posted on 2021-07-30, 15:38authored byHong Zhang, Xiaofang Liu, Jiacheng Wang, Bin Zhang, Jie Chen, Lei Yang, Guoyu Wang, Meng Li, Yujie Zheng, Xiaoyuan Zhou, Guang Han
The
exploration of materials with multifunctional properties, such
as energy harvesting and storage, is crucial in integrated energy
devices and technologies. Herein, through an organic-free “soft
chemical” solution method, a series of dual-functional SnSe1–xSx (x = 0, 0.1, 0.2, 0.3, 0.4, and 0.5) nanoparticles have been
developed toward high-performance electrochemical energy storage and
thermoelectric conversion. Among the synthesized S-substituted SnSe,
SnSe0.5S0.5 exhibits the highest rate capacity
(546.1 mA h g–1 at 2 A g–1) and
the best reversible capacity (556.2 mA h g–1 at
0.1 A g–1 after 100 cycles), which are much enhanced
compared to those of SnSe. Density functional theory calculation confirms
that the composition regulation by S substitution can lower the diffusion
barrier of Li+, boost the diffusion rate of Li+, and in turn enhance the electrochemical kinetics, thus increasing
the Li+ storage performance. Meanwhile, partially replacing
Se by S decreases the lattice thermal conductivity, leading to an
improved peak zT of 0.64 at 773 K in SnSe0.9S0.1, which is enhanced compared to the value for SnSe
obtained at the same temperature. This study develops a combined composition
tuning-nanostructuring approach for optimizing the electrochemical
and thermoelectric performance of dual-functional SnSe.