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Dendrite-Free and Stable Lithium Metal Anodes Enabled by an Antimony-Based Lithiophilic Interphase. Tao Chen, Weihua Kong, Peiyang Zhao, Huinan Lin, Yi Hu, Renpeng Chen, Wen Yan, Zhong Jin.Ti3C2Tx MXene Interface Layer Driving Ultra-Stable Lithium-Iodine Batteries with Both High Iodine Content and Mass Loading. Chuang Sun, Xinlei Shi, Yabo Zhang, Jiajie Liang, Jie Qu, Chao Lai.Electrode Degradation in Lithium-Ion Batteries. Pender, Gaurav Jha, Duck Hyun Youn, Joshua M. Carbon-Based Fibers for Advanced Electrochemical Energy Storage Devices. Shaohua Chen, Ling Qiu, Hui-Ming Cheng.ACS Sustainable Chemistry & Engineering 2020, 8 High-Voltage and Ultrastable Aqueous Zinc–Iodine Battery Enabled by N-Doped Carbon Materials: Revealing the Contributions of Nitrogen Configurations. Donglin Yu, Anuj Kumar, Tuan Anh Nguyen, M.Anchoring Polyiodide to Conductive Polymers as Cathode for High-Performance Aqueous Zinc–Iodine Batteries. Xiaomin Zeng, Xiangjuan Meng, Wei Jiang, Jie Liu, Min Ling, Lijing Yan, Chengdu Liang.ACS Applied Materials & Interfaces 2021, 13

Trifunctional Electrolyte Additive Hexadecyltrioctylammonium Iodide for Lithium–Sulfur Batteries with Extended Cycle Life. Yujue Wang, Yan Meng, Zhaokun Zhang, Yong Guo, Dan Xiao.Hierarchically Porous Metal–Organic Gel Hosting Catholyte for Limiting Iodine Diffusion and Self-Discharge Control in Sustainable Aqueous Zinc–I2 Batteries. Encapsulation of Iodine in Nitrogen-Containing Porous Carbon Plate Arrays on Carbon Fiber Cloth as a Freestanding Cathode for Lithium-Iodine Batteries. ACS Sustainable Chemistry & Engineering 2021, 9 High-Energy Density Aqueous Zinc–Iodine Batteries with Ultra-long Cycle Life Enabled by the ZnI2 Additive. Chaojie Chen, Zhiwei Li, Yinghong Xu, Yufeng An, Langyuan Wu, Yao Sun, Haojie Liao, Kejun Zheng, Xiaogang Zhang.ACS Applied Materials & Interfaces 2022, 14 Advanced Zn–I2 Battery with Excellent Cycling Stability and Good Rate Performance by a Multifunctional Iodine Host. Weifang Liu, Penggao Liu, Yanhong Lyu, Jie Wen, Rui Hao, Jianyun Zheng, Kaiyu Liu, Yong-Jun Li, Shuangyin Wang.The Journal of Physical Chemistry C 2022, 126 Six-Electron Reduction of LiIO3 to LiOH in Aprotic Solvents and Implications for Li–O2 Batteries. Graham Leverick, Yun Guang Zhu, Sarah Lohmar, Fanny Bardé, Stéphane Cotte, Yang Shao-Horn.Rechargeable Iodine Batteries: Fundamentals, Advances, and Perspectives. Shuo Yang, Xun Guo, Haiming Lv, Cuiping Han, Ao Chen, Zijie Tang, Xinliang Li, Chunyi Zhi, Hongfei Li.This article is cited by 145 publications. The use of nanoporous carbon to adsorb iodine at room-temperature represents a new and promising direction for realizing high-performance cathode for rechargeable Li-iodine batteries. For the demonstration of application, soft-package batteries with Al-plastic film were assembled, displaying energy densities of 475 Wh/kg by mass of Li and iodine, and 136 Wh/kg by total mass of the battery. The reversible reactions of I 2/LiI 3 and LiI 3/LiI in Li-iodine batteries were also proved with in situ Raman measurement. Meanwhile, Li-iodine batteries constructed by the as-prepared cathode and ether-based electrolyte with the addition of LiNO 3 showed negligible self-discharge reaction, high rate and long cycling performance. Herein, we designed a room-temperature “solution-adsorption” method to prepare a thermostable iodine–carbon cathode by utilizing the strong adsorption of nanoporous carbon. However, the safety risk caused by low thermostability of iodine and the self-discharge reaction due to high solvency of iodine in aprotic solvent are target issues to be considered. Rechargeable Li-iodine batteries are attractive electrochemical energy storage systems because iodine cathode provides the possibility of high energy density, wide abundance and low cost.