@misc{li_energyefficient_elastocaloric_2018, 
author={Li, Y., Zhao, D., Liu, J., Qian, S., Gan, W., Chen, X.},
title={Energy-Efficient Elastocaloric Cooling by Flexibly and Reversibly Transferring Interface in Magnetic Shape-Memory Alloys},
year={2018},
howpublished = {journal article},
doi = {https://doi.org/10.1021/acsami.8b07703},
abstract = {Elastocaloric cooling is currently under extensive study owing to its great potential to replace the conventional vapor-compression technique. In this work, by employing multiscale characterization approaches, including in situ neutron diffraction in a loading frame, in situ transmission electron microscopy observation at different temperatures, in situ synchrotron X-ray Laue microdiffraction, and high-resolution infrared thermal imaging, we have investigated the thermal and stress-induced martensitic transformation, the stability of superelastic behavior and the associated elastocaloric effect for a Heusler-type Ni50.0Fe19.0Ga27.1Co3.9 single crystal. On the basis of transformation from cubic austenite into monoclinic martensite with a flexibly and reversibly transferring interface, this unique single crystal exhibits a giant elastocaloric effect of 11 K and ultralow fatigue behavior during above 12 000 mechanical cycles. The numerical simulation shows that the Ni50.0Fe19.0Ga27.1Co3.9 alloy offers 18% energy saving potential and 70% cooling capacity enhancement potential compared to the conventional shape-memory nitinol alloy in a single-stage elastocaloric cooling system, making it a great candidate for energy-efficient air conditioner applications.},
note = {Online available at: \url{https://doi.org/10.1021/acsami.8b07703} (DOI). Li, Y.; Zhao, D.; Liu, J.; Qian, S.; Gan, W.; Chen, X.: Energy-Efficient Elastocaloric Cooling by Flexibly and Reversibly Transferring Interface in Magnetic Shape-Memory Alloys. ACS Applied Materials and Interfaces. 2018. vol. 10, no. 30, 25438-25445. DOI: 10.1021/acsami.8b07703}}