A compact and tunable forward coupler based on high-impedance superconducting nanowires

TL;DR

This paper introduces a highly compact, tunable microwave forward coupler using high-impedance superconducting nanowires, suitable for integration in quantum computing systems, with adjustable coupling via bias current or temperature.

Contribution

It presents a novel ultra-compact, tunable microwave coupler based on superconducting nanowires, addressing size and integration challenges in quantum computing hardware.

Findings

Coupling ratio of -6.7 dB at 4.753 GHz with 50:50 split

Device footprint of only 416 μm²

Coupling can be tuned via bias current or temperature

Abstract

Developing compact, low-dissipation, cryogenic-compatible microwave electronics is essential for scaling up low-temperature quantum computing systems. In this paper, we demonstrate an ultra-compact microwave directional forward coupler based on high-impedance slow-wave superconducting-nanowire transmission lines. The coupling section of the fabricated device has a footprint of $416\,\mathrm{\mu m^2}$. At 4.753 GHz, the input signal couples equally to the through port and forward-coupling port (50:50) at $-6.7\,\mathrm{dB}$ with $-13.5\,\mathrm{dB}$ isolation. The coupling ratio can be controlled with DC bias current or temperature by exploiting the dependence of the kinetic inductance on these quantities. The material and fabrication-process are suitable for direct integration with superconducting circuits, providing a practical solution to the signal distribution bottlenecks in developing large-scale quantum computers.