Theory of Photoluminescence from a Magnetic Field Induced Two-dimensional Quantum Wigner Crystal

We develop a theory of photoluminescence using a time-dependent Hartree-Fock approximation that is appropriate for the two-dimensional Wigner crystal in a strong magnetic field. The cases of localized and itinerant holes are both studied. It is found that the photoluminescence spectrum is a weighted...

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Bibliographic Details
Published inarXiv.org
Main Authors Dong-Zi, Liu, Fertig, H A, S Das Sarma
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 11.05.1993
Subjects
Crystals
Density of states
Electron density
Electron-hole interaction
Hartree approximation
Holes (electron deficiencies)
Magnetic fields
Particle density (concentration)
Photoluminescence
Quantum wells
Strong interactions (field theory)
Time dependence
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Summary:We develop a theory of photoluminescence using a time-dependent Hartree-Fock approximation that is appropriate for the two-dimensional Wigner crystal in a strong magnetic field. The cases of localized and itinerant holes are both studied. It is found that the photoluminescence spectrum is a weighted measure of the single particle density of states of the electron system, which for an undisturbed electron lattice has the intricate structure of the Hofstadter butterfly. It is shown that for the case of a localized hole, a strong interaction of the hole with the electron lattice tends to wipe out this structure. In such cases, a single final state is strongly favored in the recombination process, producing a single line in the spectrum. For the case of an itinerant hole, which could be generated in a wide quantum well system, we find that electron-hole interactions do not significantly alter the density of states of the Wigner crystal, opening the possibility of observing the Hofstadter gap spectrum in the electron density of states directly. At experimentally relevant filling fractions, these gaps are found to be extremely small, due to exchange effects. However, it is found that the hole, which interacts with the periodic potential of the electron crystal, has a Hofstadter spectrum with much larger gaps. It is shown that a finite temperature experiment would allow direct probing of this gap structure through photoluminescence.
ISSN:2331-8422
DOI:10.48550/arxiv.9305006