| Literature DB >> 25785550 |
Jie Xiao1, Jian Zhi Hu1, Honghao Chen1, M Vijayakumar1, Jianming Zheng1, Huilin Pan1, Eric D Walter1, Mary Hu1, Xuchu Deng1, Ju Feng1, Bor Yann Liaw2, Meng Gu1, Zhiqun Daniel Deng1, Dongping Lu1, Suochang Xu1, Chongmin Wang1, Jun Liu1.
Abstract
A fundamental understanding of electrochemical reaction pathways is critical to improving the performance of Li-S batteries, but few techniques can be used to directly identify and quantify the reaction species during disharge/charge cycling processes in real time. Here, an in situ (7)Li NMR technique employing a specially designed cylindrical microbattery was used to probe the transient electrochemical and chemical reactions occurring during the cycling of a Li-S system. In situ NMR provides real time, semiquantitative information related to the temporal evolution of lithium polysulfide allotropes during both discharge/charge processes. This technique uniquely reveals that the polysulfide redox reactions involve charged free radicals as intermediate species that are difficult to detect in ex situ NMR studies. Additionally, it also uncovers vital information about the (7)Li chemical environments during the electrochemical and parasitic reactions on the Li metal anode. These new molecular-level insights about transient species and the associated anode failure mechanism are crucial to delineating effective strategies to accelerate the development of Li-S battery technologies.Entities:
Keywords: Li−S batteries; energy storage; in situ NMR; radicals
Year: 2015 PMID: 25785550 DOI: 10.1021/acs.nanolett.5b00521
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189