Mechanically-intermixed indium superconducting connections for microwave quantum interconnects

Abstract

Superconducting coaxial cables represent critical communication channels for interconnecting superconducting quantum processors. Here, we report mechanically-intermixed indium joins to aluminum coaxial cables for low loss quantum interconnects. We describe an ABCD matrix formalism to characterize the total resonator internal quality factor (Qi) and any contact (Rcont) or shunt resistance (Rshunt) associated with the mechanically-intermixed indium joins. We present four resonator test systems incorporating three indium join methods over the typical frequency range of interest (3-5.5GHz) at temperatures below 20mK. We measure high internal quality factor aluminum cables (Qi = 1.55 0.37 x 106) through a push-to-connect indium join of the outer conductor that capacitively couples the inner conductor for reflection measurements. We then characterize the total internal quality factors of modes of a cable resonator with a push-to-connect superconducting cable-splice at the midpoint to find mean Qi = 1.40 x 106 and Qi = 9.39 x 105 for even and odd-modes respectively and use an ABCD matrix model of the system to extract Rcont = 6x10-4 for the indium join of the inner conductor. Finally, we demonstrate indium press-mold cable-to-chip connections where the cable-to-chip join is placed at a current node and voltage node through varying on-chip waveguide lengths with mean Qi = 1.24 x 106 and Qi = 1.07 x 106 respectively to extract Rcont = 8.5x10-4 and Rshunt = 1.3x107 for the interface. With these techniques, we demonstrate a set of low-loss methods to join superconducting cables for future quantum