Abstract

Superconducting microwave circuits show great potential for practical quantum technological applications such as quantum information processing. However, fast and on-demand initialization of the quantum degrees of freedom in these devices remains a challenge. Here, we experimentally implement a tunable heat sink that is potentially suitable for the initialization of superconducting qubits. Our device consists of two coupled resonators. The first resonator has a high quality factor and a fixed frequency whereas the second resonator is designed to have a low quality factor and a tunable resonance frequency. We engineer the low quality factor using an on-chip resistor and the frequency tunability using a superconducting quantum interference device. When the two resonators are in resonance, the photons in the high-quality resonator can be efficiently dissipated. We show that the corresponding loaded quality factor can be tuned from above 105 down to a few thousand at 10 GHz in good quantitative agreement with our theoretical model.

Highlights

  • One of the most promising approaches to building a quantum computer is based on superconducting qubits in the framework of circuit quantum electrodynamics[1,2,3,4,5,6]

  • The modes of Resonator 2 are tunable owing to a superconducting quantum interference device (SQUID), acting as a flux-tunable inductance, placed in the middle of the resonator

  • The SQUID is integrated into the center pin of the waveguide and consists of two aluminium layers separated by an insulating aluminium oxide layer

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Summary

Introduction

One of the most promising approaches to building a quantum computer is based on superconducting qubits in the framework of circuit quantum electrodynamics[1,2,3,4,5,6]. Many quantum error correction codes require frequent initialization of ancillary qubits during the computation. In this work we focus on a specialized initialization circuit, which remains to be implemented in superconducting quantum processors. A promising qubit initialization protocol based on dissipative environments was proposed in refs[15,16]. We experimentally realize such a tunable dissipative environment and study its effect on a superconducting resonator. Tunable transmission lines are useful in studying fundamental quantum phenomena[26,27]. Dissipation is in some cases beneficial for quantum computing[28], lossy materials are typically harmful for qubit lifetimes during computation. We tune the Q factor from above 105 down to a few thousand by coupling the resonator relatively strongly to a dissipative element. The integrated resistive element we introduce does not inherently degrade the Q factor when it is weakly coupled to the resonator compared to fabricated resonators without any engineered resistive elements

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