Comparison of gate geometries for tunable, local barriers in InAs nanowires

Peter Dahl Nissen; Thomas Sand Jespersen; Kasper Grove-Rasmussen; Attila Márton; Shivendra Upadhyay; Morten Hannibal Madsen; Szabolcs Csonka; Jesper Nygård

doi:10.1063/1.4759248

Comparison of gate geometries for tunable, local barriers in InAs nanowires

Peter Dahl Nissen, Thomas Sand Jespersen, Kasper Grove-Rasmussen, Attila Márton, Shivendra Upadhyay, Morten Hannibal Madsen, Szabolcs Csonka, Jesper Nygård

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3 Citationer (Scopus)

Abstract

We report measurements and analysis of gate-induced electrostatic barriers for electron transport in InAs nanowires. Three types of local gates are analyzed; narrow gates (50 - 100 nm) located on top of or below the nanowire, and wide gates overlapping the interfaces between nanowire and source and drain electrodes. We find that applying negative potentials to the local gate electrodes induces tunable barriers of up to 0.25 eV and that transport through the wire can be blocked at neutral and slightly positive potentials on the nanowire-contact gates, indicating that built-in barriers can exist at the nanowire-contact interface. The contact gates can be biased to remove the unwanted interface barriers occasionally formed during processing. From the temperature dependence of the conductance, the barrier height is extracted and mapped as a function of gate voltage. Top and bottom gates are similar to each other in terms of electrostatic couplings (lever arms ∼ 0.1 - 0.2 eV / V) and threshold voltages for barrier induction (V _g ∼ - 1 to - 2 V), but low temperature gate sweeps suggest that device stability could be affected by the differences in device processing for the two gate geometries.

Originalsprog	Engelsk
Artikelnummer	084323
Tidsskrift	Journal of Applied Physics
Vol/bind	112
Udgave nummer	8
Antal sider	7
ISSN	0021-8979
DOI	https://doi.org/10.1063/1.4759248
Status	Udgivet - 15 okt. 2012

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10.1063/1.4759248

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abstract = "We report measurements and analysis of gate-induced electrostatic barriers for electron transport in InAs nanowires. Three types of local gates are analyzed; narrow gates (50 - 100 nm) located on top of or below the nanowire, and wide gates overlapping the interfaces between nanowire and source and drain electrodes. We find that applying negative potentials to the local gate electrodes induces tunable barriers of up to 0.25 eV and that transport through the wire can be blocked at neutral and slightly positive potentials on the nanowire-contact gates, indicating that built-in barriers can exist at the nanowire-contact interface. The contact gates can be biased to remove the unwanted interface barriers occasionally formed during processing. From the temperature dependence of the conductance, the barrier height is extracted and mapped as a function of gate voltage. Top and bottom gates are similar to each other in terms of electrostatic couplings (lever arms ∼ 0.1 - 0.2 eV / V) and threshold voltages for barrier induction (V g ∼ - 1 to - 2 V), but low temperature gate sweeps suggest that device stability could be affected by the differences in device processing for the two gate geometries.",

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AU - Nissen, Peter Dahl

AU - Jespersen, Thomas Sand

AU - Grove-Rasmussen, Kasper

AU - Márton, Attila

AU - Upadhyay, Shivendra

AU - Madsen, Morten Hannibal

AU - Csonka, Szabolcs

AU - Nygård, Jesper

N1 - [QDev]

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N2 - We report measurements and analysis of gate-induced electrostatic barriers for electron transport in InAs nanowires. Three types of local gates are analyzed; narrow gates (50 - 100 nm) located on top of or below the nanowire, and wide gates overlapping the interfaces between nanowire and source and drain electrodes. We find that applying negative potentials to the local gate electrodes induces tunable barriers of up to 0.25 eV and that transport through the wire can be blocked at neutral and slightly positive potentials on the nanowire-contact gates, indicating that built-in barriers can exist at the nanowire-contact interface. The contact gates can be biased to remove the unwanted interface barriers occasionally formed during processing. From the temperature dependence of the conductance, the barrier height is extracted and mapped as a function of gate voltage. Top and bottom gates are similar to each other in terms of electrostatic couplings (lever arms ∼ 0.1 - 0.2 eV / V) and threshold voltages for barrier induction (V g ∼ - 1 to - 2 V), but low temperature gate sweeps suggest that device stability could be affected by the differences in device processing for the two gate geometries.

AB - We report measurements and analysis of gate-induced electrostatic barriers for electron transport in InAs nanowires. Three types of local gates are analyzed; narrow gates (50 - 100 nm) located on top of or below the nanowire, and wide gates overlapping the interfaces between nanowire and source and drain electrodes. We find that applying negative potentials to the local gate electrodes induces tunable barriers of up to 0.25 eV and that transport through the wire can be blocked at neutral and slightly positive potentials on the nanowire-contact gates, indicating that built-in barriers can exist at the nanowire-contact interface. The contact gates can be biased to remove the unwanted interface barriers occasionally formed during processing. From the temperature dependence of the conductance, the barrier height is extracted and mapped as a function of gate voltage. Top and bottom gates are similar to each other in terms of electrostatic couplings (lever arms ∼ 0.1 - 0.2 eV / V) and threshold voltages for barrier induction (V g ∼ - 1 to - 2 V), but low temperature gate sweeps suggest that device stability could be affected by the differences in device processing for the two gate geometries.

U2 - 10.1063/1.4759248

DO - 10.1063/1.4759248

M3 - Journal article

SN - 0021-8979

VL - 112

JO - Journal of Applied Physics

JF - Journal of Applied Physics

IS - 8

M1 - 084323

ER -

Comparison of gate geometries for tunable, local barriers in InAs nanowires

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