Recent development of magnetocaloric effect in Pyrochlore oxides

TL;DR

This paper reviews recent progress in magnetocaloric effect research within pyrochlore oxides, highlighting their complex magnetic states, potential for magnetic cooling, and the need for further exploration of different phases and compounds.

Contribution

It provides a comprehensive overview of the magnetocaloric effect in pyrochlore oxides, emphasizing new findings and the diversity of magnetic behaviors in these materials.

Findings

ErMnO exhibits the largest conventional MCE at 5 T

YIrCrO shows coexistence of conventional and inverse MCE

Phase crystallization depends on synthesis conditions

Abstract

In recent years, solid state magnetic cooling based on magnetocaloric effect (MCE) have drawn attention worldwide as a promising alternative potential candidate to the conventional gas compression-expansion cooling technique. In this chapter, the current developments of MCE in pyrochlore oxide materials is presented. The interaction between magnetic frustration, strong spin-orbit coupling, electronic correlations and crystal electric field lead to various complex magnetic states in pyrochlore oxides gives a broad template to explore these materials in MCE point of view. Pyrochlore oxides show strong frustration due to its crystal structure. Thus, the study of MCE in pyrochlore oxides could be fascinating not only from the an applications point of view but as well as from fundamental point of view. Among all the compounds, cubic pyrochlore oxide ErMnO exhibit largest conventional MCE value at change of field 5 T. On the other hand, YIrCrO series show coexistence of conventional MCE and inverse MCE which is absent in whole reported family of pyrochlore oxides. It is worth mention that depending on synthesis condition A2Mn2O7 series crystallizes in either cubic pyrochlore phase (Fd-3m) or monoclinic layered perovskite (P2M). It suggests the need of more materials to be explore experimentally and theoretically to establish the connection between these two phases.