Materials Today Energy

Thermoelectric data of Zn(1-x)CdxSb solid solutions

XR,SEM,TEM,XPS and OER data are included in this file

Supporting data for TiO2 nanopowder as a high rate, long cycle life electrode in aqueous aluminium electrolyte.

A rapid (5-second) sulfur deposition technique is demonstrated on electrospun carbon nanofibers to fabricate binder-free, freestanding cathodes for lithium-sulfur batteries. The 5-second procedure melts sulfur into carbon nanofiber mats, which play a significant role as a built-in conductive matrix to provide uninterrupted electron transport pathways throughout the electrode such that the heavy current collector is eliminated. Meanwhile, the large inter-fiber spacing facilitates electrolyte diffusion and provides sufficient space for sulfur integration during cathode fabrication and the volume expansion during lithium-sulfur redox reaction. This technique eliminates the need for slurry processing with insulating binders and toxic solvents as well as eliminating heavy current collectors. This ultra-rapid technique involving only 140 °C, 5 s, and slight pressure (< 250 psi) offers a practical approach to light-weight sulfur cathodes compared to the conventional sulfur melt deposition techniques requiring high temperatures (155 - 300 °C), long times (8 - 10 h), and heavy components in the cell assembly. The cathodes thus obtained deliver a discharge capacity of ~ 550 mA h gsulfur-1 owing to their simple construction, with 100% capacity retention at 0.5C rate over 150 cycles. This translates to ~250 mA h gelectrode-1 (based on total mass at the cathode) which is comparable to highly sophisticated electrodes when the weight of the entire electrode and current collector is considered.

Related Article: Peng Tao, Xiao-Kang Zheng, Xiao-Zhen Wei, Mei-Tung Lau, Yuk-Ki Lee, Zi-Kang Li, Ze-Ling Guo, Fang-Qing Zhao, Xing Liu, Shu-Juan Liu, Qiang Zhao, Yan-Qin Miao, Wai-Yeung Wong|2021|Mat.Today.Energy|21|100773|doi:10.1016/j.mtener.2021.100773

Related Article: Peng Tao, Xiao-Kang Zheng, Xiao-Zhen Wei, Mei-Tung Lau, Yuk-Ki Lee, Zi-Kang Li, Ze-Ling Guo, Fang-Qing Zhao, Xing Liu, Shu-Juan Liu, Qiang Zhao, Yan-Qin Miao, Wai-Yeung Wong|2021|Mat.Today.Energy|21|100773|doi:10.1016/j.mtener.2021.100773

Related Article: Chen Cao, Guo-Xi Yang, Ji-Hua Tan, Dong Shen, Wen-Cheng Chen, Jia-Xiong Chen, Jian-Li Liang, Ze-Lin Zhu, Shi-Hao Liu, Qing-Xiao Tong, Chun-Sing Lee|2021|Mat.Today.Energy|21|100727|doi:10.1016/j.mtener.2021.100727

Related Article: Chen Cao, Guo-Xi Yang, Ji-Hua Tan, Dong Shen, Wen-Cheng Chen, Jia-Xiong Chen, Jian-Li Liang, Ze-Lin Zhu, Shi-Hao Liu, Qing-Xiao Tong, Chun-Sing Lee|2021|Mat.Today.Energy|21|100727|doi:10.1016/j.mtener.2021.100727

Related Article: S.L. Zhang, Y.Z. Shi, K. Wang, X.C. Fan, J. Yu, X.M. Ou, X.H. Zhang|2021|Mat.Today.Energy||100581|doi:10.1016/j.mtener.2020.100581

Related Article: Chen Cao, Guo-Xi Yang, Ji-Hua Tan, Dong Shen, Wen-Cheng Chen, Jia-Xiong Chen, Jian-Li Liang, Ze-Lin Zhu, Shi-Hao Liu, Qing-Xiao Tong, Chun-Sing Lee|2021|Mat.Today.Energy|21|100727|doi:10.1016/j.mtener.2021.100727