Two-level system hyperpolarization using a quantum Szilard engine

The innate complexity of solid state physics exposes superconducting quantum circuits to interactions with uncontrolled degrees of freedom degrading their coherence. By using a simple stabilization sequence we show that a superconducting fluxonium qubit is coupled to a two-level system (TLS) environ...

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Veröffentlicht in:	arXiv.org 2024-05
Hauptverfasser:	Spiecker, Martin, Paluch, Patrick, Gosling, Nicolas, Drucker, Niv, Matityahu, Shlomi, Gusenkova, Daria, Günzler, Simon, Rieger, Dennis, Takmakov, Ivan, Valenti, Francesco, Winkel, Patrick, Gebauer, Richard, Sander, Oliver, Catelani, Gianluigi, Shnirman, Alexander, Ustinov, Alexey V, Wernsdorfer, Wolfgang, Cohen, Yonatan, Pop, Ioan M
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Schlagworte:	Active control Feedback control Physics - Mesoscale and Nanoscale Physics Physics - Quantum Physics Physics - Statistical Mechanics Qubits (quantum computing) Relaxation time Solid state physics Superconductivity
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creator	Spiecker, Martin Paluch, Patrick Gosling, Nicolas Drucker, Niv Matityahu, Shlomi Gusenkova, Daria Günzler, Simon Rieger, Dennis Takmakov, Ivan Valenti, Francesco Winkel, Patrick Gebauer, Richard Sander, Oliver Catelani, Gianluigi Shnirman, Alexander Ustinov, Alexey V Wernsdorfer, Wolfgang Cohen, Yonatan Pop, Ioan M
description	The innate complexity of solid state physics exposes superconducting quantum circuits to interactions with uncontrolled degrees of freedom degrading their coherence. By using a simple stabilization sequence we show that a superconducting fluxonium qubit is coupled to a two-level system (TLS) environment of unknown origin, with a relatively long energy relaxation time exceeding $50\,\text{ms}$. Implementing a quantum Szilard engine with an active feedback control loop allows us to decide whether the qubit heats or cools its TLS environment. The TLSs can be cooled down resulting in a four times lower qubit population, or they can be heated to manifest themselves as a negative temperature environment corresponding to a qubit population of $\sim 80\,\%$. We show that the TLSs and the qubit are each other's dominant loss mechanism and that the qubit relaxation is independent of the TLS populations. Understanding and mitigating TLS environments is therefore not only crucial to improve qubit lifetimes but also to avoid non-Markovian qubit dynamics.
doi_str_mv	10.48550/arxiv.2204.00499
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By using a simple stabilization sequence we show that a superconducting fluxonium qubit is coupled to a two-level system (TLS) environment of unknown origin, with a relatively long energy relaxation time exceeding $50\,\text{ms}$. Implementing a quantum Szilard engine with an active feedback control loop allows us to decide whether the qubit heats or cools its TLS environment. The TLSs can be cooled down resulting in a four times lower qubit population, or they can be heated to manifest themselves as a negative temperature environment corresponding to a qubit population of $\sim 80\,\%$. We show that the TLSs and the qubit are each other's dominant loss mechanism and that the qubit relaxation is independent of the TLS populations. 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subjects	Active control Feedback control Physics - Mesoscale and Nanoscale Physics Physics - Quantum Physics Physics - Statistical Mechanics Qubits (quantum computing) Relaxation time Solid state physics Superconductivity
title	Two-level system hyperpolarization using a quantum Szilard engine
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