Crystal electric field level scheme leading to giant magnetocaloric effect for hydrogen liquefaction
Noriki Terada, Hiroaki Mamiya, Hiraku Saito, Taro Nakajima, Takafumi D. Yamamoto, Kensei Terashima, Hiroyuki Takeya, Osamu Sakai, Shinichi Itoh, Yoshihiko Takano, Masashi Hase, Hideaki Kitazawa
Abstract
Abstract In recent years, magnetic refrigeration has attracted considerable attention for hydrogen liquefaction. Most materials used for magnetic refrigeration contain heavy rare earth ions with complex crystalline electric field energy splittings, whose effect on the magnetic entropy change Δ S M has not been systematically studied. In particular, the theoretical upper limits of ∣Δ S M ∣ for general heavy earth cases are unknown. Here, we show that the crystalline electric field level schemes result in a large Δ S M for general heavy rare earth cases. We provide a specific example of the magnetic refrigeration material HoB 2 using inelastic neutron scattering experiments combined with mean-field calculations with crystal field splitting and exchange interactions. The relationship between Δ S M and crystal field parameters presented in this study can be useful for developing compounds with a large ∣Δ S M ∣ and advancing the design of magnetic refrigeration materials.