.04 L C)x = 0.60 L D)Both (a)and (b). E)Both (b)and (c). <div style=padding-top: 35px>
)If the box extends from x = 0 to x = L,at which of the following positions is the highest probability for finding the particle?

A)x = 0.33 L
B)x = 0.04 L
C)x = 0.60 L
D)Both (a)and (b).
E)Both (b)and (c).
Question
A particle in a finite potential well has energy E,as shown below. <strong>A particle in a finite potential well has energy E,as shown below. The wave function in region I where x < 0 has the form ψ<sub>I</sub> =</strong> A)Ae−Cx. B)Ae<sup>Cx</sup>. C)F sin kx. D)G cos kx. E)F sin kx + G cos kx. <div style=padding-top: 35px>
The wave function in region I where x < 0 has the form ψI =

A)Ae−Cx.
B)AeCx.
C)F sin kx.
D)G cos kx.
E)F sin kx + G cos kx.
Question
The graph below shows the value of the probability density |ψ(x)|2 in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px>

A) <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
B) <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
C) <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
D) <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
E)either <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> or <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
Question
Frank says that quantum mechanics does not apply to baseballs because they do not jump from quantum state to quantum state when being thrown.Francine agrees with him.She says that there is no uncertainty in a baseball's position or momentum.Are they correct,or not,and why?

A)They are correct because the first excited state of a baseball is at a higher energy that any baseball ever receives.Therefore we cannot determine whether or not there is uncertainty in its position or momentum.
B)They are correct because the first excited state of a baseball is at a higher energy that any baseball ever receives.Therefore its position and momentum are completely uncertain until it is caught.
C)They are wrong because the baseball goes through so many quantum states in being thrown that we cannot observe the transitions.The uncertainties in its position and momentum are too small to observe.
D)They are wrong because the baseball goes through so many quantum states in being thrown that we cannot observe the transitions.Because of the number of transitions its position and momentum are completely uncertain until it is caught.
E)Quantum mechanics states that they are correct as long as they do not make any observations,but wrong as soon as they begin to make observations.
Question
The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px>

A) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
B) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
C) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
D) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
E)either <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> or <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . <div style=padding-top: 35px> .
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Deck 41: Quantum Mechanics
1
The ground state energy of a harmonic oscillator is

A) <strong>The ground state energy of a harmonic oscillator is</strong> A) B) C) D)E = 0 E)
B) <strong>The ground state energy of a harmonic oscillator is</strong> A) B) C) D)E = 0 E)
C) <strong>The ground state energy of a harmonic oscillator is</strong> A) B) C) D)E = 0 E)
D)E = 0
E) <strong>The ground state energy of a harmonic oscillator is</strong> A) B) C) D)E = 0 E)
2
A particle is in the ground state of a one-dimensional box of length 1.0 m.What is the minimum value of its momentum (in kg ⋅ m/s)?

A)9.9 × 10−34
B)6.6 × 10−34
C)3.3 × 10−34
D)13 × 10−34
E)cannot be solved unless mass of particle is known.
3.3 × 10−34
3
The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =

A) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . .
B) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . .
C) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . .
D) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . .
E) <strong>The expectations value of a function f(x)of x when the wave function depends only on x is given by < f(x)> =</strong> A) . B) . C) . D) . E) . .
. .
4
The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be

A) <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 ,0
B) <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 , <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0
C)0, <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0
D) <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0 , <strong>The wave function for a particle confined to a one-dimensional box located between x = 0 and x = L is given by Ψ(x)= A sin (nπx/L)+ B cos (nπx/L).The constants A and B are determined to be</strong> A) ,0 B) , C)0, D) , E)2/L,0
E)2/L,0
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5
The wave function for a particle in a one-dimensional box is <strong>The wave function for a particle in a one-dimensional box is )Which statement is correct?</strong> A)This wavefunction gives the probability of finding the particle at x. B)|Ψ(x)|<sup>2</sup> gives the probability of finding the particle at x. C)|Ψ(x)|<sup>2</sup> Δx gives the probability of finding the particle between x and x + Δx. D) gives the probability of finding the particle at a particular value of x. E) gives the probability of finding the particle between x and x + Δx.
)Which statement is correct?

A)This wavefunction gives the probability of finding the particle at x.
B)|Ψ(x)|2 gives the probability of finding the particle at x.
C)|Ψ(x)|2 Δx gives the probability of finding the particle between x and x + Δx.
D) <strong>The wave function for a particle in a one-dimensional box is )Which statement is correct?</strong> A)This wavefunction gives the probability of finding the particle at x. B)|Ψ(x)|<sup>2</sup> gives the probability of finding the particle at x. C)|Ψ(x)|<sup>2</sup> Δx gives the probability of finding the particle between x and x + Δx. D) gives the probability of finding the particle at a particular value of x. E) gives the probability of finding the particle between x and x + Δx. gives the probability of finding the particle at a particular value of x.
E) <strong>The wave function for a particle in a one-dimensional box is )Which statement is correct?</strong> A)This wavefunction gives the probability of finding the particle at x. B)|Ψ(x)|<sup>2</sup> gives the probability of finding the particle at x. C)|Ψ(x)|<sup>2</sup> Δx gives the probability of finding the particle between x and x + Δx. D) gives the probability of finding the particle at a particular value of x. E) gives the probability of finding the particle between x and x + Δx. gives the probability of finding the particle between x and x + Δx.
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6
A particle is in the first excited state of a one-dimensional box of length 1.0 m.What is the minimum value of its momentum (in kg ⋅ m/s)?

A)3.3 × 10−34
B)6.6 × 10−34
C)9.9 × 10−34
D)13 × 10−34
E)22 × 10−34
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7
The fact that we can only calculate probabilities for values of physical quantities in quantum measurements means that

A)radiation and matter are not described by mathematical relations between measurements.
B)the probabilities cannot be calculated from mathematical relationships.
C)the results of physical measurements bear no relationship to theory.
D)the average values of a large number of measurements correspond to the calculated probabilities.
E)the average of the values calculated in a large number of different theories corresponds to the results of a measurement.
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8
A particle has a total energy that is less than that of a potential barrier.When the particle penetrates the barrier,its wave function is

A)a positive constant.
B)exponentially increasing.
C)oscillatory.
D)exponentially decreasing.
E)none of the above.
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9
Calculate the ground state energy (in eV)for an electron in a box (an infinite well)having a width of 0.050 nm.

A)10
B)75
C)24
D)150
E)54
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10
What is the quantum number n of a particle of mass m confined to a one-dimensional box of length L when its momentum is 4h/L?

A)1
B)4
C)2
D)8
E)16
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11
Classically,the concept of "tunneling" is impossible.Why?

A)The kinetic energy of the particle would be negative.
B)The velocity of the particle would be negative.
C)The total energy of a particle is equal to the kinetic and potential energies.
D)The kinetic energy must be equal to the potential energy.
E)The total energy for the particle would be negative.
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12
What is the quantum number n of a particle of mass m confined to a one-dimensional box of length L when its energy is 2 h2/mL2?

A)2
B)8
C)4
D)1
E)16
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13
When the potential energy of a system is independent of time,the wave function of the system

A)is a constant.
B)is directly proportional to the time.
C)cannot be normalized.
D)depends only on the center of mass, <strong>When the potential energy of a system is independent of time,the wave function of the system</strong> A)is a constant. B)is directly proportional to the time. C)cannot be normalized. D)depends only on the center of mass, ,of the system. E)depends on the vector positions, <sub>i</sub>,of each particle in the system. ,of the system.
E)depends on the vector positions, <strong>When the potential energy of a system is independent of time,the wave function of the system</strong> A)is a constant. B)is directly proportional to the time. C)cannot be normalized. D)depends only on the center of mass, ,of the system. E)depends on the vector positions, <sub>i</sub>,of each particle in the system. i,of each particle in the system.
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14
If the interaction of a particle with its environment restricts the particle to a finite region of space,the result is the quantization of ____ of the particle.

A)the momentum
B)the energy
C)the velocity
D)all of the above properties
E)only properties (a)and (b)
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15
When a particle approaching a potential step has a total energy that is greater than the potential step,what is the probability that the particle will be reflected?

A)P < 0.
B)P = 0.
C)P = 1.
D)P > 0.
E)P = ∞.
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16
Find the kinetic energy (in terms of Planck's constant)of a baseball (m = 1 kg)confined to a one-dimensional box that is 25 cm wide if the baseball can be treated as a wave in the ground state.

A)3 h2
B)2 h2
C)h2
D)4h2
E)0.5 h2
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17
A physically reasonable wave function,ψ(x),for a one-dimensional system must

A)be defined at all points in space.
B)be continuous at all points in space.
C)be single-valued.
D)obey all the constraints listed above.
E)obey only (b)and (c)above.
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18
The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =

A) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . .
B) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . .
C) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . .
D) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . .
E) <strong>The average position,or expectation value,of a particle whose wave function ψ(x)depends only on the value of x,is given by < x > =</strong> A) . B) . C) . D) . E) . .
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19
A 15-kg mass,attached to a massless spring whose force constant is 2500 N/m,has an amplitude of 4 cm.Assuming the energy is quantized,find the quantum number of the system,n,if En = nhf.

A)1.5 × 1033
B)3.0 × 1033
C)4.5 × 1033
D)5.4 × 1033
E)1.0 × 1033
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20
A particle is in the second excited state of a one-dimensional box of length 1.0 m.What is its momentum (in kg ⋅ m/s)?

A)6.6 × 10−34
B)3.3 × 10−34
C)9.9 × 10−34
D)13 × 10−34
E)cannot be solved unless mass of particle is known
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21
The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4.

A) <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. .
B) <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. .
C) <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. .
D) <strong>The graph below represents a wave function ψ(x)for a particle confined to −4.00 m ≤ x ≤ +4.00 m.The magnitude of the normalization constant A is </strong> A) . B) . C) . D) . E)4. .
E)4.
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22
The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or .

A) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
B) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
C) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
D) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
E)either <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . or <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
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23
The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value

A) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . .
B) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . .
C) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . .
D) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . .
E) <strong>The wave function ψ(x)of a particle confined to 0 ≤ x ≤ L is given by ψ(x)= Ax.ψ(x)= 0 for x < 0 and x > L.When the wave function is normalized,the probability density at coordinate x has the value</strong> A) . B) . C) . D) . E) . .
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24
The wave function for a particle in a box of length L is given by <strong>The wave function for a particle in a box of length L is given by )If the box extends from x = 0 to x = L,What is the probability of finding the particle between x = 0.60 L and x = 0.70 L?</strong> A)0.10 B)0.20 C)0.25 D)0.05 E)The probability is not given.
)If the box extends from x = 0 to x = L,What is the probability of finding the particle between x = 0.60 L and x = 0.70 L?

A)0.10
B)0.20
C)0.25
D)0.05
E)The probability is not given.
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25
Quantum tunneling occurs in

A)nuclear fusion.
B)radioactive decay by emission of alpha particles.
C)the scanning tunneling microscope.
D)all of the above.
E)only (b)and (c)above.
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26
A particle in a finite potential well has energy E,as shown below. <strong>A particle in a finite potential well has energy E,as shown below. The wave function in region III where x > L has the form ψ<sub>III</sub> =</strong> A)Ae−Cx. B)Ae<sup>Cx</sup>. C)F sin kx. D)G cos kx. E)F sin kx + G cos kx.
The wave function in region III where x > L has the form ψIII =

A)Ae−Cx.
B)AeCx.
C)F sin kx.
D)G cos kx.
E)F sin kx + G cos kx.
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27
When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=

A) <strong>When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=</strong> A) . B) . C)Aenπx<sup> / </sup><sup>L</sup>. D) . E) . .
B) <strong>When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=</strong> A) . B) . C)Aenπx<sup> / </sup><sup>L</sup>. D) . E) . .
C)Aenπx / L.
D) <strong>When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=</strong> A) . B) . C)Aenπx<sup> / </sup><sup>L</sup>. D) . E) . .
E) <strong>When U(x)is infinitely large elsewhere,the wave function of a particle restricted to the region 0 < x < L where U(x)= 0,may have the form ψ(x)=</strong> A) . B) . C)Aenπx<sup> / </sup><sup>L</sup>. D) . E) . .
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28
A particle in a finite potential well has energy E,as shown below. <strong>A particle in a finite potential well has energy E,as shown below. The wave function in region II where x > 0 has the form ψ<sub>II</sub> =</strong> A)Ae−Cx. B)Ae<sup>Cx</sup>. C)F sin kx. D)G cos kx. E)F sin kx + G cos kx.
The wave function in region II where x > 0 has the form ψII =

A)Ae−Cx.
B)AeCx.
C)F sin kx.
D)G cos kx.
E)F sin kx + G cos kx.
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29
The wave function for a particle in a box of length L is given by <strong>The wave function for a particle in a box of length L is given by )If the box extends from x = 0 to x = L,at which of the following positions is the highest probability for finding the particle?</strong> A)x = 0.33 L B)x = 0.04 L C)x = 0.60 L D)Both (a)and (b). E)Both (b)and (c).
)If the box extends from x = 0 to x = L,at which of the following positions is the highest probability for finding the particle?

A)x = 0.33 L
B)x = 0.04 L
C)x = 0.60 L
D)Both (a)and (b).
E)Both (b)and (c).
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30
A particle in a finite potential well has energy E,as shown below. <strong>A particle in a finite potential well has energy E,as shown below. The wave function in region I where x < 0 has the form ψ<sub>I</sub> =</strong> A)Ae−Cx. B)Ae<sup>Cx</sup>. C)F sin kx. D)G cos kx. E)F sin kx + G cos kx.
The wave function in region I where x < 0 has the form ψI =

A)Ae−Cx.
B)AeCx.
C)F sin kx.
D)G cos kx.
E)F sin kx + G cos kx.
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31
The graph below shows the value of the probability density |ψ(x)|2 in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or .

A) <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . .
B) <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . .
C) <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . .
D) <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . .
E)either <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . or <strong>The graph below shows the value of the probability density |ψ(x)|<sup>2</sup> in the region −3.00 m ≤ x ≤ +3.00 m.The value of the constant A is </strong> A) . B) . C) . D) . E)either or . .
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32
Frank says that quantum mechanics does not apply to baseballs because they do not jump from quantum state to quantum state when being thrown.Francine agrees with him.She says that there is no uncertainty in a baseball's position or momentum.Are they correct,or not,and why?

A)They are correct because the first excited state of a baseball is at a higher energy that any baseball ever receives.Therefore we cannot determine whether or not there is uncertainty in its position or momentum.
B)They are correct because the first excited state of a baseball is at a higher energy that any baseball ever receives.Therefore its position and momentum are completely uncertain until it is caught.
C)They are wrong because the baseball goes through so many quantum states in being thrown that we cannot observe the transitions.The uncertainties in its position and momentum are too small to observe.
D)They are wrong because the baseball goes through so many quantum states in being thrown that we cannot observe the transitions.Because of the number of transitions its position and momentum are completely uncertain until it is caught.
E)Quantum mechanics states that they are correct as long as they do not make any observations,but wrong as soon as they begin to make observations.
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33
The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or .

A) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
B) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
C) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
D) <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
E)either <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . or <strong>The graph below represents a wave function ψ(x)for a particle confined to −2.00 m ≤ x ≤ +2.00 m.The value of the normalization constant A may be </strong> A) . B) . C) . D) . E)either or . .
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