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Coupling of a hole double quantum dot in planar germanium to a microwave cavity

Yuan Kang, Zong-Hu Li, Zhenzhen Kong, Fang-Ge Li, Tian-Yue Hao, Ze-Cheng Wei, Song-Yan Deng, Bao‐Chuan Wang, Hai-Ou Li, Guilei Wang, Guang-Can Guo, Gang Cao, Guo-Ping Guo

2024Physical Review Applied12 citationsDOI

Abstract

In recent years, notable progress has been made in the study of hole qubits in planar germanium, and circuit quantum electrodynamics (circuit QED) has emerged as a promising approach for achieving long-range coupling and scaling up of qubits. Here, we demonstrate the coupling between holes in a planar germanium double quantum dot (DQD) and photons in a microwave cavity. Specifically, a real-time calibrated virtual gate method is developed to characterize this hybrid system, which in turn allows us to determine the typical parameters sequentially through a single-parameter fitting instead of conventional multiparameter fitting with additional uncertainty, giving a hole-photon coupling rate of ${g}_{0}$/2\ensuremath{\pi} = 21.7 MHz. This work is a step toward further research on hole-photon interactions and long-range qubit coupling in planar germanium. The experimental method developed in this work contributes to a more accurate and efficient characterization of hybrid cavity-QED systems.

Topics & Concepts

QubitPhysicsPlanarGermaniumPhotonCoupling (piping)MicrowaveQuantum dotSuperconducting quantum computingQuantumOptoelectronicsQuantum mechanicsMaterials scienceSiliconComputer scienceComputer graphics (images)MetallurgyQuantum Information and CryptographyQuantum and electron transport phenomenaQuantum Computing Algorithms and Architecture
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