1. Chapter 40

2. Three de Broglie waves are shown for particles of equal mass
Three de Broglie waves are shown for particles of equal mass. Rank in order, from largest to smallest, the speeds of particles a, b, and c.
1. va = vb > vc
2. vb > va > vc
3. vb > va = vc
4. vc > va > vb
5. vc > va = vb
STT40.1

3. Three de Broglie waves are shown for particles of equal mass
Three de Broglie waves are shown for particles of equal mass. Rank in order, from largest to smallest, the speeds of particles a, b, and c.
1. va = vb > vc
2. vb > va > vc
3. vb > va = vc
4. vc > va > vb
5. vc > va = vb
STT40.1

4. 1. One-quarter of the way from either end.
A particle in a rigid box in the n = 2 stationary state is most likely to be found
1. One-quarter of the way from either end.
2. One-third of the way from either end.
3. In the center of the box.
4. It is equally likely to be found at any point in the box.
STT40.2

5. 1. One-quarter of the way from either end.
A particle in a rigid box in the n = 2 stationary state is most likely to be found
1. One-quarter of the way from either end.
2. One-third of the way from either end.
3. In the center of the box.
4. It is equally likely to be found at any point in the box.
STT40.2

6. This is a wave function for a particle in a finite quantum well
This is a wave function for a particle in a finite quantum well. What is the particle’s quantum number?
1. n = 1
2. n = 2
3. n = 3
4. n = 4
5. n = 5
STT40.3

7. This is a wave function for a particle in a finite quantum well
This is a wave function for a particle in a finite quantum well. What is the particle’s quantum number?
1. n = 1
2. n = 2
3. n = 3
4. n = 4
5. n = 5
STT40.3

8. For which potential energy is this an appropriate n = 4 wave function?
STT40.4
(1) (2) (3) (4)

9. For which potential energy is this an appropriate n = 4 wave function?
STT40.4
(1) (2) (3)
(4)

10. Which probability density represents a quantum harmonic oscillator with
STT40.5

11. Which probability density represents a quantum harmonic oscillator with
STT40.5

12. A particle with energy E approaches an energy barrier with height U0 > E. If U0 is slowly decreased, the probability that the particle reflects from the barrier
1. Decreases.
2. Increases.
3. Does not change.
STT40.6

13. A particle with energy E approaches an energy barrier with height U0 > E. If U0 is slowly decreased, the probability that the particle reflects from the barrier
1. Decreases.
2. Increases.
3. Does not change.
STT40.6

14. Chapter 40
Reading Quiz

15. A quantum particle can pass through a region of space that would be forbidden to a classical particle. What is the name of this process?
1. Teleportation
2. Vacuum decay
3. Lasing
4. Trapping
5. Tunneling
IG40.2

16. A quantum particle can pass through a region of space that would be forbidden to a classical particle. What is the name of this process?
1. Teleportation
2. Vacuum decay
3. Lasing
4. Trapping
5. Tunneling
IG40.2

17. A particle in the ground state of a potential energy well
1. is at rest.
2. has a zero-point motion.
3. is equally probable to be found at any point inside the well.
4. has a wave function that is zero at all points.
5. has zero energy.
IG40.3

18. A particle in the ground state of a potential energy well
1. is at rest.
2. has a zero-point motion.
3. is equally probable to be found at any point inside the well.
4. has a wave function that is zero at all points.
5. has zero energy.
IG40.3

19. Which of these was not analyzed in this chapter?
1. A particle in a capacitor
2. A particle in a finite potential well
3. A neutron in a nucleus
4. An electron in an atom
5. An electron in a quantum-well device
IG40.4

20. Which of these was not analyzed in this chapter?
1. A particle in a capacitor
2. A particle in a finite potential well
3. A neutron in a nucleus
4. An electron in an atom
5. An electron in a quantum-well device
IG40.4