Microwave dual-mode resonators for coherent spin-photon coupling

TL;DR

This paper demonstrates superconducting dual-mode resonators with tunable frequencies that enable coherent coupling with spin ensembles, advancing quantum information processing capabilities.

Contribution

It introduces superconducting YBCO resonators with two modes for enhanced spin-photon interaction in circuit QED experiments.

Findings

Achieved tunable resonant microwave frequencies.

Observed coherent spin-photon coupling with two modes.

Demonstrated spin-induced mixing of photon modes.

Abstract

We implement superconducting YBCO planar resonators with two fundamental modes for circuit quantum electrodynamics experiments. We first demonstrate good tunability in the resonant microwave frequencies and in their interplay as it emerges from the dependence of the transmission spectra on the device geometry. We then investigate the magnetic coupling of the resonant modes with bulk samples of DPPH organic radical spins. The transmission spectroscopies performed at low temperature show that the coherent spin-photon coupling regime with the spin ensembles can be achieved by each of the resonator modes. The analysis of the results within the framework of the Input-Output formalism and by means of entropic measures demonstrates coherent mixing of the degrees of freedom corresponding to two remote spin ensembles and, with a suitable choice of the geometry, the approaching of a regime with spin-induced mixing of the two photon modes.