Electron Transport in Double-Barrier Semiconductor Heterostructures for Thermionic Cooling

We investigate electron transport in asymmetric double-barrier (Al, Ga)As/GaAs thermionic cooling heterostructures. Measurements of temperature-dependent current-voltage characteristics confirm that the dominant electron transport is a sequential process of resonant tunneling injection into and ther...

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Veröffentlicht in:	Physical review applied 2021-12, Vol.16 (6), Article 064017
Hauptverfasser:	Zhu, Xiangyu, Bescond, Marc, Onoue, Toshiki, Bastard, Gerald, Carosella, Francesca, Ferreira, Robson, Nagai, Naomi, Hirakawa, Kazuhiko
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Sprache:	eng
Schlagworte:	Physics
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container_title	Physical review applied
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creator	Zhu, Xiangyu Bescond, Marc Onoue, Toshiki Bastard, Gerald Carosella, Francesca Ferreira, Robson Nagai, Naomi Hirakawa, Kazuhiko
description	We investigate electron transport in asymmetric double-barrier (Al, Ga)As/GaAs thermionic cooling heterostructures. Measurements of temperature-dependent current-voltage characteristics confirm that the dominant electron transport is a sequential process of resonant tunneling injection into and thermionic emission from the quantum-well (QW) cooling layer. The thermal activation energy of the current is found to be strongly dependent on the bias voltage. Furthermore, instead of showing a simple thermal activation behavior, the current exhibits rather complicated temperature and voltage dependence, particularly when the thermionic emission barrier is low. To establish a quantitative understanding, we develop an intuitive analytical model for sequential electron transport that explicitly takes into account scattering effects in the thermionic emission process from the two-dimensional QW states to the three-dimensional above-barrier states. The observed temperature-dependent sequential current is well explained by the present theory.
doi_str_mv	10.1103/PhysRevApplied.16.064017
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title	Electron Transport in Double-Barrier Semiconductor Heterostructures for Thermionic Cooling
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