%0 Journal Article
%T An Explanation of the Temperature-Dependent Upper Critical Field Data of H3S on the Basis of the Thermodynamics of a Superconductor in a Magnetic Field
%A Gulshan Prakash Malik
%J World Journal of Condensed Matter Physics
%P 45-50
%@ 2160-6927
%D 2024
%I Scientific Research Publishing
%R 10.4236/wjcmp.2024.143005
%X Excellent fits to a couple of the data-sets on the temperature (T)-dependent upper critical field (Hc2) of H3S (critical temperature, Tc ≈ 200 K at pressure ≈ 150 GPa) reported by Mozaffari, et al. (2019) were obtained by Talantsev (2019) in an approach based on an ingenious mix of the Ginzberg-Landau (GL), the Werthamer, Helfand and Hohenberg (WHH), and the Gor’kov, etc., theories which have individually been employed for the same purpose for a long time. Up to the lowest temperature (TL) in each of these data-sets, similarly accurate fits have also been obtained by Malik and Varma (2023) in a radically different approach based on the Bethe-Salpeter equation (BSE) supplemented by the Matsubara and the Landau quantization prescriptions. For T < TL, however, while the (GL, WHH, etc.)-based approach leads to Hc2(0) ≈ 100 T, the BSE-based approach leads to about twice this value even at 1 K. In this paper, a fit to one of the said data-sets is obtained for the first time via a thermodynamic approach which, up to TL, is as good as those obtained via the earlier approaches. While this is interesting per se, another significant result of this paper is that for T < TL it corroborates the result of the BSE-based approach.
%K H3S
%K Upper Critical Field (Hc2)
%K Variation of Hc2 with Temperature
%K Clausius-Clapeyron equation in a magnetic field
%K Behavior of Hc2 for Temperatures Close to 0 K
%U http://www.scirp.org/journal/PaperInformation.aspx?PaperID=134300