Free-spin dominated magnetocaloric effect in dense Gd$^{3+}$ double perovskites

TL;DR

This study explores dense Gd-based double perovskites with frustrated lattices, demonstrating significant magnetocaloric effects driven by free spins and minimal superexchange, with potential for cryogenic refrigeration applications.

Contribution

It reports new Gd double perovskite compounds with enhanced magnetocaloric effects and analyzes their magnetic properties, highlighting the role of free spins in cooling performance.

Findings

Gd compounds show up to -15.8 J/K/mol Gd entropy change at 2 K in 7 T

Lack of magnetic ordering down to 0.4 K suggests effective cryogenic cooling

Mean-field model links free spin behavior to high magnetocaloric performance

Abstract

Frustrated lanthanide oxides with dense magnetic lattices are of fundamental interest for their potential in cryogenic refrigeration due to a large ground state entropy and suppressed ordering temperatures, but can often be limited by short-range correlations. Here, we present examples of frustrated fcc oxides, Ba$_2$GdSbO$_6$ and Sr$_2$GdSbO$_6$ and the new site-disordered analog Ca$_2$GdSbO$_6$ ([CaGd]$_A$[CaSb]$_B$O$_6$), in which the magnetocaloric effect is influenced by minimal superexchange ($J_1 \sim 10$ mK). We report on the crystal structures using powder x-ray diffraction and the bulk magnetic properties through low-field susceptibility and isothermal magnetization measurements. The Gd compounds exhibit a magnetic entropy change of up to -15.8 J/K/mol$_\textrm{Gd}$ in a field of 7 T at 2 K, a 20 % excess compared to the value of -13.0 J/K/mol$_\textrm{Gd}$ for a standard in magnetic refrigeration, Gd$_3$Ga$_5$O$_{12}$. Heat capacity measurements indicate a lack of magnetic ordering down to 0.4 K for Ba$_2$GdSbO$_6$ and Sr$_2$GdSbO$_6$, suggesting cooling down through the liquid 4-He regime. A mean-field model is used to elucidate the role of primarily free spin behavior in the magnetocaloric performance of these compounds in comparison to other top-performing Gd-based oxides. The chemical flexibility of the double perovskites raises the possibility of further enhancement of the magnetocaloric effect in the Gd$^{3+}$ fcc lattices.