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Modern Physics 6b Physical Systems, week 7, Thursday 22 Feb. 2007, EJZ Ch.6.4-5: Expectation values and operators Quantum harmonic oscillator → blackbody.

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Presentation on theme: "Modern Physics 6b Physical Systems, week 7, Thursday 22 Feb. 2007, EJZ Ch.6.4-5: Expectation values and operators Quantum harmonic oscillator → blackbody."— Presentation transcript:

1 Modern Physics 6b Physical Systems, week 7, Thursday 22 Feb. 2007, EJZ Ch.6.4-5: Expectation values and operators Quantum harmonic oscillator → blackbody applications week 8, Ch.7.1-3: Schrödinger Eqn in 3D, Hydrogen atom week 9, Ch.7.4-8: Spin and angular momentum, applications

2 Review energy and momentum operators Apply to the Schrödinger eqn: E  (x,t) = T  (x,t) + V  (x,t) Find the wavefunction for a given potential V(x)

3 Expectation values Most likely outcome of a measurement of position, for a system (or particle) in state  x,t  : Order matters for operators like momentum – differentiate  (x,t):

4 Expectation values Exercise: Consider the infinite square well of width L. (a)What is ? (b) What is ? (c)What is ? (Guess first) (d)What is ? (Guess first)

5

6 This is one of the classic potentials for which we can analytically solve Sch.Eqn., and it approximates many physical situations. Harmonic oscillator

7 Simple Harmonic oscillator (SHO) What values of total Energy are possible? What is the zero-point energy for the simple harmonic oscillator? Compare this to the finite square well.

8 Solving the Quantum Harmonic oscillator 0. QHO Preview Substitution approach: Verify that y 0 =Ae -ax^2 is a solution 2. Analytic approach: rewrite SE diffeq and solve 3. Algebraic method: ladder operators a±

9 QHO preview: What values of total energy are possible? What is the zero-point energy for the Quantum Harmonic Oscillator? Compare this to the finite square well and SHO

10 QHO: 1. Substitution: Verify solution to SE:

11

12 2. QHO analytically: solve the diffeq directly: Rewrite SE using * At large  ~x, has solutions * Guess series solution h(  ) * Consider normalization and BC to find that h n =a n H n (  ) where H n (  ) are Hermite polynomials * The ground state solution  0 is the same as before: * Higher states can be constructed with ladder operators

13 3. QHO algebraically: use a ± to get  n Ladder operators a ± generate higher-energy wave- functions from the ground state  0. Griffiths Quantum Section 2.3.1 Result:

14 Griffiths Prob.2.13 QHO Worksheet

15

16 Free particle: V=0 Looks easy, but we need Fourier series If it has a definite energy, it isn’t normalizable! No stationary states for free particles Wave function’s v g = 2 v p, consistent with classical particle:

17 Applications of Quantum mechanics Choose your Minilectures for Ch.7 Blackbody radiation: resolve ultraviolet catastrophe, measure star temperatures http://192.211.16.13/curricular/physys/0607/lectures/BB/BBKK.pdf Photoelectric effect: particle detectors and signal amplifiers Bohr atom: predict and understand H-like spectra and energies Structure and behavior of solids, including semiconductors STM (p.279),  -decay (280), NH 3 atomic clock (p.282) Zeeman effect: measure magnetic fields of stars from light Electron spin: Pauli exclusion principle Lasers, NMR, nuclear and particle physics, and much more...

18 Scanning Tunneling Microscope

19 Alpha Decay

20 Ammonia Atomic Clock

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