Single-Electron Occupation in Quantum Dot Arrays at Selectable Plunger Gate Voltage

Journal article (2023)

Authors

M. Meyer Kavli institute of nanoscience Delft, QuTech Advanced Research Centre, QCD/Veldhorst Lab - QuTech Advanced Research Centre
C.C. Déprez Kavli institute of nanoscience Delft, QCD/Veldhorst Lab - QuTech Advanced Research Centre , QuTech Advanced Research Centre
Ilja N. Meijer Kavli institute of nanoscience Delft, Student
F.K. Unseld QCD/Vandersypen Lab - QuTech Advanced Research Centre , Kavli institute of nanoscience Delft, QuTech Advanced Research Centre
S. Karwal BUS/TNO STAFF - QuTech Advanced Research Centre , TNO, QuTech Advanced Research Centre
A. Sammak TNO, QuTech Advanced Research Centre, BUS/TNO STAFF - QuTech Advanced Research Centre
G. Scappucci QCD/Scappucci Lab - QuTech Advanced Research Centre , Kavli institute of nanoscience Delft, QuTech Advanced Research Centre
L.M.K. Vandersypen QN/Vandersypen Lab - AS , Kavli institute of nanoscience Delft, QuTech Advanced Research Centre
M. Veldhorst QuTech Advanced Research Centre, QN/Veldhorst Lab - AS , Kavli institute of nanoscience Delft
Affiliation
QuTech Advanced Research Centre
More Info
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Published Date

2023

Language

English

Affiliation

QuTech Advanced Research Centre

Abstract

The small footprint of semiconductor qubits is favorable for scalable quantum computing. However, their size also makes them sensitive to their local environment and variations in the gate structure. Currently, each device requires tailored gate voltages to confine a single charge per quantum dot, clearly challenging scalability. Here, we tune these gate voltages and equalize them solely through the temporary application of stress voltages. In a double quantum dot, we reach a stable (1,1) charge state at identical and predetermined plunger gate voltage and for various interdot couplings. Applying our findings, we tune a 2 × 2 quadruple quantum dot such that the (1,1,1,1) charge state is reached when all plunger gates are set to 1 V. The ability to define required gate voltages may relax requirements on control electronics and operations for spin qubit devices, providing means to advance quantum hardware.