Related papers: One-dimensional quantum dot array integrated with charge sensors in an InAs nanowire

One-dimensional quantum dot array integrated with charge sensors in an InAs nanowire

URL: http://arxiv.org/abs/2407.15534v1
Date: Mon, 22 Jul 2024 10:53:39 GMT
Title: One-dimensional quantum dot array integrated with charge sensors in an InAs nanowire
Authors: Yi Luo, Xiao-Fei Liu, Zhi-Hai Liu, Weijie Li, Shili Yan, Han Gao, Haitian Su, Dong Pan, Jianhua Zhao, Ji-Yin Wang, H. Q. Xu,
Abstract summary: We report a one-dimensional quintuple-quantum-dot array integrated with two quantum dot charge sensors in an InAs nanowire. The device is studied by measuring double quantum dots formed consecutively in the array. A theoretical simulation based on a 4-dimensional Hamiltonian confirms the strong coupling strength between the two double quantum dots.
Score: 11.376853122289328
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We report an experimental study of a one-dimensional quintuple-quantum-dot array integrated with two quantum dot charge sensors in an InAs nanowire. The device is studied by measuring double quantum dots formed consecutively in the array and corresponding charge stability diagrams are revealed with both direct current measurements and charge sensor signals. The one-dimensional quintuple-quantum-dot array are then tuned up and its charge configurations are fully mapped out with the two charge sensors. The energy level of each dot in the array can be controlled individually by using a compensated gate architecture (i.e., "virtual gate"). After that, four dots in the array are selected to form two double quantum dots and ultra strong inter-double-dot interaction is obtained. A theoretical simulation based on a 4-dimensional Hamiltonian confirms the strong coupling strength between the two double quantum dots. The highly controllable one-dimensional quantum dot array achieved in this work is expected to be valuable for employing InAs nanowires to construct advanced quantum hardware in the future.

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