Journal Article10.1038/NMAT2731
Giant solid-state barocaloric effect in the Ni-Mn-In magnetic shape-memory alloy
Lluís Mañosa,David González-Alonso,Antoni Planes,Erell Bonnot,Maria Barrio,Josep-Lluís Tamarit,Seda Aksoy,Mehmet Acet +7 more
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TL;DR: It is shown that the application of a moderate hydrostatic pressure to a magnetic shape-memory alloy gives rise to a caloric effect with a magnitude that is comparable to the giant magnetocaloric effect reported in this class of materials.
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Abstract: The search for materials showing large caloric effects close to room temperature has become a challenge in modern materials physics and it is expected that such a class of materials will provide a way to renew present cooling devices that are based on the vapour compression of hazardous gases. Up to now, the most promising materials are giant magnetocaloric materials. The discovery of materials showing a giant magnetocaloric effect at temperatures close to ambient has opened up the possibility of using them for refrigeration. As caloric effects refer to the isothermal entropy change achieved by application of an external field, several caloric effects can take place on tuning different external parameters such as pressure and electric field. Indeed the occurrence of large electrocaloric and elastocaloric effects has recently been reported. Here we show that the application of a moderate hydrostatic pressure to a magnetic shape-memory alloy gives rise to a caloric effect with a magnitude that is comparable to the giant magnetocaloric effect reported in this class of materials. We anticipate that similar barocaloric effects will occur in many giant-magnetocaloric materials undergoing magnetostructural transitions involving a volume change.
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Citations
Achieving a broad refrigeration temperature region through the combination of successive caloric effects in a multiferroic Ni50Mn35In15 alloy
Zhenzhuang Li,Zongbin Li,Dong Li,Jiajing Yang,Bo Yang,Yong Hu,Dunhui Wang,Yudong Zhang,Claude Esling,Xiang Zhao,Liang Zuo +10 more
TL;DR: In this paper, the authors demonstrate that various caloric effects can be achieved successively in a multiferroic Ni50Mn35In15 meta-magnetic shape memory alloy prepared by directional solidification.
101
Reversible adiabatic temperature changes at the magnetocaloric and barocaloric effects in Fe49Rh51
Enric Stern-Taulats,Adrià Gràcia-Condal,Antoni Planes,Pol Lloveras,Maria Barrio,Josep-Lluís Tamarit,S. Pramanick,Subham Majumdar,Lluís Mañosa +8 more
TL;DR: In this paper, the adiabatic temperature changes associated with the magnetocaloric and barocaloric effects in a Fe49Rh51 alloy were investigated and the agreement between the two sets of data provided support to the estimation of ΔT for the barocalory effect, which were indirectly determined from entropy curves.
Caloric Effects in Perovskite Oxides
Abstract: Perovskite oxides show an amazing diversity of electronic and magnetic properties along with a myriad of structural variants and phase transitions. Large thermal changes may be driven near the ferroic phase transitions in perovskite oxides using magnetic, electric, and stress fields to manipulate conjugate order parameters. The ensuing magnetocaloric, electrocaloric, and mechanocaloric effects can be utilized for environment‐friendly and high‐efficiency solid‐state cooling applications. In this review the details of these caloric effects in perovskite oxides both from a chronological perspective and from the viewpoint of the recent advances in multiple caloric phenomena are described. The authors highlight the role of interfaces in oxide thin films for the different caloric effects and address some of the outstanding challenges for the fundamental understanding and practical implementation of perovskite oxides in solid state refrigeration.
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High-performance multimode elastocaloric cooling system
Suxin Qian,David Catalini,Jan Muehlbauer,Boyang Liu,Huilong Hou,Yunho Hwang,Reinhard Radermacher,Ichiro Takeuchi +7 more
TL;DR: In this article , the authors developed an elastocaloric cooling system with a maximum cooling power of 260 watts and a maximum temperature span of 22.5 kelvin, which is among the highest reported for any caloric cooling system.
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Giant room-temperature elastocaloric effect in ferroelectric ultrathin films.
Yang Liu,Yang Liu,Ingrid C. Infante,Xiaojie Lou,Laurent Bellaiche,James F. Scott,Brahim Dkhil +6 more
TL;DR: An ideal refrigeration cycle with high performance (temperature change over 10 K with a wide working-temperature window of 60 K) at room temperature is proposed for future cooling applications.
98
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Karl A. Gschneidner
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