Synergistic Regulation of Intrinsic Lithiophilicity and Mass Transport Kinetics of Non-Lithium-Alloying Nucleation Sites for Stable Operation of Low N/P Ratio Lithium Metal Batteries
- Authors
- Bae, Minjun; Park, Sung-Joon; Kim, Minki; Kwon, Eunji; Yu, Seungho; Choi, Juhyung; Chang, Yujin; Kim, Yonghwan; Choi, Yoon Jeong; Hong, Hwichan; Lin, Liwei; Zhang, Wang; Park, Seungman; Maeng, Ji Young; Park, Jungjin; Lee, Seung-Yong; Yu, Seung-Ho; Piao, Yuanzhe
- Issue Date
- May-2024
- Publisher
- Wiley-VCH Verlag
- Keywords
- intrinsic lithiophilicity; lithium metal battery; low N/P ratio; mass transport kinetic; synergistic regulation
- Citation
- Advanced Energy Materials, v.14, no.17, pp 1 - 19
- Pages
- 19
- Indexed
- SCIE
SCOPUS
- Journal Title
- Advanced Energy Materials
- Volume
- 14
- Number
- 17
- Start Page
- 1
- End Page
- 19
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/197813
- DOI
- 10.1002/aenm.202304101
- ISSN
- 1614-6832
1614-6840
- Abstract
- Constructing functional materials on a 3D host is an efficient strategy to tackle issues of lithium (Li) metal anodes. Although non-Li-alloying materials provide structural stability during cycling due to reduced lattice distortions, low lithiophilicity and sluggish mass transport kinetics limit their functionality. Herein, a synergistic strategy is proposed to improve intrinsic lithiophilicity and mass transport kinetics of non-Li-alloying nucleation sites and demonstrate its remarkable efficacy. Two carbon fiber (CF) hosts coated by non-Li-alloying nanosheets with and without oxygen-enriched carbon filler (OCF) as lithiophilicity and mass transport booster (OCF-DSC@CF and DSC@CF, respectively) are constructed and their physiochemical properties are systematically evaluated to reveal the efficacy of OCF. By advanced characterization techniques, including 3D tomography and location-dependent electron energy loss spectroscopies, the complex heterostructure of OCF-DSC@CF with distinctive roles of each constituent is clearly identified. As verified by theoretical and electrochemical analyses, the incorporation of OCF endows OCF-DSC@CF with substantially improved lithiophilicity and mass transport kinetics. Moreover, OCF-DSC@CF induces a multifunctional SEI enriched with LiF and LiCx, which exhibits well-balanced electrical resistivity and ionic conductivity. Benefiting from these attributes, OCF-DSC@CF exhibits an unprecedented cyclability under a low N/P ratio of 1.8, achieving 700 cycles at 0.5C with an exceptional capacity retention of 97.8%.
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