Characterization of dc SQUID damping on superconducting resonant circuits

Elizabeth C van Assendelft; Hsiao-Mei Cho; Jason Corbin; Fedja Kadribasic; Stephen E Kuenstner; Dale Li; Arran T Phipps; Nicholas M Rapidis; Maria Simanovskaia; Jyotirmai Singh; Betty Young; Kent D Irwin

Characterization of dc SQUID damping on superconducting resonant circuits

ORAL

Abstract

The high bandwidth, high dynamic range, low noise characteristics, and maturity of dc SQUIDs make them a versatile tool for a variety of precision measurements, including readout of resonant circuits in applications such as quantum information, gravitational wave detection, and dark-matter detection. The dc SQUID is a lossy active circuit with a dynamic input impedance that varies based on its detailed design, temperature, magnetic flux, current, voltage operating points, and applied feedback. Coupling a dc SQUID to a resonant circuit can modify the circuit's resonance frequency, quality factor, noise, and impedance. We present experimental measurements of dc SQUID-induced damping effects on highly coupled, lumped-element resonators in the 500kHz-1MHz regime.

March 15, 2022, 10:00 AM – March 15, 2022, 10:12 AM

Presenters

Elizabeth C van Assendelft

Stanford University

Authors

Elizabeth C van Assendelft

Stanford University
Hsiao-Mei Cho

SLAC - Natl Accelerator Lab
Jason Corbin

Stanford University
Fedja Kadribasic

Stanford Univ
Stephen E Kuenstner

Stanford Univ
Dale Li

SLAC - Natl Accelerator Lab
Arran T Phipps

California State University, East Bay
Nicholas M Rapidis

Stanford Univ
Maria Simanovskaia

University of California, Berkeley
Jyotirmai Singh

Stanford Univ
Betty Young

Santa Clara University
Kent D Irwin

Stanford Univ