F/N co-doped carbon coating on graphite for high-rate, long-cycle-life lithium-ion batteries

Open Access

Issue		Natl Sci Open Volume 5, Number 2, 2026


Article Number		20250083
Number of page(s)		12
Section		Materials Science
DOI		https://doi.org/10.1360/nso/20250083
Published online		18 January 2026

Huang Y, Wang C, Lv H, et al. Bifunctional interphase promotes Li⁺ de-solvation and transportation enabling fast-charging graphite anode at low temperature. Adv Mater 2023; 36: 2308675. [Article] [Google Scholar]
Niu M, Dong L, Yue J, et al. A fast-charge graphite anode with a Li-ion-conductive, electron/solvent-repelling interface. Angew Chem Int Ed 2024; 63: e202318663. [Article] [Google Scholar]
Zhang Q, Cui C, Chen H, et al. Surface cobaltization for boosted kinetics and excellent stability of nickel-rich layered cathodes. Natl Sci Open 2024; 3: 20240010. [Article] [Google Scholar]
Xu T, Feng H, Liu W, et al. Opportunities and challenges of high-entropy materials in lithium-ion batteries. Rare Met 2024; 43: 4884-4902. [Article] [Google Scholar]
Chen Y, Liu Y, He Z, et al. Artificial intelligence for the understanding of electrolyte chemistry and electrode interface in lithium battery. Natl Sci Open 2023; : 20230039. [Article] [Google Scholar]
Zhang SS, Ma L, Allen JL, et al. Stabilizing capacity retention of Li-ion battery in fast-charge by reducing particle size of graphite. J Electrochem Soc 2021; 168: 040519. [Article] [Google Scholar]
Zou Y, Wang Y. Microwave-assisted synthesis of porous nickel oxide nanostructures as anode materials for lithium-ion batteries. Rare Met 2011; 30: 59-62. [Article] [Google Scholar]
Tang C, Qiu Z, Li C, et al. Rational synthesis of vertical graphene supported TiN@N-Li₄Ti₅O₁₂ as advanced high-rate electrodes for lithium-ion batteries. Chin Chem Lett 2025; 36: 110589. [Article] [Google Scholar]
Liang J, Qin Z, Quan Z, et al. A review of strategies to produce a fast-charging graphite anode in lithium-ion batteries. New Carbon Mater 2025; 40: 738-764. [Article] [Google Scholar]
Su L, Gao L, Hou L, et al. Nitrogen-doped porous carbon coated on graphene sheets as anode materials for Li-ion batteries. Ionics 2018; 25: 1541-1549. [Article] [Google Scholar]
Kang SX, Lun H, Qi YX, et al. Boosted electrochemical performance of graphite anode enabled by polytetrafluoroethylene-derived F-doping. Mater Chem Phys 2021; 261: 124214. [Article] [Google Scholar]
Wang T, Tu S, Chen Y, et al. Scalable and flexible porous hybrid film as a thermal insulating subambient radiative cooler for energy-saving buildings. Natl Sci Open 2023; 2: 20220063. [Article] [Google Scholar]
Feng S, Yu Q, Ma X, et al. Hydroformylation over polyoxometalates supported single-atom Rh catalysts. Natl Sci Open 2023; 2: 20220064. [Article] [Google Scholar]
Wang JY, Lyu Y, Wei HX, et al. Constructing a simple conductive-elastic layer on graphite surfaces for high-rate and long-life lithium-ion batteries. Front Phys 2025; 20: 044207 [Google Scholar]
Zou Y, Lyu Y, Wei H, et al. A green route based on π-π interactions to coat graphite for high-rate and long-life anodes in lithium-ion batteries. Mater Rep-Energy 2025; 5: 100332. [Article] [Google Scholar]
Kaniyoor A, Ramaprabhu S. A Raman spectroscopic investigation of graphite oxide derived graphene. AIP Adv 2012; 2: 032183. [Article] [Google Scholar]
Jiao X, Qiu Y, Zhang L, et al. Comparison of the characteristic properties of reduced graphene oxides synthesized from natural graphites with different graphitization degrees. RSC Adv 2017; 7: 52337-52344. [Article] [Google Scholar]
Xiao P, Wang Z, Long K, et al. Stable cycling and low-temperature operation utilizing amorphous carbon-coated graphite anodes for lithium-ion batteries. RSC Adv 2024; 14: 13277-13285. [Article] [Google Scholar]
Bayındır O, Sohel IH, Erol M, et al. Controlling the crystallographic orientation of graphite electrodes for fast-charging Li-ion batteries. ACS Appl Mater Interfaces 2022; 14: 891-899. [Article] [Google Scholar]
Yan Y, Zhao X, Dou H, et al. Rational design of robust nano-Si/graphite nanocomposites anodes with strong interfacial adhesion for high-performance lithium-ion batteries. Chin Chem Lett 2021; 32: 910-913. [Article] [Google Scholar]
Ye S, Han S, Tian F, et al. Dynamic ion-buffering gradient bilayer anode realizes 200 Wh kg⁻¹ dendrite-free sodium battery. Natl Sci Rev 2025; 12: nwaf427. [Article] [Google Scholar]
Wang P, Qiao B, Du Y, et al. Fluorine-doped carbon particles derived from lotus petioles as high-performance anode materials for sodium-ion batteries. J Phys Chem C 2015; 119: 21336-21344. [Article] [Google Scholar]
Luo Z, Ma J, Wang X, et al. Surface engineering of fluorinated graphene nanosheets enables ultrafast lithium/sodium/potassium primary batteries. Adv Mater 2023; 35: 2303444. [Article] [Google Scholar]
Fan X, Chen L, Ji X, et al. Highly fluorinated interphases enable high-voltage Li-metal batteries. Chem 2018; 4: 174-185. [Article] [Google Scholar]
Groult H, Nakajima T, Perrigaud L, et al. Surface-fluorinated graphite anode materials for Li-ion batteries. J Fluorine Chem 2005; 126: 1111-1116. [Article] [Google Scholar]
Zhao Y, Yang L, Ma C, et al. One-step fabrication of fluorine-doped graphite derived from a low-grade microcrystalline graphite ore for potassium-ion batteries. Energy Fuels 2020; 34: 8993-9001. [Article] [Google Scholar]
Yang L, Zhao Y, Cao L, et al. Polyvinylidene fluoride-derived carbon-confined microcrystalline graphite with improved cycling life and rate performance for potassium ion batteries. Energy Fuels 2021; 35: 5308-5319. [Article] [Google Scholar]
Wu Y, Feng X, Liu X, et al. In-built ultraconformal interphases enable high-safety practical lithium batteries. Energy Storage Mater 2021; 43: 248-257. [Article] [Google Scholar]
Feng W, Long P, Feng Y, et al. Two-dimensional fluorinated graphene: Synthesis, structures, properties and applications. Adv Sci 2016; 3: 1500413. [Article] [Google Scholar]
Liu Y, Yang S, Guo H, et al. Low LUMO energy carbon molecular interface to suppress electrolyte decomposition for fast charging natural graphite anode. Energy Storage Mater 2024; 73: 103806. [Article] [Google Scholar]
Yeon SH, Jin CS, Shin KH, et al. Raising lithium-ion storage capacity by order-to-disorder transformation in MAX-derived carbon anode during cycling. Carbon 2021; 185: 681-696. [Article] [Google Scholar]
Zhang D, Li L, Zhang W, et al. Research progress on electrolytes for fast-charging lithium-ion batteries. Chin Chem Lett 2023; 34: 107122. [Article] [Google Scholar]
Chen J, Fan X, Li Q, et al. Electrolyte design for LiF-rich solid-electrolyte interfaces to enable high-performance microsized alloy anodes for batteries. Nat Energy 2020; 5: 386-397. [Article] [Google Scholar]
Wang Z, He Z, Wang Z, et al. Engineering the solid electrolyte interphase for enhancing high-rate cycling and temperature adaptability of lithium-ion batteries. Chem Sci 2025; 16: 3571-3579. [Article] [Google Scholar]
Zhang Z, Wang J, Zhang S, et al. Stable all-solid-state lithium metal batteries with Li₃N-LiF-enriched interface induced by lithium nitrate addition. Energy Storage Mater 2021; 43: 229-237. [Article] [Google Scholar]
Youn JW, Park GH, Kim M, et al. Surface modification with F-doped carbon layer coating on natural graphite anode for improving interface compatibility and electrochemical performance of lithium-ion capacitors. ACS Appl Electron Mater 2023; 5: 4344-4353. [Article] [Google Scholar]
Sun G, Zhu B, He R, et al. Synergy of F⁻ doping and fluorocarbon coating on elevating high-voltage cycling stability of NCM811 for lithium-ion batteries. Rare Met 2024; 44: 1577-1593. [Article] [Google Scholar]
Liu C, Reed S, Manthiram A. Delineating the triphasic side reaction products in high‐energy density lithium‐ion batteries. Adv Mater 2025; 37: e09889. [Article] [Google Scholar]
Zhao ZX, Bai X, Zhu HL, et al. Promoting the normal- and low-temperature performances of natural graphite by the F-doping derived from PVDF modification. ACS Appl Electron Mater 2022; 4: 4936-4946. [Article] [Google Scholar]
Hu A, Chen W, Du X, et al. An artificial hybrid interphase for an ultrahigh-rate and practical lithium metal anode. Energy Environ Sci 2021; 14: 4115-4124. [Article] [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.