On-chip integration of Si/SiGe-based quantum dots and electronic circuits for scaling

Y. Xu

On-chip integration of Si/SiGe-based quantum dots and electronic circuits for scaling

Y. Xu

QCD/Vandersypen Lab

Research output: Thesis › Dissertation (TU Delft)

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Abstract

With continuous breakthroughs in quantum science and technology in recent years, the development of quantum computers is moving from pure scientific research to engineering realization. Meanwhile, the underlying physical structures also develop from the initial single qubit to multiple qubits or medium-scale qubit registers. Since qubits are operated by many sophisticated instruments under strict environmental conditions, people need a scalable solution to support many qubits working at the same time, so as to achieve high computing speed for a practical quantum computer.

Original language	English
Awarding Institution	Delft University of Technology
Supervisors/Advisors	Vandersypen, L.M.K., Supervisor Ishihara, R., Advisor
Award date	23 Nov 2021
Print ISBNs	978-94-6419-370-1
Publication status	Published - 2021

Keywords

floating gate
quantum dots
integration
scalability

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Dissertation - XUFinal published version, 9.12 MB
propositions - XUFinal published version, 52.8 KB

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title = "On-chip integration of Si/SiGe-based quantum dots and electronic circuits for scaling",

abstract = "With continuous breakthroughs in quantum science and technology in recent years, the development of quantum computers is moving from pure scientific research to engineering realization. Meanwhile, the underlying physical structures also develop from the initial single qubit to multiple qubits or medium-scale qubit registers. Since qubits are operated by many sophisticated instruments under strict environmental conditions, people need a scalable solution to support many qubits working at the same time, so as to achieve high computing speed for a practical quantum computer.",

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AB - With continuous breakthroughs in quantum science and technology in recent years, the development of quantum computers is moving from pure scientific research to engineering realization. Meanwhile, the underlying physical structures also develop from the initial single qubit to multiple qubits or medium-scale qubit registers. Since qubits are operated by many sophisticated instruments under strict environmental conditions, people need a scalable solution to support many qubits working at the same time, so as to achieve high computing speed for a practical quantum computer.

KW - floating gate

KW - quantum dots

KW - integration

KW - scalability

M3 - Dissertation (TU Delft)

SN - 978-94-6419-370-1

ER -

On-chip integration of Si/SiGe-based quantum dots and electronic circuits for scaling

Abstract

Keywords

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