Schrödinger Equation for Electron-Photon Interaction Archives - Time Travel, Quantum Entanglement and Quantum Computing https://stationarystates.com/tag/schrodinger-equation-for-electron-photon-interaction/ Not only is the Universe stranger than we think, it is stranger than we can think...Hiesenberg Wed, 27 Nov 2024 00:41:44 +0000 en-US hourly 1 https://wordpress.org/?v=6.6.2 Electron interacts with a photon – Schrodinger equation and it’s solution https://stationarystates.com/quantum-field-theory/electron-interacts-with-a-photon-schrodinger-equation-and-its-solution/?utm_source=rss&utm_medium=rss&utm_campaign=electron-interacts-with-a-photon-schrodinger-equation-and-its-solution https://stationarystates.com/quantum-field-theory/electron-interacts-with-a-photon-schrodinger-equation-and-its-solution/#respond Wed, 27 Nov 2024 00:41:44 +0000 https://stationarystates.com/?p=670 Schrödinger Equation for Electron-Photon Interaction The system includes: An electron with wavefunction ψe(r, t), A photon field described by the vector potential A(r, t). The total Hamiltonian includes: The electron’s […]

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Schrödinger Equation for Electron-Photon Interaction

The system includes:

  • An electron with wavefunction ψe(r, t),
  • A photon field described by the vector potential A(r, t).

The total Hamiltonian includes:

  1. The electron’s kinetic energy, -ℏ2/2me2,
  2. The coupling between the electron and photon field through minimal coupling,
  3. The photon’s energy.

The Hamiltonian in SI units is:

H = (1/2me) [ -iℏ∇ - eA(r, t) ]2
    + eφ(r, t) 
    + (1/2)ε0 ∫ |E(r, t)|2 + (1/2μ0)|B(r, t)|2 d3r,

where:

  • φ(r, t) is the scalar potential,
  • E = -∂A/∂t - ∇φ is the electric field,
  • B = ∇×A is the magnetic field.

Simplifying for interaction only, the Schrödinger equation is:

iℏ∂ψe/∂t = Hψe.

Solving for Energy States

Solving the energy states requires quantizing the photon field. Using second quantization:

  • Represent the photon field as a superposition of modes:
        A(r, t) = Σk sqrt(ℏ/2ε0ωk) 
        [ akeik·r + ake-ik·r ].
    

Approach to Energy Levels:

  1. Electron in an Electromagnetic Field (Perturbation Theory): For weak coupling, perturbation theory gives corrections to the electron’s energy levels.
  2. Jaynes-Cummings Model: For resonant interactions (electron treated as a two-level system), one can use this model to calculate Rabi oscillations and energy splitting.
  3. Numerical Methods: For more general cases, computational methods are necessary.

 

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