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Lecture I: The Time-dependent Schrodinger Equation

Lecture I: The Time-dependent Schrodinger Equation. A. Mathematical and Physical Introduction B. Four methods of solution 1. Separation of variables 2. Parametrized functional form 3. Method of characteristics 4. Numerical methods. H is a Hermitian operator

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Lecture I: The Time-dependent Schrodinger Equation

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  1. Lecture I: The Time-dependent Schrodinger Equation • A. Mathematical and Physical Introduction • B. Four methods of solution • 1. Separation of variables • 2. Parametrized functional form • 3. Method of characteristics • 4. Numerical methods

  2. H is a Hermitian operator is a complex wavefunction Normalization has physical interpretation as a probability density A is an anti-Hermitian operator on a complex Hilbert space Inner product on a complex Hilbert space Physics Perspective: Time-dependent Schrodinger eq. Math Perspective: Complex wave equation

  3. Integral representation for Y Proof of norm conservation Physics Perspective: Time-dependent Schrodinger eq. Math Perspective: Complex wave equation

  4. Solution of the time-dependent Schrodinger equationMethod 1: Separation of variables • Ansatz: • Time-independent Schrodinger eq has solutions that satisfy boundary conditions in general only for particular values of

  5. Solutions of the time-independent Schrodinger equation harmonic oscillator (discrete) particle in a box (discrete) IV Eckart barrier (degenerate continous ) Morse oscillator (discrete +continuous)

  6. Reconstituting the wavefunction Y(x,t)

  7. Example: Particle in half a box

  8. Solution of the time-dependent Schrodinger equationMethod 2: Parametrized functional form • For the ansatz: leads to the diff eqs for the parameters:

  9. Solution of the time-dependent Schrodinger equationMethod 2: Parametrized functional form • For the ansatz: leads to the diff eqs for the parameters: (Ricatti equattion) Hamilton’s equations (classical mechanics) Classical Lagrangian

  10. Squeezed state Coherent state Anti-squeezed state

  11. Ehrenfest’s theorem and wavepacket revivals • Ehrenfest’s theorem • Wavepacket revivals On intermediate time scales for anharmonic potentials Ehrenfest’s theorem quite generally breaks down. However, on still longer time scales there is, in many cases of interest, an almost complete revival of the wavepacket and a second Ehrenfest epoch. In between these full revivals are an infinite number of fractional revivals that collectively have an interesting mathematical structure.

  12. Ehrenfest’s theorem and wavepacket revivals • Ehrenfest’s theorem • Wavepacket revivals

  13. Wigner phase space representation

  14. Wigner phase space representation Harmonic oscillator Coherent state Squeezed state Anti-squeezed state

  15. Wigner phase space representation Particle in half a box

  16. continuity equation quantum HJ equation Solution of the time-dependent Schrodinger equationMethod 3: Method of characteristics • Ansatz: LHS is the classical HJ equation: phase  actionRHSis thequantum potential: contains all quantum non-locality

  17. From the quantum HJ equation to quantum trajectories total derivative=“go with the flow” Classical HJ equation Classical trajectories Quantum HJ equation Quantum trajectories Quantumforce-- nonlocal

  18. Reconciling Bohm and Ehrenfest Complex S ! Complex quantum Hamilton-Jacobi equation ! Complex quantum potential • The LHS is the classical Hamilton-Jacobi equation for complex S, therefore complex x and p (complex trajectories). • The RHS is the quantum potential which is now complex.

  19. Reconciling Bohm and Ehrenfest Complex S ! Complex quantum Hamilton-Jacobi equation ! Complex quantum potential • For Gaussian wavepackets in potentials up to quadratic, the quantum force vanishes!

  20. Solution of the time-dependent Schrodinger equationMethod 4: Numerical methods Digression on the momentum representation and Dirac notation

  21. Solution of the time-dependent Schrodinger equationMethod 4: Numerical methods Digression on the momentum representation and Dirac notation

  22. Solution of the time-dependent Schrodinger equationMethod 4: Numerical methods

  23. Increase accuracy by subdividing time interval:

  24. t ti+1 ti 0 x’ x From the the split operator to classical mechanics: Feynman path integration evolution operator or propagator

  25. ti+1 ti From the the split operator to classical mechanics: Feynman path integration evolution operator or propagator t 0 x’ x

  26. From the the split operator to classical mechanics: Feynman path integration

  27. Lecture II: Concepts for Chemical Simulations • A. Wavepacket time-correlation functions • 1. Bound potentials Spectroscopy • 2. Unbound potentials Chemical reactions • B. Eigenstates as superpositions of wavepackets • C. Manipulating wavepacket motion • 1. Franck-Condon principle • 2. Control of photochemical reactions

  28. A.Wavepacket correlation functions for bound potentials

  29. A.Wavepacket correlation functions for bound potentials Particle in half a box

  30. A. Wavepacket correlation functions for bound potentials Harmonic oscillator

  31. t2 t1 t3 A. Wavepacket correlation functions for bound potentials

  32. A. Wavepacket correlation functions for unbound potentials Eckart barrier Correlation function and spectrum of incident wavepacket

  33. Correlation function and spectrum of reflected and transmitted wavepackets

  34. Normalizing the spectrum to obtain reflection and transmission coefficients

  35. B. Eigenfunctions as superpositions of wavepackets eigenfunction wavepacket superposition

  36. B. Eigenfunctions as superpositions of wavepackets eigenfunction wavepacket superposition

  37. B. Eigenfunctions as superpositions of wavepackets eigenfunction wavepacket superposition n=7 E=7.5 2<n<3 E=3.0 n=1 E=1.5

  38. B. Eigenfunctions as superpositions of wavepackets superposition eigenfunction wavepacket

  39. C. Manipulating Wavepacket Motion • Franck-Condon principle

  40. C. Manipulating Wavepacket Motion • Franck-Condon principle

  41. C. Manipulating Wavepacket Motion • Franck-Condon principle—a second time

  42. C. Manipulating Wavepacket Motion • 1. Franck-Condon principle photodissociation

  43. ring opening dissociation H isomerization H H H C C O C H H H C C C C H H O C. Manipulating Wavepacket Motion • Control of photochemical reactions Laser selective chemistry: Is it possible?

  44. Wavepacket Dancing: Chemical Selectivity by Shaping Light Pulses (Tannor, Kosloff and Rice, 1985, 1986) Review of Tannor-Rice scheme Calculus of Variations Approach Iterative Approach and Learning Algorithms

  45. Tannor, Kosloff and Rice (1986)

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