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PHY 102: Quantum Physics Topic 4 Introduction to Quantum Theory

PHY 102: Quantum Physics Topic 4 Introduction to Quantum Theory. Wave functions Significance of wave function Normalisation The time-independent Schrodinger Equation. Solutions of the T.I.S.E. The de Broglie Hypothesis.

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PHY 102: Quantum Physics Topic 4 Introduction to Quantum Theory

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  1. PHY 102: Quantum Physics Topic 4 Introduction to Quantum Theory

  2. Wave functions • Significance of wave function • Normalisation • The time-independent Schrodinger Equation. • Solutions of the T.I.S.E

  3. The de Broglie Hypothesis In 1924, de Broglie suggested that if waves of wavelength λ were associated with particles of momentum p=h/λ, then it should also work the other way round……. A particle of mass m, moving with velocity v has momentum p given by:

  4. Kinetic Energy of particle If the de Broglie hypothesis is correct, then a stream of classical particles should show evidence of wave-like characteristics……………………………………………

  5. V= V= V= V= V=0 V=0 Standing de Broglie waves Eg electron in a “box” (infinite potential well) Standing wave formed Electron “rattles” to and fro

  6. Wavelengths of confined states In general, k =nπ/L, n= number of antinodes in standing wave

  7. Energies of confined states

  8. Energies of confined states

  9. Particle in a box: wave functions From Lecture 4, standing wave on a string has form: Our particle in a box wave functions represent STATIONARY (time independent) states, so we write: A is a constant, to be determined……………

  10. Interpretation of the wave function The wave function of a particle is related to the probability density for finding the particle in a given region of space: Probability of finding particle between x and x + dx: Probability of finding particle somewhere = 1, so we have the NORMALISATION CONDITION for the wave function:

  11. Interpretation of the wave function

  12. Interpretation of the wave function Normalisation condition allows unknown constants in the wave function to be determined. For our particle in a box we have WF: Since, in this case the particle is confined by INFINITE potential barriers, we know particle must be located between x=0 and x=L →Normalisation condition reduces to :

  13. Particle in a box: normalisation of wave functions

  14. Some points to note………….. So far we have only treated a very simple one-dimensional case of a particle in a completely confining potential. In general, we should be able to determine wave functions for a particle in all three dimensions and for potential energies of any value Requires the development of a more sophisticated “QUANTUM MECHANICS” based on the SCHRÖDINGER EQUATION…………………

  15. The Schrödinger Equation in 1-dimension (time-independent) KE Term PE Term

  16. Solving the Schrodinger equation allows us to calculate particle wave functions for a wide range of situations (See Y2 QM course)……. Finite potential well WF “leakage”, particle has finite probability of being found in barrier: CLASSICALLY FORBIDDEN

  17. Solving the Schrodinger equation allows us to calculate particle wave functions for a wide range of situations (See Y2 QM course)……. Barrier Penetration (Tunnelling) Quantum mechanics allows particles to travel through “brick walls”!!!!

  18. Solving the SE for particle in an infinite potential well So, for 0<x<L, the time independent SE reduces to: General Solution:

  19. Boundary condition: ψ(x) = 0 when x=0:→B=0 Boundary condition: ψ(x) = 0 when x=L:

  20. In agreement with the “fitting waves in boxes” treatment earlier………………..

  21. Molecular Beam Epitaxy: Man-made potential wells for Quantum mechanical engineering

  22. Molecular Beam Epitaxy: Man-made potential wells for Quantum mechanical engineering

  23. Quantum Cascade Laser: Engineering with electron wavefunctions

  24. Scanning Tunnelling Microscope: Imaging atoms

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