Low-Temperature Characteristics of Nanowire Network Demultiplexer for Qubit Biasing

Lasse Södergren; Patrik Olausson; Erik Lind

doi:10.1021/acs.nanolett.1c04971

Low-Temperature Characteristics of Nanowire Network Demultiplexer for Qubit Biasing

Lasse Södergren, Patrik Olausson, Erik Lind

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In current quantum computers, most qubit control electronics are connected to the qubit chip inside the cryostat by cables at room temperature. This poses a challenge when scaling the quantum chip to an increasing number of qubits. We present a lateral nanowire network 1-to-4 demultiplexer design fabricated by selective area grown InGaAs on InP, suitable for on chip routing of DC current for qubit biasing. We have characterized the device at cryogenic temperatures, and at 40 mK the device exhibits a minimum inverse subthreshold slope of 2 mV/dec, which is encouraging for low power operation. At low drain bias, the transmission breaks up into several resonance peaks due to a rough conduction band edge; this is qualitatively explained by a simple model based on a 1D real space tight-binding nonequilibrium Green's functions model.

Originalspråk	engelska
Sidor (från-till)	3884-3888
Antal sidor	5
Tidskrift	Nano Letters
Volym	22
Nummer	10
DOI	https://doi.org/10.1021/acs.nanolett.1c04971
Status	Published - 2022 maj 25

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10.1021/acs.nanolett.1c04971Licens: CC BY

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III-V Devices for Emerging Electronic Applications
Bidragets översatta titel : III-V komponenter för nya elektroniska applikationerOlausson, P., 2024 jan. 25, Lund: Department of Electrical and Information Technology, Lund University. 180 s.
Forskningsoutput: Avhandling › Doktorsavhandling (sammanläggning)

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III-V komponenter för nya elektroniska applikationer
Olausson, P. (Forskarstuderande), Lind, E. (Handledare) & Borg, M. (Biträdande handledare)
2019/07/01 → 2024/02/23
Projekt: Avhandling

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title = "Low-Temperature Characteristics of Nanowire Network Demultiplexer for Qubit Biasing",

abstract = "In current quantum computers, most qubit control electronics are connected to the qubit chip inside the cryostat by cables at room temperature. This poses a challenge when scaling the quantum chip to an increasing number of qubits. We present a lateral nanowire network 1-to-4 demultiplexer design fabricated by selective area grown InGaAs on InP, suitable for on chip routing of DC current for qubit biasing. We have characterized the device at cryogenic temperatures, and at 40 mK the device exhibits a minimum inverse subthreshold slope of 2 mV/dec, which is encouraging for low power operation. At low drain bias, the transmission breaks up into several resonance peaks due to a rough conduction band edge; this is qualitatively explained by a simple model based on a 1D real space tight-binding nonequilibrium Green's functions model.",

keywords = "cryogenic, InGaAs, multiplexer, nanowire",

author = "Lasse S{\"o}dergren and Patrik Olausson and Erik Lind",

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doi = "10.1021/acs.nanolett.1c04971",

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AU - Södergren, Lasse

AU - Olausson, Patrik

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Y1 - 2022/5/25

N2 - In current quantum computers, most qubit control electronics are connected to the qubit chip inside the cryostat by cables at room temperature. This poses a challenge when scaling the quantum chip to an increasing number of qubits. We present a lateral nanowire network 1-to-4 demultiplexer design fabricated by selective area grown InGaAs on InP, suitable for on chip routing of DC current for qubit biasing. We have characterized the device at cryogenic temperatures, and at 40 mK the device exhibits a minimum inverse subthreshold slope of 2 mV/dec, which is encouraging for low power operation. At low drain bias, the transmission breaks up into several resonance peaks due to a rough conduction band edge; this is qualitatively explained by a simple model based on a 1D real space tight-binding nonequilibrium Green's functions model.

AB - In current quantum computers, most qubit control electronics are connected to the qubit chip inside the cryostat by cables at room temperature. This poses a challenge when scaling the quantum chip to an increasing number of qubits. We present a lateral nanowire network 1-to-4 demultiplexer design fabricated by selective area grown InGaAs on InP, suitable for on chip routing of DC current for qubit biasing. We have characterized the device at cryogenic temperatures, and at 40 mK the device exhibits a minimum inverse subthreshold slope of 2 mV/dec, which is encouraging for low power operation. At low drain bias, the transmission breaks up into several resonance peaks due to a rough conduction band edge; this is qualitatively explained by a simple model based on a 1D real space tight-binding nonequilibrium Green's functions model.

KW - cryogenic

KW - InGaAs

KW - multiplexer

KW - nanowire

U2 - 10.1021/acs.nanolett.1c04971

DO - 10.1021/acs.nanolett.1c04971

M3 - Article

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SN - 1530-6984

VL - 22

SP - 3884

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JO - Nano Letters

JF - Nano Letters

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ER -

Low-Temperature Characteristics of Nanowire Network Demultiplexer for Qubit Biasing

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Ämnesklassifikation (UKÄ)

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III-V Devices for Emerging Electronic Applications

Projekt

III-V komponenter för nya elektroniska applikationer

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