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A matter of performance and criticality: A review of rare-earth-based magnetocaloric intermetallic compounds for hydrogen liquefaction

Wei Liu, Tino Gottschall, Franziska Scheibel, Eduard Bykov, Alex Aubert, Nuno M. Fortunato, Benedikt Beckmann, Allan M. Döring, Hongbin Zhang, Konstantin Skokov, Oliver Gutfleisch

2024Journal of Alloys and Compounds58 citationsDOIOpen Access PDF

Abstract

The low efficiency of conventional liquefaction technologies based on the Joule-Thomson expansion makes liquid hydrogen currently not attractive enough for large-scale energy-related technologies that are important for the transition to a carbon-neutral society. Magnetocaloric hydrogen liquefaction has great potential to achieve higher efficiency and is therefore a crucial enabler for affordable liquid hydrogen. Cost-effective magnetocaloric materials with large magnetic entropy and adiabatic temperature changes in the temperature range of 77 ~ 20 K under commercially practicable magnetic fields are the foundation for the success of magnetocaloric hydrogen liquefaction. Heavy rare-earth-based magnetocaloric intermetallic compounds generally show excellent magnetocaloric performances, but the heavy rare-earth elements (Gd, Tb, Dy, Ho, Er, and Tm) are highly critical in resources. Yttrium and light rare-earth elements (La, Ce, Pr, and Nd) are relatively abundant, but their alloys generally show less excellent magnetocaloric properties. A dilemma appears: higher performance or lower criticality? In this review, we study how cryogenic temperature influences magnetocaloric performance by first reviewing heavy rare-earth-based intermetallic compounds. Next, we look at light rare-earth-based, “mixed” rare-earth-based, and Gd-based intermetallic compounds with the nature of the phase transition order taken into consideration, and summarize ways to resolve the dilemma.

Topics & Concepts

Magnetic refrigerationIntermetallicLiquefactionMaterials scienceHydrogenThermodynamicsCondensed matter physicsMetallurgyChemistryMagnetizationAlloyPhysicsMagnetic fieldOrganic chemistryQuantum mechanicsMagnetic and transport properties of perovskites and related materialsShape Memory Alloy TransformationsHydrogen Storage and Materials