English

Ferromagnetic insulator-based superconducting junctions as sensitive electron thermometers

Mesoscale and Nanoscale Physics 2015-10-28 v3 Superconductivity

Abstract

We present an exhaustive theoretical analysis of charge and thermoelectric transport in a normal metal-ferromagnetic insulator-superconductor (NFIS) junction, and explore the possibility of its use as a sensitive thermometer. We investigated the transfer functions and the intrinsic noise performance for different measurement configurations. A common feature of all configurations is that the best temperature noise performance is obtained in the non-linear temperature regime for a structure based on an europium chalcogenide ferromagnetic insulator in contact with a superconducting Al film structure. For an open-circuit configuration, although the maximal intrinsic temperature sensitivity can achieve 1010nKHz1/2^{-1/2}, a realistic amplifying chain will reduce the sensitivity up to 1010μ\muKHz1/2^{-1/2}. To overcome this limitation we propose a measurement scheme in a closed-circuit configuration based on state-of-art SQUID detection technology in an inductive setup. In such a case we show that temperature noise can be as low as 3535nKHz1/2^{-1/2}. We also discuss a temperature-to-frequency converter where the obtained thermo-voltage developed over a Josephson junction operated in the dissipative regime is converted into a high-frequency signal. We predict that the structure can generate frequencies up to 120\sim 120GHz, and transfer functions up to 200200GHz/K at around 1\sim 1K. If operated as electron thermometer, the device may provide temperature noise lower than 3535nKHz1/2^{-1/2} thereby being potentially attractive for radiation sensing applications.

Keywords

Cite

@article{arxiv.1502.07548,
  title  = {Ferromagnetic insulator-based superconducting junctions as sensitive electron thermometers},
  author = {F. Giazotto and P. Solinas and A. Braggio and F. S. Bergeret},
  journal= {arXiv preprint arXiv:1502.07548},
  year   = {2015}
}

Comments

11 pages, 10 color figures

R2 v1 2026-06-22T08:38:46.703Z