Communications Physics (Jul 2023)

Interference, diffraction, and diode effects in superconducting array based on bismuth antimony telluride topological insulator

  • Xiangyu Song,
  • Soorya Suresh Babu,
  • Yang Bai,
  • Dmitry S. Golubev,
  • Irina Burkova,
  • Alexander Romanov,
  • Eduard Ilin,
  • James N. Eckstein,
  • Alexey Bezryadin

DOI
https://doi.org/10.1038/s42005-023-01288-9
Journal volume & issue
Vol. 6, no. 1
pp. 1 – 11

Abstract

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Abstract It is well-known in optics that the spectroscopic resolution of a diffraction grating is much better compared to an interference device having just two slits, as in Young’s famous double-slit experiment. On the other hand, it is well known that a classical superconducting quantum interference device (SQUID) is analogous to the optical double-slit experiment. Here we report experiments and present a model describing a superconducting analogue to the diffraction grating, namely an array of superconducting islands positioned on a topological insulator film Bi0.8Sb1.2Te3. In the limit of an extremely weak field, of the order of one vortex per the entire array, such devices exhibit a critical current peak that is much sharper than the analogous peak of an ordinary SQUID. Therefore, such arrays can be used as sensitive absolute magnetic field sensors. A key finding is that the device acts as a superconducting diode, controlled by magnetic field.