Xi Liang scite author profile

Within the framework of the dielectric continuum model, the interface-optical (IO) phonon modes and their interaction with electrons in an asymmetric double-barrier structure is studied by using a transfer matrix method. The dispersion equation of IO phonon modes and the electron-IO-phonon (e-IO-p) interaction Hamiltonian are derived. It is found that there are eight branches of IO-phonon modes coupling with electrons besides the confined LO-phonon modes. The numerical results are obtained for several GaAs/Al x Ga 1-x As systems. It is seen that the contributions of long-wavelength phonons to the e-IO-p coupling are important. The e-IO-p coupling related to the IO modes with the GaAs LO-frequency (phonon energy 36.25 meV) at the long-wavelength limit is strongest in the eight branches of IO-phonon modes.

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Binding energies of donors in quantum wells under hydrostatic pressure

Zhao

Liang

Ban

2003

Physics Letters A

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Xi Liang

Effects of interface and bulk optical phonons on polarons in a quantum well

Transfer Matrix Method for Electron-Io-Phonon Interaction in Asymmetric Double-Barrier Structures

Binding energies of donors in quantum wells under hydrostatic pressure

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