| Literature DB >> 36161954 |
Jingwen Zhou1,2,3, Tianshuai Wang4, Lin Chen3, Lingwen Liao1, Yunhao Wang1, Shibo Xi5, Bo Chen1, Ting Lin6,7, Qinghua Zhang6,7, Chenliang Ye8, Xichen Zhou1, Zhiqiang Guan1, Li Zhai1,2, Zhen He1,2, Gang Wang9, Juan Wang1, Jinli Yu1, Yangbo Ma1, Pengyi Lu1,2, Yuecheng Xiong1, Shiyao Lu1, Ye Chen9, Bin Wang10, Chun-Sing Lee1,11, Jianli Cheng3, Lin Gu6,7, Tianshou Zhao4, Zhanxi Fan1,2,12.
Abstract
Given the high energy density and eco-friendly characteristics, lithium-carbon dioxide (Li-CO2) batteries have been considered to be a next-generation energy technology to promote carbon neutral and space exploration. However, Li-CO2 batteries suffer from sluggish reaction kinetics, causing large overpotential and poor energy efficiency. Here, we observe enhanced reaction kinetics in aprotic Li-CO2 batteries with unconventional phase 4H/face-centered cubic (fcc) iridium (Ir) nanostructures grown on gold template. Significantly, 4H/fcc Ir exhibits superior electrochemical performance over fcc Ir in facilitating the round-trip reaction kinetics of Li+-mediated CO2 reduction and evolution, achieving a low charge plateau below 3.61 V and high energy efficiency of 83.8%. Ex situ/in situ studies and theoretical calculations reveal that the boosted reaction kinetics arises from the highly reversible generation of amorphous/low-crystalline discharge products on 4H/fcc Ir via the Ir-O coupling. The demonstration of flexible Li-CO2 pouch cells with 4H/fcc Ir suggests the feasibility of using unconventional phase nanomaterials in practical scenarios.Entities:
Keywords: Ir nanostructures; Li-CO2 battery; electrochemical mechanism; reaction kinetics; unconventional phase
Year: 2022 PMID: 36161954 PMCID: PMC9546633 DOI: 10.1073/pnas.2204666119
Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN: 0027-8424 Impact factor: 12.779