Search results for "Quantum wire"

showing 2 items of 22 documents

Quantum wire with periodic serial structure

1991

Electron wave motion in a quantum wire with periodic structure is treated by direct solution of the Schr\"odinger equation as a mode-matching problem. Our method is particularly useful for a wire consisting of several distinct units, where the total transfer matrix for wave propagation is just the product of those for its basic units. It is generally applicable to any linearly connected serial device, and it can be implemented on a small computer. The one-dimensional mesoscopic crystal recently considered by Ulloa, Casta\~no, and Kirczenow [Phys. Rev. B 41, 12 350 (1990)] is discussed with our method, and is shown to be a strictly one-dimensional problem. Electron motion in the multiple-stu…

Wave propagationThin filmsDispersió (Física nuclear)Schrödinger equationElectronTransport d'electronsSchrödinger equationsymbols.namesakeOpticsQuantum mechanicsPel·lícules finesPhysicsMesoscopic physicsFenòmens mesoscòpics (Física)business.industryQuantum wireElectron transportNanostructured materialsTransfer matrixElectronic transportProduct (mathematics)Scattering (Physics)Equació de SchrödingersymbolsMesoscopic phenomena (Physics)Fundamental Resolution EquationMaterials nanoestructuratsbusinessTeoria del transport
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Size control of InAs∕InP(001) quantum wires by tailoring P∕As exchange

2004

The size and emission wavelength of self-assembled InAs∕InP(001) quantum wires (QWrs) is affected by the P∕As exchange process. In this work, we demonstrate by in situ stress measurements that P∕As exchange at the InAs∕InP interface depends on the surface reconstruction of the InAs starting surface and its immediate evolution when the arsenic cell is closed. Accordingly, the amount of InP grown on InAs by P∕As exchange increases with substrate temperature in a steplike way. These results allow us to engineer the size of the QWr for emission at 1.3 and 1.55 μm at room temperature by selecting the range of substrate temperatures in which the InP cap layer is grown.

Work (thermodynamics)Materials scienceOptical fiberPhysics and Astronomy (miscellaneous)Substrate (electronics)Optoelectronic deviceslaw.inventionEmissionOptical fibreslawIndium compoundsArsenic compoundsSize effectPhosphorus compoundsRange (particle radiation)business.industrySelf-assemblyWavelengthSemiconductor quantum wiresOptoelectronicsSelf-assemblybusinessSurface reconstructionLayer (electronics)Surface reconstruction
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