English

Chip-Integrated Vortex Manipulation

Superconductivity 2023-06-07 v1

Abstract

Abrikosov Vortices have long been considered as means to encode classical information in low-temperature logic circuits (1) and memory devices (2-4). Although it is possible to control individual vortices using local probes (5-11), scalability towards the control of of multiple vortices remains challenging. Vortex logic devices require means to shuttle selected vortices reliably over long distances between engineered pinning potentials. Concomitantly, all other vortices should remains fixed to their precise locations. Here we demonstrate such capabilities using Nb loops patterned below a NbSe2_2 layer. SQUID-on-Tip (SOT) microscopy reveals that the loops can position vortices in sites designated to a precision better than 100 nm; they can realize "push" and "pull" operations of vortices as far as 3μ\mum. Successive application of such operations shuttles a vortex between adjacent loops. Our results may be used as means to integrate vortices in future quantum circuitry. Strikingly, we are able to demonstrate a winding operation. Such winding, if realized in topological superconductors, is considered an essential part of future topological quantum information processing (12-17).

Keywords

Cite

@article{arxiv.2212.06171,
  title  = {Chip-Integrated Vortex Manipulation},
  author = {Itai Keren and Alon Gutfreund and Avia Noah and Nofar Friedman and Angelo Di Bernardo and Hadar Steinberg and Yonathan Anahory},
  journal= {arXiv preprint arXiv:2212.06171},
  year   = {2023}
}
R2 v1 2026-06-28T07:31:39.494Z