Impact of the gate geometry on adiabatic charge pumping in InAs double quantum dots

Sung Jin An; Myung Ho Bae; Myoung Jae Lee; Man Suk Song; Morten H. Madsen; Jesper Nygård; Christian Schönenberger; Andreas Baumgartner; Jungpil Seo; Minkyung Jung

doi:10.1039/d2na00372d

Impact of the gate geometry on adiabatic charge pumping in InAs double quantum dots

Sung Jin An, Myung Ho Bae, Myoung Jae Lee, Man Suk Song, Morten H. Madsen, Jesper Nygård, Christian Schönenberger, Andreas Baumgartner, Jungpil Seo, Minkyung Jung

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

We compare the adiabatic quantized charge pumping performed in two types of InAs nanowire double quantum dots (DQDs), either with tunnel barriers defined by closely spaced narrow bottom gates, or by well-separated side gates. In the device with an array of bottom gates of 100 nm pitch and 10 μm lengths, the pump current is quantized only up to frequencies of a few MHz due to the strong capacitive coupling between the bottom gates. In contrast, in devices with well-separated side gates with reduced mutual gate capacitances, we find well-defined pump currents up to 30 MHz. Our experiments demonstrate that high frequency quantized charge pumping requires careful optimization of the device geometry, including the typically neglected gate feed lines.

Original language	English
Pages (from-to)	3816-3823
Number of pages	8
Journal	Nanoscale Advances
Volume	4
Issue number	18
DOIs	https://doi.org/10.1039/d2na00372d
State	Published - 11 Aug 2022

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title = "Impact of the gate geometry on adiabatic charge pumping in InAs double quantum dots",

abstract = "We compare the adiabatic quantized charge pumping performed in two types of InAs nanowire double quantum dots (DQDs), either with tunnel barriers defined by closely spaced narrow bottom gates, or by well-separated side gates. In the device with an array of bottom gates of 100 nm pitch and 10 μm lengths, the pump current is quantized only up to frequencies of a few MHz due to the strong capacitive coupling between the bottom gates. In contrast, in devices with well-separated side gates with reduced mutual gate capacitances, we find well-defined pump currents up to 30 MHz. Our experiments demonstrate that high frequency quantized charge pumping requires careful optimization of the device geometry, including the typically neglected gate feed lines.",

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AU - An, Sung Jin

AU - Bae, Myung Ho

AU - Lee, Myoung Jae

AU - Song, Man Suk

AU - Madsen, Morten H.

AU - Nygård, Jesper

AU - Schönenberger, Christian

AU - Baumgartner, Andreas

AU - Seo, Jungpil

AU - Jung, Minkyung

PY - 2022/8/11

Y1 - 2022/8/11

N2 - We compare the adiabatic quantized charge pumping performed in two types of InAs nanowire double quantum dots (DQDs), either with tunnel barriers defined by closely spaced narrow bottom gates, or by well-separated side gates. In the device with an array of bottom gates of 100 nm pitch and 10 μm lengths, the pump current is quantized only up to frequencies of a few MHz due to the strong capacitive coupling between the bottom gates. In contrast, in devices with well-separated side gates with reduced mutual gate capacitances, we find well-defined pump currents up to 30 MHz. Our experiments demonstrate that high frequency quantized charge pumping requires careful optimization of the device geometry, including the typically neglected gate feed lines.

AB - We compare the adiabatic quantized charge pumping performed in two types of InAs nanowire double quantum dots (DQDs), either with tunnel barriers defined by closely spaced narrow bottom gates, or by well-separated side gates. In the device with an array of bottom gates of 100 nm pitch and 10 μm lengths, the pump current is quantized only up to frequencies of a few MHz due to the strong capacitive coupling between the bottom gates. In contrast, in devices with well-separated side gates with reduced mutual gate capacitances, we find well-defined pump currents up to 30 MHz. Our experiments demonstrate that high frequency quantized charge pumping requires careful optimization of the device geometry, including the typically neglected gate feed lines.

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DO - 10.1039/d2na00372d

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JO - Nanoscale Advances

JF - Nanoscale Advances

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Impact of the gate geometry on adiabatic charge pumping in InAs double quantum dots

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