Microwave radiometry of a quantum-critical hybrid Josephson array
Galvin KW, Bubis A, Mikalsen M, Schiela WF, Elfeky BH, Strickland WM, Phan DT, Shabani J, Higginbotham AP. 2026. Microwave radiometry of a quantum-critical hybrid Josephson array. Physical Review Applied. 26, 014031.
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Journal Article
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Scopus indexed
Author
Galvin, Kristen WISTA;
Bubis, AntonISTA;
Mikalsen, Melissa;
Schiela, William F.;
Elfeky, Bassel H.;
Strickland, William M.;
Phan, DucISTA;
Shabani, Javad;
Higginbotham, Andrew PISTA 
Corresponding author has ISTA affiliation
Abstract
Arrays of Josephson junctions can be tuned through anomalous metallic, quantum-critical, and insulating regimes. We introduce an alternative experimental probe, capturing microwave radiation across all three regimes, using a two-dimensional array of superconductor-semiconductor hybrid Josephson junctions as a model system. Our approach allows calibration of the sample’s circuit parameters and provides isolation from measurement back-action effects. We measure the radiation temperature of the anomalous metal and find that it is hotter than both the quantum-critical and insulating regimes. We further show that the anomalous metallic regime is more susceptible to additional heating than other regimes, explaining its emergence in otherwise thermalized systems. Turning to the quantum-critical regime, we discover nonlinear scaling of radiative noise with applied bias, consistent with theoretical predictions of universal nonequilibrium behavior at quantum-critical points.
Publishing Year
Date Published
2026-07-10
Journal Title
Physical Review Applied
Publisher
American Physical Society
Acknowledgement
We gratefully acknowledge feedback on the preprint
from Charles Marcus, Vadim Khrapai, Joel Moore,
Andrew Green, Shivaji Sondhi, Rufus Boyack, and
Luca Delacr´etaz. This work was primarily supported by
the NOMIS foundation. This work was partially supported
by the University of Chicago Materials Research Science
and Engineering Center, which is funded by the National
Science Foundation under Award No. DMR-2011854, and
by the SFB Q-M&S funded by the Austrian Science Fund
(FWF). We acknowledge technical support from the
Nanofabrication Facility and the MIBA machine shop at
IST Austria.
Acknowledged SSUs
Volume
26
Article Number
014031
ISSN
IST-REx-ID
Cite this
Galvin KW, Bubis A, Mikalsen M, et al. Microwave radiometry of a quantum-critical hybrid Josephson array. Physical Review Applied. 2026;26. doi:10.1103/75bl-mm3b
Galvin, K. W., Bubis, A., Mikalsen, M., Schiela, W. F., Elfeky, B. H., Strickland, W. M., … Higginbotham, A. P. (2026). Microwave radiometry of a quantum-critical hybrid Josephson array. Physical Review Applied. American Physical Society. https://doi.org/10.1103/75bl-mm3b
Galvin, Kristen W, Anton Bubis, Melissa Mikalsen, William F. Schiela, Bassel H. Elfeky, William M. Strickland, Duc T Phan, Javad Shabani, and Andrew P Higginbotham. “Microwave Radiometry of a Quantum-Critical Hybrid Josephson Array.” Physical Review Applied. American Physical Society, 2026. https://doi.org/10.1103/75bl-mm3b.
K. W. Galvin et al., “Microwave radiometry of a quantum-critical hybrid Josephson array,” Physical Review Applied, vol. 26. American Physical Society, 2026.
Galvin KW, Bubis A, Mikalsen M, Schiela WF, Elfeky BH, Strickland WM, Phan DT, Shabani J, Higginbotham AP. 2026. Microwave radiometry of a quantum-critical hybrid Josephson array. Physical Review Applied. 26, 014031.
Galvin, Kristen W., et al. “Microwave Radiometry of a Quantum-Critical Hybrid Josephson Array.” Physical Review Applied, vol. 26, 014031, American Physical Society, 2026, doi:10.1103/75bl-mm3b.
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