Detecting half-quantum superconducting vortices by spin-qubit relaxometry
Abstract
Half-quantum vortices in spin-triplet superconductors are predicted to harbor Majorana zero modes and may provide a viable avenue to topological quantum computation. Here, we introduce a novel approach for directly measuring the half-integer-quantized magnetic fluxes, , carried by such half-quantum vortices via spin-qubit relaxometry. We consider a superconducting strip with a narrow pinch point at which vortices cross quasi-periodically below a spin qubit as a result of a bias current. We demonstrate that the relaxation rate of the spin qubit exhibits a pronounced peak if the vortex-crossing frequency matches the transition frequency of the spin qubit and conclude that the magnetic flux of a single vortex can be obtained by dividing the corresponding voltage along the strip with the transition frequency. We discuss experimental constraints on implementing our proposed setup in spin-triplet candidate materials like UTe, UPt, and URhGe.
Cite
@article{arxiv.2601.19975,
title = {Detecting half-quantum superconducting vortices by spin-qubit relaxometry},
author = {Gábor B. Halász and Nirjhar Sarkar and Yueh-Chun Wu and Joshua T. Damron and Chengyun Hua and Benjamin Lawrie},
journal= {arXiv preprint arXiv:2601.19975},
year = {2026}
}
Comments
5 pages, 4 figures