Kinetic Inductance Current Sensor for Visible to Near-infrared Wavelength Transition-edge Sensor Readout

Overview

Journal Commun Eng

Publisher Springer Nature

Date 2024 Nov 6

PMID 39505997

Authors

Paul Szypryt

Douglas A Bennett

Ian Fogarty Florang

Joseph W Fowler

Andrea Giachero

Ruslan Hummatov

Adriana E Lita

John A B Mates

Sae Woo Nam

Galen C ONeil

Daniel S Swetz

Joel N Ullom

Michael R Vissers

Jordan Wheeler

Jiansong Gao

Affiliations

Soon will be listed here.

Abstract

Single-photon detectors based on the superconducting transition-edge sensor are used in a number of visible to near-infrared applications, particularly for photon-number-resolving measurements in quantum information science. To be practical for large-scale spectroscopic imaging or photonic quantum computing applications, the size of visible to near-infrared transition-edge sensor arrays and their associated readouts must be increased from a few pixels to many thousands. In this manuscript, we introduce the kinetic inductance current sensor, a scalable readout technology that exploits the nonlinear kinetic inductance in a superconducting resonator to make sensitive current measurements. Kinetic inductance current sensors can replace superconducting quantum interference devices for many applications because of their ability to measure fast, high slew-rate signals, their compatibility with standard microwave frequency-division multiplexing techniques, and their relatively simple fabrication. Here, we demonstrate the readout of a visible to near-infrared transition-edge sensor using a kinetic inductance current sensor with 3.7 MHz of bandwidth. We measure a readout noise of , considerably below the detector noise at frequencies of interest, and an energy resolution of (0.137 ± 0.001) eV at 0.8 eV, comparable to resolutions observed with non-multiplexed superconducting quantum interference device readouts.

Citing Articles

Kinetic inductance current sensor for visible to near-infrared wavelength transition-edge sensor readout.

Szypryt P, Bennett D, Fogarty Florang I, Fowler J, Giachero A, Hummatov R Commun Eng. 2024; 3(1):160.

PMID: 39505997 PMC: 11541868. DOI: 10.1038/s44172-024-00308-y.

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