Abstract
Non-equiatomic high-entropy alloys (HEAs), the second-generation multi-phase HEAs, have been recently reported with outstanding properties that surpass the typical limits of conventional alloys and/or the first-generation equiatomic single-phase HEAs. For magnetocaloric HEAs, non-equiatomic (Gd36Tb20Co20Al24)100−xFex microwires, with Curie temperatures up to 108 K, overcome the typical low temperature limit of rare-earth-containing HEAs (which typically concentrate lower than around 60 K). For alloys with x = 2 and 3, they possess some nanocrystals, though very minor, which offers a widening in the Curie temperature distribution. In this work, we further optimize the magnetocaloric responses of x = 3 microwires by microstructural control using the current annealing technique. With this processing method, the precipitation of nanocrystals within the amorphous matrix leads to a phase compositional difference in the microwires. The multi-phase character leads to challenges in rescaling the magnetocaloric curves, which is overcome by using two reference temperatures during the scaling procedure. The phase composition difference increases with increasing current density, whereby within a certain range, the working temperature span broadens and simultaneously offers relative cooling power values that are at least 2-fold larger than many reported conventional magnetocaloric alloys, both single amorphous phase or multi-phase character (amorphous and nanocrystalline). Among the amorphous rare-earth-containing HEAs, our work increases the working temperature beyond the typical <60 K limit while maintaining a comparable magnetocaloric effect. This demonstrates that microstructural control is a feasible way, in addition to appropriate compositional design selection, to optimize the magnetocaloric effect of HEAs.
Highlights
Solid-state magnetic cooling based on the magnetocaloric effect (MCE) has been considered as the next-generation refrigeration technology, and attracted intense research interest [1]
In previous work [20], we have found that minor Fe doping to (Gd36Tb20Co20Al24)100−xFex (x = 0–3 at%) high-entropy metallic glasses (HE-MGs) could tune the TC from 80 to 108 K, which equates to more than 60% increase than the typical limit
In this work, we studied the tuning of magnetocaloric responses of HE-MG microwires by controlling their microstructures through annealing with the current annealing technique: (Gd36Tb20Co20Al24)97Fe3 microwires were annealed by current densities of 50 × 106, 75 × 106 and 100 × 106 A m−2
Summary
Solid-state magnetic cooling based on the magnetocaloric effect (MCE) has been considered as the next-generation refrigeration technology, and attracted intense research interest [1]. In the point of view on the energy transfer between the MCE materials and their external environment under varying magnetic fields (H), there is a practical need for the solid refrigerant materials to exhibit high heat-exchange efficiency. RE-containing HEAs, especially Gd-containing high-entropy metallic glasses (HE-MGs), have received the most attention due to their excellent MCE properties [24,25,26,27,28,29] Their Curie temperatures (TC) are typically below 60 K, which further indicates that their working temperature is limited to that range as their MCE peaks around TC. MCE enhancement is found for conventional alloys exhibiting amorphous/nanocrystalline dual-phase structures [6,30,31,32,33,34,35], whereby those Gd-based compositions show an improve-
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
