Two-dimensional Planck spectroscopy for microwave photon calibration

S. Gandorfer; M. Renger; W. K. Yam; F. Fesquet; A. Marx; R. Gross; K. G. Fedorov

doi:10.1103/PhysRevApplied.23.024064

Two-dimensional Planck spectroscopy for microwave photon calibration

S. Gandorfer
, M. Renger
, W. K. Yam
, F. Fesquet
, A. Marx
, R. Gross
, K. G. Fedorov

Chair of Technical Physics

Walther-Meissner-Institut
Technical University of Munich
Munich Center for Quantum Science and Technology (MCQST)

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Quantum state tomography of weak microwave signals is an important part of many protocols in the field of quantum information processing with superconducting circuits. This step typically relies on an accurate in-situ estimation of signal losses in the experimental setup and requires a careful photon-number calibration. Here, we present an improved method for the microwave loss estimation inside of a closed cryogenic system. Our approach is based on Planck's law and makes use of independent temperature sweeps of individual parts of the cryogenic setup. Using this technique, we can experimentally resolve changes in microwave losses of less than 0.1 dB in the cryogenic environment. We discuss potential applications of this approach for the precise characterization of quantum limited superconducting amplifiers and in other prominent experimental settings.

Original language	English
Article number	024064
Journal	Physical Review Applied
Volume	23
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevApplied.23.024064
State	Published - Feb 2025

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10.1103/PhysRevApplied.23.024064

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abstract = "Quantum state tomography of weak microwave signals is an important part of many protocols in the field of quantum information processing with superconducting circuits. This step typically relies on an accurate in-situ estimation of signal losses in the experimental setup and requires a careful photon-number calibration. Here, we present an improved method for the microwave loss estimation inside of a closed cryogenic system. Our approach is based on Planck's law and makes use of independent temperature sweeps of individual parts of the cryogenic setup. Using this technique, we can experimentally resolve changes in microwave losses of less than 0.1 dB in the cryogenic environment. We discuss potential applications of this approach for the precise characterization of quantum limited superconducting amplifiers and in other prominent experimental settings.",

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AU - Yam, W. K.

AU - Fesquet, F.

AU - Marx, A.

AU - Gross, R.

AU - Fedorov, K. G.

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N2 - Quantum state tomography of weak microwave signals is an important part of many protocols in the field of quantum information processing with superconducting circuits. This step typically relies on an accurate in-situ estimation of signal losses in the experimental setup and requires a careful photon-number calibration. Here, we present an improved method for the microwave loss estimation inside of a closed cryogenic system. Our approach is based on Planck's law and makes use of independent temperature sweeps of individual parts of the cryogenic setup. Using this technique, we can experimentally resolve changes in microwave losses of less than 0.1 dB in the cryogenic environment. We discuss potential applications of this approach for the precise characterization of quantum limited superconducting amplifiers and in other prominent experimental settings.

AB - Quantum state tomography of weak microwave signals is an important part of many protocols in the field of quantum information processing with superconducting circuits. This step typically relies on an accurate in-situ estimation of signal losses in the experimental setup and requires a careful photon-number calibration. Here, we present an improved method for the microwave loss estimation inside of a closed cryogenic system. Our approach is based on Planck's law and makes use of independent temperature sweeps of individual parts of the cryogenic setup. Using this technique, we can experimentally resolve changes in microwave losses of less than 0.1 dB in the cryogenic environment. We discuss potential applications of this approach for the precise characterization of quantum limited superconducting amplifiers and in other prominent experimental settings.

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Two-dimensional Planck spectroscopy for microwave photon calibration

Abstract

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