English

Barocaloric thermal batteries

Materials Science 2021-06-23 v2 Disordered Systems and Neural Networks

Abstract

Nowadays the world is facing a prominent paradox regarding thermal energy. The production of heat accounts for more than 50% of global final energy consumption while the waste heat potential analysis reveals that 72% of the global primary energy consumption is lost after conversion mainly in the form of heat. Towards global decarbonization, it is of vital importance to establish a solution to thermal energy utilization under full control. Here, we propose and realize an unprecedented concept -- barocaloric thermal batteries based on the inverse colossal barocaloric effect of NH4SCN. Thermal charging is initialized upon pressurization through an order-to-disorder phase transition below 364 K and in turn the discharging of 43 J g-1, which are eleven times more than the input mechanical energy, occurs on demand at depressurization at lower temperatures. The discharging is also manifested as a directly measured temperature rise of 12 K. The thermodynamic equilibrium nature of the pressure-restrained heat-carrying phase guarantees stable storage and/or transport over a variety of temporal and/or spatial scales. The barocaloric thermal batteries reinforced by their solid microscopic mechanism are expected to significantly advance the ability to take advantage of waste heat.

Keywords

Cite

@article{arxiv.2103.04348,
  title  = {Barocaloric thermal batteries},
  author = {Zhe Zhang and Kuo Li and Shangchao Lin and Dehong Yu and Ruiqi Song and Yida Wang and Jingfan Wang and Shogo Kawaguchi and Zhao Zhang and Chenyang Yu and Xiaodong Li and Jie Chen and Lunhua He and Richard Mole and Bao Yuan and Qingyong Ren and Kun Qian and Zhuangli Cai and Jingui Yu and Mingchao Wang and Changying Zhao and Xin Tong and Zhidong Zhang and Bing Li},
  journal= {arXiv preprint arXiv:2103.04348},
  year   = {2021}
}

Comments

5 figures in the main text plus the Extended Data. Adiabatic-temperature-change data were added

R2 v1 2026-06-23T23:51:02.492Z