While transverse coupling (σx) is commonly used in qubit-resonator systems, longitudinal coupling via σz presents a tantalizing alternative: it does not hybridize the modes, eliminating Purcell decay, and it enables quantum-nondemolition qubit readout independent of the qubit-resonator frequency detuning. Here, we demonstrate longitudinal coupling between a Cr7Ni molecular spin qubit ensemble and the kinetic inductance of a granular aluminum superconducting microwave resonator. The inherent frequency independence of this coupling allows for the utilization of a 7. 8-GHz readout resonator to measure the full Cr7Ni magnetization curve spanning 0–600 mT, corresponding to a spin frequency range of fspin=0–15 GHz. For 2-GHz detuning from the readout resonator, we measure a 1/e spin relaxation time of τ=0. 38 s, limited by phonon decay to the substrate. Based on these results, we propose a path towards longitudinal coupling of single spins to a superconducting fluxonium qubit.
Günzler et al. (Thu,) studied this question.
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