Electron-longitudinal acoustic phonon interaction

The electron-LA phonon interaction is an interaction that can take place between an electron and a longitudinal acoustic (LA) phonon in a material such as a semiconductor.

Displacement operator of the LA phonon

The equations of motion of the atoms of mass M which locates in the periodic lattice is

,

where is the displacement of the nth atom from their equilibrium positions.

Defining the displacement of the th atom by , where is the coordinates of the th atom and is the lattice constant,

the displacement is given by

Then using Fourier transform:

and

.

Since is a Hermite operator,

From the definition of the creation and annihilation operator

is written as

Then expressed as

Hence, using the continuum model, the displacement operator for the 3-dimensional case is

,

where is the unit vector along the displacement direction.

Interaction Hamiltonian

The electron-longitudinal acoustic phonon interaction Hamiltonian is defined as

,

where is the deformation potential for electron scattering by acoustic phonons.[1]

Inserting the displacement vector to the Hamiltonian results to

Scattering probability

The scattering probability for electrons from to states is

Replace the integral over the whole space with a summation of unit cell integrations

where , is the volume of a unit cell.

gollark: You can still do that while storing it locally, but people don't like anything which requires actually having any technical competence whatsoever nowadays.
gollark: They could get a non-"cloud" security camera.
gollark: And apparently provides video to local police or something.
gollark: They have a known awful privacy record. Are you sure you can't get them to reconsider?
gollark: Oh dear.

See also

Notes

  1. Hamaguchi, Chihiro. Basic Semiconductor Physics (3 ed.). Springer. p. 292. ISBN 978-3-319-88329-8.

References

  • Hamaguchi, Chihiro. Basic Semiconductor Physics (3 ed.). Springer. pp. 265–363. ISBN 978-3-319-88329-8.
  • Yu, Peter Y.; Cardona, Manuel (2005). Fundamentals of Semiconductors (3rd ed.). Springer.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.