Electrical characteristics of core–shell p–n GaAs nanowire structures with Te as the n-dopant

GaAs nanowire (NW)-based p-n photovoltaic devices, with two distinct p and n spatial distributions and where Te was the n-dopant, have been studied by impedance spectroscopy in the 10(3)-10(7) Hz frequency range and the - 1.5-1.5 V bias range. For a large n-core/p-shell overlap region within NWs in...

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Veröffentlicht in:	Nanotechnology 2010-04, Vol.21 (13), p.134007-134007
Hauptverfasser:	Caram, J, Sandoval, C, Tirado, M, Comedi, D, Czaban, J, Thompson, D A, LaPierre, R R
Format:	Artikel
Sprache:	eng
Schlagworte:	Bias Conductance Devices Dispersions Gallium arsenide Gallium arsenides Nanocomposites Nanomaterials Nanostructure Nanowires
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creator	Caram, J Sandoval, C Tirado, M Comedi, D Czaban, J Thompson, D A LaPierre, R R
description	GaAs nanowire (NW)-based p-n photovoltaic devices, with two distinct p and n spatial distributions and where Te was the n-dopant, have been studied by impedance spectroscopy in the 10(3)-10(7) Hz frequency range and the - 1.5-1.5 V bias range. For a large n-core/p-shell overlap region within NWs in a coaxial geometry, the p-n junction properties (DC rectification and p-n depletion capacitance) are found to prevail. The impedance data at low bias for both NW devices show large frequency dispersions with relaxation frequencies that are compatible with carrier re-emission times from traps due to GaAs surface states. An increasing conductance with increasing frequency for low bias is observed, suggesting hopping transport through localized states. For large bias the conductance increases exponentially with bias and is frequency independent, indicating conduction through extended states in this regime.
doi_str_mv	10.1088/0957-4484/21/13/134007
format	Article
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For a large n-core/p-shell overlap region within NWs in a coaxial geometry, the p-n junction properties (DC rectification and p-n depletion capacitance) are found to prevail. The impedance data at low bias for both NW devices show large frequency dispersions with relaxation frequencies that are compatible with carrier re-emission times from traps due to GaAs surface states. An increasing conductance with increasing frequency for low bias is observed, suggesting hopping transport through localized states. 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subjects	Bias Conductance Devices Dispersions Gallium arsenide Gallium arsenides Nanocomposites Nanomaterials Nanostructure Nanowires
title	Electrical characteristics of core–shell p–n GaAs nanowire structures with Te as the n-dopant
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