Physics 3 for Electrical Engineering

Ben Gurion University of the Negev www.bgu.ac.il/atomchip,www.bgu.ac.il/nanocenter Physics 3 for Electrical Engineering Lecturers: Daniel Rohrlich, Ron Folman Teaching Assistants: Daniel Ariad, Barukh Dolgin Week 8. Quantum mechanics – raising and lowering operators, 1D harmonic oscillator • harmonic oscillator eigenvalues and eigenfunctions • matrix representation • motion of a minimum-uncertainty wave packet • 3D harmonic oscillator • classical limit Sources: Merzbacher (2nd edition) Chap. 5 Sects. 1-4; Merzbacher (3rd edition) Chap. 5 Sects. 1, 3 and Chap. 10 Sect. 6; Tipler and Llewellyn, Chap. 6 Sect. 5.

We already stated that Schrödinger’s wave equation, with its continuous solutions, and Heisenberg’s matrix algebra, with its quantum jumps, are equivalent. Let’s see and compare how these two different methods apply to the quantum harmonic oscillator.

The 1D harmonic oscillator x 0

x x x x x 0 0 0 0 0 The 1D harmonic oscillator x t1 0 t2 t3 t4 t5 t6

x x x x x 0 0 0 0 0 The 1D harmonic oscillator x t1 0 t2 F(t2) t3 F(t3) t4 F(t4) t5 t6 F(t6)

The 1D harmonic oscillator This system is a model for many systems, e.g. molecules made of two atoms. x 0

The 1D harmonic oscillator Any system with a potential minimum at some x = x0 may behave like a harmonic oscillator at low energies: V(x) = V(x0) + (x–x0)2 V′′(x0) + …. x 0 x0

The 1D harmonic oscillator Also, a mode of the electromagnetic field of frequency ν behaves like a 1D harmonic oscillator of frequency ν. Its energy levels nhν correspond to n photons of frequency ν. x 0

The 1D harmonic oscillator Schrödinger’s equation: x 0

Solving Schrödinger’s equation Schrödinger’s way: Define a new variable , where In terms of ξ , Schrödinger’s equation is Solutions: Try where H(ξ) is a polynomial. ψ is a solution when H(ξ) is one of the Hermite polynomials: H0(ξ) = 1, H1(ξ) = 2ξ, H2(ξ) = 4ξ2–2, H3(ξ) = 8ξ3–12ξ, ….

Solving Schrödinger’s equation Heisenberg’s way: Define new variables where Let’s prove that Try also to prove (for any three operators ) that

Raising and lowering operators To prove:

Suppose is an eigenstate of with eigenvalue E. Then using Therefore, is an eigenstate of with eigenvalue . We call a raising operator. Homework: Show that is a lowering operator, i.e.

Suppose is an eigenstate of with eigenvalue E. Then using Therefore, is an eigenstate of with eigenvalue . We call a raising operator. The harmonic oscillator must have a ground state – call it ψ0(x) or – with minimum energy. For we have which means and therefore

Since and , the ground-state energy is , and the energy of the state , defined by is From we learn that Thus we call the number operator. Since we can write . Likewise, since , we can write

Since and , the ground-state energy is , and the energy of the state , defined by is Normalization: So the ground state normalization is Then for all n, (Prove it!)

Harmonic oscillator eigenvalues and eigenfunctions What are the lowest eigenstates of the harmonic oscillator? Note that the eigenfunctions ψn(x) are even or odd in x. Why?

Harmonic oscillator eigenvalues and eigenfunctions This Figure is taken from here.

Harmonic oscillator eigenvalues and eigenfunctions This Figure is taken from here. If the harmonic oscillator represents a mode of the electromagnetic field, an energy level ½ represents n photons each having energy , plus additional “zero-point energy” of per mode.

Matrix representation In the basis of harmonic-oscillator eigenvectors, we can represent the operators as matrices. Since ½ if m = n and vanishes otherwise, we can represent as an infinite matrix:

Matrix representation In the basis of harmonic-oscillator eigenvectors, we can represent the operators as matrices. Since if m = n–1 and vanishes otherwise, we can represent as an infinite matrix:

Matrix representation In the basis of harmonic-oscillator eigenvectors, we can represent the operators as matrices. Since if m = n+1 and vanishes otherwise, we can represent as an infinite matrix:

The normalized harmonic-oscillator eigenvectors themselves are the basis vectors:

The transpose of a matrix is written and defined by

The adjoint of a matrix is written and defined by

The adjoint of a matrix is written and defined by Any observable is self-adjoint, i.e. “ is Hermitian” and “ is self-adjoint” mean the same thing.

The adjoint of a matrix is written and defined by Any observable is self-adjoint, i.e. “ is Hermitian” and “ is self-adjoint” mean the same thing. The raising and lowering operators and are not self-adjoint, but are adjoints of each other:

are manifestly self-adjoint:

Vectors, too, have adjoints. For any we have and, for example, Try to prove, for any two operators , the rule

Motion of a minimum-uncertainty wave packet The ground state wave function ψ0(x) is a minimum-uncertainty wave function: we can calculate In general, the time evolution of any initial wave function Ψ(x,0) can be obtained from the expansion of Ψ(x,0) in the basis of energy eigenstates. If the initial wave function is for given cn, then the wave function at time t is

Motion of a minimum-uncertainty wave packet The period of a classical harmonic oscillator having angular frequency ω is T = 2π /ω . If we add T to t in Ψ(x,t), the wave function does not change, up to an overall phase factor –1: Schrödinger even found a solution Ψ(x,0) that moves between x = R and x = –R while the probability distribution |Ψ(x,0)|2 keeps its (minimum uncertainty) shape:

Motion of a minimum-uncertainty wave packet Schrödinger thought his solution might be typical, but it is not. Usually the probability distribution spreads over time. Prove that a free 1D wave packet spreads, that if it is initially then at time t the wave packet is Show that Δp = is constant in time, but

3D harmonic oscillator The Schrödinger equation for a general 3D harmonic oscillator, allows for a harmonic potential with different strengths along the three axes. Show that the eigenfunctions are products of 1D harmonic oscillator eigenfunctions. What are the lowest energies and their degeneracies as a function of kx, ky and kz?

Classical limit A classical particle in a square well has equal probability to be at any point inside. How about a quantum particle in its ground state? a quantum particle in a highly excited state? The probability P(x) for classical harmonically oscillating particle to be at any point x is inversely proportional to its speed at that point: P(x) ~ (2E/m – ω2x2)–1/2, where E is total energy. n = 0 n = 10 .

Physics 3 for Electrical Engineering