Hole Spin Relaxation in Ge/Si Core-Shell Nanowire Qubits

Yongjie Hu; Ferdinand Kuemmeth; Charles Lieber; Charles M. Marcus

doi:10.1038/nnano.2011.234

Hole Spin Relaxation in Ge/Si Core-Shell Nanowire Qubits

Yongjie Hu, Ferdinand Kuemmeth, Charles Lieber, Charles M. Marcus

146 Citations (Scopus)

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Abstract

Controlling decoherence is the biggest challenge in efforts to develop quantum information hardware^1-3. Single electron spins in gallium arsenide are a leading candidate among implementations of solid-state quantum bits, but their strong coupling to nuclear spins produces high decoherence rates^4-6. Group IV semiconductors, on the other hand, have relatively low nuclear spin densities, making them an attractive platform for spin quantum bits. However, device fabrication remains a challenge, particularly with respect to the control of materials and interfaces. Here, we demonstrate state preparation, pulsed gate control and charge-sensing spin readout of hole spins confined in a Ge-Si core-shell nanowire. With fast gating, we measure T ₁ spin relaxation times of up to 0.6? ms in coupled quantum dots at zero magnetic field. Relaxation time increases as the magnetic field is reduced, which is consistent with a spin-orbit mechanism that is usually masked by hyperfine contributions.

Original language	English
Journal	Nature Nanotechnology
Volume	7
Pages (from-to)	47-50
ISSN	1748-3387
DOIs	https://doi.org/10.1038/nnano.2011.234
Publication status	Published - Jan 2012
Externally published	Yes

Keywords

cond-mat.mes-hall
quant-ph

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title = "Hole Spin Relaxation in Ge/Si Core-Shell Nanowire Qubits",

abstract = "Controlling decoherence is the biggest challenge in efforts to develop quantum information hardware1-3. Single electron spins in gallium arsenide are a leading candidate among implementations of solid-state quantum bits, but their strong coupling to nuclear spins produces high decoherence rates4-6. Group IV semiconductors, on the other hand, have relatively low nuclear spin densities, making them an attractive platform for spin quantum bits. However, device fabrication remains a challenge, particularly with respect to the control of materials and interfaces. Here, we demonstrate state preparation, pulsed gate control and charge-sensing spin readout of hole spins confined in a Ge-Si core-shell nanowire. With fast gating, we measure T 1 spin relaxation times of up to 0.6? ms in coupled quantum dots at zero magnetic field. Relaxation time increases as the magnetic field is reduced, which is consistent with a spin-orbit mechanism that is usually masked by hyperfine contributions.",

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author = "Yongjie Hu and Ferdinand Kuemmeth and Charles Lieber and {M. Marcus}, Charles",

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T1 - Hole Spin Relaxation in Ge/Si Core-Shell Nanowire Qubits

AU - Hu, Yongjie

AU - Kuemmeth, Ferdinand

AU - Lieber, Charles

AU - M. Marcus, Charles

PY - 2012/1

Y1 - 2012/1

N2 - Controlling decoherence is the biggest challenge in efforts to develop quantum information hardware1-3. Single electron spins in gallium arsenide are a leading candidate among implementations of solid-state quantum bits, but their strong coupling to nuclear spins produces high decoherence rates4-6. Group IV semiconductors, on the other hand, have relatively low nuclear spin densities, making them an attractive platform for spin quantum bits. However, device fabrication remains a challenge, particularly with respect to the control of materials and interfaces. Here, we demonstrate state preparation, pulsed gate control and charge-sensing spin readout of hole spins confined in a Ge-Si core-shell nanowire. With fast gating, we measure T 1 spin relaxation times of up to 0.6? ms in coupled quantum dots at zero magnetic field. Relaxation time increases as the magnetic field is reduced, which is consistent with a spin-orbit mechanism that is usually masked by hyperfine contributions.

AB - Controlling decoherence is the biggest challenge in efforts to develop quantum information hardware1-3. Single electron spins in gallium arsenide are a leading candidate among implementations of solid-state quantum bits, but their strong coupling to nuclear spins produces high decoherence rates4-6. Group IV semiconductors, on the other hand, have relatively low nuclear spin densities, making them an attractive platform for spin quantum bits. However, device fabrication remains a challenge, particularly with respect to the control of materials and interfaces. Here, we demonstrate state preparation, pulsed gate control and charge-sensing spin readout of hole spins confined in a Ge-Si core-shell nanowire. With fast gating, we measure T 1 spin relaxation times of up to 0.6? ms in coupled quantum dots at zero magnetic field. Relaxation time increases as the magnetic field is reduced, which is consistent with a spin-orbit mechanism that is usually masked by hyperfine contributions.

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DO - 10.1038/nnano.2011.234

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JO - Nature Nanotechnology

JF - Nature Nanotechnology

ER -

Hole Spin Relaxation in Ge/Si Core-Shell Nanowire Qubits

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