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Electronic structures and electron spin decoherence in (001)-grown layered zincblende semiconductors

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 Added by Wayne Lau
 Publication date 2004
  fields Physics
and research's language is English




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Electronic structure calculations for layered zincblende semiconductors are described within a restricted basis formalism which naturally and non-perturbatively accomodates both crystalline inversion asymmetry and cubic anisotropy. These calculations are applied to calculate the electron spin decoherence times $T_1$ and $T_2$ due to precessional decoherence in quantum wells. Distinctly different dependences of spin coherence times on mobility, quantization energy, and temperature are found from perturbative calculations. Quantitative agreement between these calculations and experiments is found for GaAs/AlGaAs, InGaAs/InP, and GaSb/AlSb $(001)$-grown quantum wells. The electron spin coherence times for CdZnSe/ZnSe II-VI quantum wells are calculated, and calculations of InGaAs/GaAs quantum wells appropiate for comparison with spin-LED structures are also presented.



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A theory for longitudinal (T1) and transverse (T2) electron spin coherence times in zincblende semiconductor quantum wells is developed based on a non-perturbative nanostructure model solved in a fourteen-band restricted basis set. Distinctly different dependences of coherence times on mobility, quantization energy, and temperature are found from previous calculations. Quantitative agreement between our calculations and measurements is found for GaAs/AlGaAs, InGaAs/InP, and GaSb/AlSb quantum wells.
We present a detailed experimental and theoretical analysis of the spin dynamics of two-dimensional electron gases (2DEGs) in a series of n-doped GaAs/AlGaAs quantum wells. Picosecond-resolution polarized pump-probe reflection techniques were applied in order to study in detail the temperature-, concentration- and quantum-well-width- dependencies of the spin relaxation rate of a small photoexcited electron population. A rapid enhancement of the spin life-time with temperature up to a maximum near the Fermi temperature of the 2DEG was demonstrated experimentally. These observations are consistent with the Dyakonov-Perel spin relaxation mechanism controlled by electron-electron collisions. The experimental results and theoretical predictions for the spin relaxation times are in good quantitative agreement.
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Hexagonal boron nitride (BN), one of the very few layered insulators, plays a crucial role in 2D materials research. In particular, BN grown with a high pressure technique has proven to be an excellent substrate material for graphene and related 2D materials, but at the same time very hard to replace. Here we report on a method of growth at atmospheric pressure as a true alternative for producing BN for high quality graphene/BN heterostructures. The process is not only more scalable, but also allows to grow isotopically purified BN crystals. We employ Raman spectroscopy, cathodoluminescence, and electronic transport measurements to show the high-quality of such monoisotopic BN and its potential for graphene-based heterostructures. The excellent electronic performance of our heterostructures is demonstrated by well developed fractional quantum Hall states, ballistic transport over distances around $10,mathrm{mu m}$ at low temperatures and electron-phonon scattering limited transport at room temperature.
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