Relativity Problem Set 9 - Solutions

Similar documents
Lecture 5. Potentials

PHYS 3313 Section 001 Lecture # 22

CHAPTER 6 Quantum Mechanics II

CHAPTER 6 Quantum Mechanics II

CHAPTER 6 Quantum Mechanics II


Opinions on quantum mechanics. CHAPTER 6 Quantum Mechanics II. 6.1: The Schrödinger Wave Equation. Normalization and Probability

Chemistry 432 Problem Set 4 Spring 2018 Solutions

Quantum Mechanical Tunneling

Columbia University Department of Physics QUALIFYING EXAMINATION

Quantum Mechanical Tunneling

One-dimensional potentials: potential step

Physics 505 Homework No. 4 Solutions S4-1

PHYSICS DEPARTMENT, PRINCETON UNIVERSITY PHYSICS 505 MIDTERM EXAMINATION. October 25, 2012, 11:00am 12:20pm, Jadwin Hall A06 SOLUTIONS

Applied Nuclear Physics Homework #2

CHAPTER 36. 1* True or false: Boundary conditions on the wave function lead to energy quantization. True

if trap wave like violin string tied down at end standing wave

Løsningsforslag Eksamen 18. desember 2003 TFY4250 Atom- og molekylfysikk og FY2045 Innføring i kvantemekanikk

MATH325 - QUANTUM MECHANICS - SOLUTION SHEET 11

Physics 443, Solutions to PS 4

Model Problems 09 - Ch.14 - Engel/ Particle in box - all texts. Consider E-M wave 1st wave: E 0 e i(kx ωt) = E 0 [cos (kx - ωt) i sin (kx - ωt)]

PHYS 3313 Section 001 Lecture #20

Foundations of quantum mechanics

More On Carbon Monoxide

Quantum Physics III (8.06) Spring 2007 FINAL EXAMINATION Monday May 21, 9:00 am You have 3 hours.

Notes on Quantum Mechanics

PHYS 771, Quantum Mechanics, Final Exam, Fall 2011 Instructor: Dr. A. G. Petukhov. Solutions

QUANTUM MECHANICS A (SPA 5319) The Finite Square Well

Explanations of animations

Physics 505 Homework No. 3 Solutions S3-1

Lecture 5: Harmonic oscillator, Morse Oscillator, 1D Rigid Rotor

PHY4905: Intro to Solid State Physics. Tight-binding Model

Probability and Normalization

6. Qualitative Solutions of the TISE

Quantum Mechanics: Vibration and Rotation of Molecules

Section 4: Harmonic Oscillator and Free Particles Solutions

The Sommerfeld Polynomial Method: Harmonic Oscillator Example

Tunneling via a barrier faster than light

The Quantum Harmonic Oscillator

1 Imaginary Time Path Integral

Lecture 3. Lecturer: Prof. Sergei Fedotov Calculus and Vectors. Exponential and logarithmic functions

CHAPTER 8 The Quantum Theory of Motion

Columbia University Department of Physics QUALIFYING EXAMINATION

QM I Exercise Sheet 2

3.23 Electrical, Optical, and Magnetic Properties of Materials

* = 2 = Probability distribution function. probability of finding a particle near a given point x,y,z at a time t

Quantum Field Theory III

Scattering in One Dimension

Physics 342 Lecture 17. Midterm I Recap. Lecture 17. Physics 342 Quantum Mechanics I

Analogous comments can be made for the regions where E < V, wherein the solution to the Schrödinger equation for constant V is

Physics 137A Quantum Mechanics Fall 2012 Midterm II - Solutions

Chemistry 532 Problem Set 7 Spring 2012 Solutions

Chapter 3 Differentiation Rules (continued)

2m dx 2. The particle in a one dimensional box (of size L) energy levels are

Basics Quantum Mechanics Prof. Ajoy Ghatak Department of physics Indian Institute of Technology, Delhi

Physics 43 Chapter 41 Homework #11 Key

It illustrates quantum mechanical principals. It illustrates the use of differential eqns. & boundary conditions to solve for ψ

Summary of Last Time Barrier Potential/Tunneling Case I: E<V 0 Describes alpha-decay (Details are in the lecture note; go over it yourself!!) Case II:

STEP Support Programme. Pure STEP 3 Solutions

BASICS OF QUANTUM MECHANICS. Reading: QM Course packet Ch 5

The Position Representation in Quantum Mechanics

PHY 396 K. Problem set #5. Due October 9, 2008.

7.3 Hyperbolic Functions Hyperbolic functions are similar to trigonometric functions, and have the following

Module 40: Tunneling Lecture 40: Step potentials

Collection of formulae Quantum mechanics. Basic Formulas Division of Material Science Hans Weber. Operators

REFLECTION AND REFRACTION OF PLANE EM WAVES

Physics 215b: Problem Set 5

PHYS 3220 PhET Quantum Tunneling Tutorial

Physics 215 Quantum Mechanics 1 Assignment 5

Quantum Mechanics II

Quantum Physics Lecture 8

There is light at the end of the tunnel. -- proverb. The light at the end of the tunnel is just the light of an oncoming train. --R.

Understand the basic principles of spectroscopy using selection rules and the energy levels. Derive Hund s Rule from the symmetrization postulate.

9 Instantons in Quantum Mechanics

Contents. 1 Solutions to Chapter 1 Exercises 3. 2 Solutions to Chapter 2 Exercises Solutions to Chapter 3 Exercises 57

Advanced Quantum Mechanics, Notes based on online course given by Leonard Susskind - Lecture 8

Model for vibrational motion of a diatomic molecule. To solve the Schrödinger Eq. for molecules, make the Born- Oppenheimer Approximation:

Introduction to Quantum Mechanics (Prelude to Nuclear Shell Model) Heisenberg Uncertainty Principle In the microscopic world,

SOLUTIONS. PROBLEM 1. The Hamiltonian of the particle in the gravitational field can be written as, x 0, + U(x), U(x) =

Math F15 Rahman

Atkins & de Paula: Atkins Physical Chemistry 9e Checklist of key ideas. Chapter 8: Quantum Theory: Techniques and Applications

1. The infinite square well

Massachusetts Institute of Technology Physics Department

5.1 Classical Harmonic Oscillator

Quantum Theory. Thornton and Rex, Ch. 6

8.04: Quantum Mechanics Professor Allan Adams. Problem Set 7. Due Tuesday April 9 at 11.00AM

Quantum Theory. Thornton and Rex, Ch. 6

Lecture #8: Quantum Mechanical Harmonic Oscillator

Total Internal Reflection & Metal Mirrors

Schrödinger equation for the nuclear potential

Throughout this module we use x to denote the positive square root of x; for example, 4 = 2.

Band Structure and matrix Methods

Physics 217 Problem Set 1 Due: Friday, Aug 29th, 2008

Appendix A. The Particle in a Box: A Demonstration of Quantum Mechanical Principles for a Simple, One-Dimensional, One-Electron Model System

If electrons moved in simple orbits, p and x could be determined, but this violates the Heisenberg Uncertainty Principle.

The Postulates of (Non-Relativistic) Quantum Mechanics (The Rules of the Game)

Physics 228 Today: Ch 41: 1-3: 3D quantum mechanics, hydrogen atom

arxiv:quant-ph/ v1 1 Jul 2003

Columbia University Department of Physics QUALIFYING EXAMINATION

Exam in TFY4205 Quantum Mechanics Saturday June 10, :00 13:00

Transcription:

Relativity Problem Set 9 - Solutions Prof. J. Gerton October 3, 011 Problem 1 (10 pts.) The quantum harmonic oscillator (a) The Schroedinger equation for the ground state of the 1D QHO is ) ( m x + mω x ψ(x) = E 0 ψ(x). (1) Evaluating the kinetic operator gives m ψ(x) = x m B (1 B x ) ψ(x), () If we want the Schroedinger equation to be satisfied it must be ( B m + m ) ( ) ω x B + m E 0 = 0. (3) This is a polynomial equation, in which each coefficient of the polynomial in the variable x must equate zero. The coefficient of x gives The other equation then gives which is the correct form for the ground state energy. (b) We impose the normalization condition B = mω. (4) E 0 = 1 ω, (5) + dx ψ(x) = 1, (6) which leads to A + dx e B x = 1. (7) 1

To evaluate the integral we use the result for Gaussian integrals + dy e y = π, (8) together with the substitution y = x B that leads to or A + A = dy B e y = ( ) 1/4 B = π A B π = 1, (9) ( m ω ) 1/4. (10) π Problem (10 pts.) Expectation values for a harmonic oscillator (a) Since ψ 1 (x) is an odd function, ˆpψ 1 (x) = i x ψ 1 (x) is even. Then the integr (ψ 1 (x)) (ˆpψ 1 (x)) is a product of an even function an odd function, so it is odd. The integral is thus zero because it is the integral of an odd function over an even domain. (b) With the same reasoning, the integr (ψ 1 (x)) (ˆxψ 1 (x)) is odd in x thus its integral over the even domain specified is zero. (c) We need to compute ˆK = + ψ 1 (x) ( 3 β x ) ω ψ 1 (x) = 3 ω. (11) 4 This result is expected, because of the following fact: we know that the total energy must be E 1 = 3/ ω, that for the virial theorem applied to the harmonic field we have K = V. (1) So, E 1 = K + V = K, (13) K = 1 E 1 = 3 ω. 4 (14)

3 Problem 3 (10 pts.) The Evanescent Wave (a) The momentum in the region x > 0 is k = m(e V 0 )/ = i m E V 0 /, the last equality holding because V 0 > E. We introduce κ = m E V 0 /, so that k = iκ the wave function is with C a constant. ψ(x) = C e κx, (15) (b) The number of particles dn within the positions x x + dx is given by dn = ψ(x) dx. (16) So, in the case discussed in part (a), the probability density to find the particle at the point x > 0 is ψ(x) = e κx. (17) This probability, though small, is non-zero, so that there is a certain small probability that the particle be at some x > 0. This probability decays exponentially with x, so further away from the origin the probability drops to zero. (c) This probability is given by the reflection coefficient, R = p k p + k = p iκ p + iκ. (18) Now, computing this quantity gives R = p iκ p + iκ = p iκ p + iκ = 1. (19) p + iκ p iκ So, for any value of κ p the reflection coefficient is one. (d) The answers to (b) (c) are in contrast, because in (b) one finds that there is a transmitted current in x > 0 in (c) one finds that all of the incident particles are reflected. This ambiguity is solved by thinking of the definition for the transmitted wave, T = J transmitted J incident, (0) where J is a current. So, the expression for T is T = T 0 e κx, (1) with T 0 a constant. This expression holds for large x 1/κ is particularly good for E V 0, where T 1. So, in these cases the transmission coefficient is much smaller than R, energy conservation is not violated. However, in the region x 1/κ or for E V 0 this approximation is no longer true.

4 Problem 4 (10 pts.) The double well - Part 1 (a) Since the potential is infinite in these regions, the wave function is zero. (b) In the regions [ a, b] [a, b], the potential is V (x) = 0. Energy conservation then gives p m = E, or p = me. () In the region [ b, b] we have V (x) = V 0, with the condition V 0 > E. Indicating the momentum in this region with p, the energy conservation relation is thus p m + V 0 = E, or p m = E V 0 < 0. (3) So, in the last equation, the right h side is always negative, by assumption. This means that the momentum has to be imaginary, as suggested in the text. We write p = iκ, with κ a real quantity with the dimension of a momentum. If we do so, the kinetic energy is p m = (iκ) m = κ m. (4) The term E V 0, on the other h, can be written as E V 0 = E V 0, because we know that E V 0 < 0. Here, x indicates the absolute value of x. Finally, putting together these expressions, we find the expression for κ ss κ m = E V 0 or κ = m E V 0. (5) Compare the expression for κ with the expression for p above. (c) In classical mechanics, the particle cannot stay in the region [ b, b] because this would violate the conservation of energy constraint. In fact, since the kinetic energy has to be always positive in classical mechanics, from KE + V (x) = E KE 0 we obtain E V (x) 0. (6) The expression above yields the domain x where the particle can move in the classical picture. In our case, this domain is the union of the two regions [ a, b] [a, b], but not the region [ b, b]. In quantum mechanics instead, the wave function extends in the classically forbidden region as well, so there is a certain probability to find the particle in this region. This phenomenon is peculiar of quantum mechanics, gives rise to cute effects like the quantum tunneling, which explains the α-decay in nuclei or how the tunnel diode works, among many other things.

5 Problem 5 (10 pts.) The double well - Part (a) We begin with the region [ a, b], where the momentum is p. The wave function is then ψ 1 (x) = C 1 e ipx + C e ipx, (7) with C 1 C some normalization constants to be found. In the region [ b, b], the momentum is iκ the wave function is then ψ (x) = D 1 e i(iκ)x + D e i(iκ)x = D 1 e κx + D e κx (8) with D 1 D constants to be fixed. Finally, in the region [b, a] the momentum is p the wave function is ψ 3 (x) = C 1 e ipx + C e ipx, (9) with C 1 C some normalization constants which are different from C 1 C. Summing up, the wave function is oscillating in the classically allowed region exponentially suppressed or enhanced in the classically forbidden region. (b) Imposing the symmetry of the wave function ψ( x) = ψ(x) allows us to get rid of three of the six constants above. In the region [ b, b], which is already symmetric, we have ψ (x) = D 1 e κx + D e κx, (30) ψ ( x) = D 1 e κx + D e κx. (31) Imposing ψ ( x) = ψ (x) in this region gives D 1 = D, so that the wave function is ψ (x) = D 1 [ e κx + e κx]. (3) We can use the function cosh(x) = (e x + e x )/, so that finally ψ (x) = D 1 cosh(κx). (33) To impose the symmetrization in the other regions, we impose that the wave function ψ 1 (x) in [ a, b] being equal to the wave function ψ 3 ( x) in [b, a], that is, the wave function is symmetric in the symmetric domain [ a, b] + [b, a]. We have ψ 1 (x) = C 1 e ipx + C e ipx, in [ a, b], (34) ψ 3 ( x) = C 1 e ipx + C e ipx, in [b, a]. (35) Imposing the condition ψ 3 ( x) = ψ 1 (x) gives C 1 = C C 1 = C 1. Thus, if we decide to get rid of the constants C 1 C, the symmetrization gives the expression for the wave function in [b, a] as ψ 3 (x) = C e ipx + C 1 e ipx, (36)

6 while the wave function ψ 1 (x) in [ a, b] is unchanged. Imposing boundary conditions, we first impose that the wave function in x = a is zero. Thanks to the symmetrization, this already includes the condition that the wave function being zero at x = a. At x = a we have This gives the relation 0 = C 1 e ip( a) + C e ip( a) = C 1 e ipa + C e ipa. (37) C = C 1 e ipa. (38) We impose the continuity at x = b. This means that the expressionψ(x) = C 1 e ipx + C e ipx, valid in the region [ a, b], must be equal to the expression ψ(x) = D 1 cosh(κx), valid in the region [ b, b], when x = b. Imposing this, we have C 1 e ip( b) + C e ip( b) = D 1 cosh(κ( b)). (39) This gives the relation C 1 e ipb + C e ipb = D 1 cosh(κ( b)) = D 1 cosh(κb), (40) where in the last step we use the fact that the function cosh(x) = cosh( x), as required by the symmetry. Imposing now the continuity of the derivative, we have ψ 1 (x) x = ψ (x) x at x = b. (41) Since ψ 1 (x) = ip C 1 e ipx + ip C e ipx, x (4) ψ (x) = D 1 κ sinh(κx), x (43) the continuity of the derivative at x = b yields ip C 1 e ip( b) + ip C e ip( b) = D 1 κ sinh(κ( b)). (44) Using sinh( x) = sinh(x), we finally obtain the third relation (c) We rewrite the three conditions below: ip C 1 e ipb + ip C e ipb = D 1 sinh(κb). (45) C = C 1 e ipa continuity at x = a, (46) C 1 e ipb + C e ipb = D 1 cosh(κb) continuity at x = b, (47) ip C 1 e ipb +ip C e ipb = D 1 κ sinh(κb) continuity of the derivative at x = b. (48)

7 Plugging the first relation in the second gives C 1 e ipa [ e ipb ipa e ipb+ipa] = D 1 cosh(κb), (49) while plugging the first relation in the third gives Now, since the two relations above are ip C 1 e ipa [ e ipb ipa + e ipb+ipa] = D 1 κ sinh(κb). (50) Dividing these two relations gives or e ipb ipa + e ipb+ipa = cos p(a b), (51) e ipb ipa e ipb+ipa = i sin p(a b), (5) ic 1 e ipa sin p(a b) = D 1 cosh(κb), (53) ip C 1 e ipa cos p(a b) = D 1 κ sinh(κb). (54) C 1 e ipa sin p(a b) p C 1 e ipa cos p(a b) = D 1 cosh(κb) D 1 κ sinh(κb), (55) κ tan p(a b) = p tanh κb. (56) (d) In terms of the given quantities, this is [ ] [ ] E tan me(a b) tanh m E V0 b = E V 0. (57) This condition gives the value of the energy E, which then results quantized. The above relation is thus a quantization requirement.

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback