Page 210 - Read Online

P. 210

Yang et al. Energy Mater 2024;4:400061 https://dx.doi.org/10.20517/energymater.2023.144 Page 21 of 23

Mater 2022;12:2201866. DOI
22. Zhou Q, Dong S, Lv Z, et al. Lithium metal batteries: a temperature-responsive electrolyte endowing superior safety characteristic of
lithium metal batteries (Adv. Energy Mater. 6/2020). Adv Energy Mater 2020;10:2070023. DOI
23. Zhu GR, Zhang Q, Liu QS, et al. Non-flammable solvent-free liquid polymer electrolyte for lithium metal batteries. Nat Commun
2023;14:4617. DOI PubMed PMC
24. Yuan S, Ding K, Zeng X, et al. Advanced nonflammable organic electrolyte promises safer Li-metal batteries: from solvation structure
perspectives. Adv Mater 2023;35:e2206228. DOI
25. Liu Q, Liu R, Cui Y, et al. Dendrite-free and long-cycling lithium metal battery enabled by ultrathin, 2D shield-defensive, and single
lithium-ion conducting polymeric membrane. Adv Mater 2022;34:e2108437. DOI
26. Kim J, Engelhard MH, Lu B, et al. High current-density-charging lithium metal batteries enabled by double-layer protected lithium
metal anode. Adv Funct Mater 2022;32:2207172. DOI
27. Liang J, Chen Q, Liao X, et al. A nano-shield design for separators to resist dendrite formation in lithium-metal batteries. Angew Chem
Int Ed 2020;59:6561-6. DOI
28. Sheng O, Jin C, Yang T, Ju Z, Luo J, Tao X. Designing biomass-integrated solid polymer electrolytes for safe and energy-dense
lithium metal batteries. Energy Environ Sci 2023;16:2804-24. DOI
29. Li R, Fan Y, Zhao C, et al. Air-stable protective layers for lithium anode achieving safe lithium metal batteries. Small Methods
2023;7:e2201177. DOI
30. Huang L, Lu T, Xu G, et al. Thermal runaway routes of large-format lithium-sulfur pouch cell batteries. Joule 2022;6:906-22. DOI
31. Zhang X, Huang L, Xie B, et al. Deciphering the thermal failure mechanism of anode-free lithium metal pouch batteries. Adv Energy
Mater 2023;13:2203648. DOI
32. Chen R, Nolan AM, Lu J, et al. The thermal stability of lithium solid electrolytes with metallic lithium. Joule 2020;4:812-21. DOI
33. Wang J, Yang K, Sun S, et al. Advances in thermal-related analysis techniques for solid-state lithium batteries. InfoMat
2023;5:e12401. DOI
34. Feng X, Ren D, He X, Ouyang M. Mitigating thermal runaway of lithium-ion batteries. Joule 2020;4:743-70. DOI
35. Yang S, Hu J, Jiang F, Yuan H, Park HS, Huang J. Safer solid-state lithium metal batteries: mechanisms and strategies. InfoMat
2024;6:e12512. DOI
36. Gou J, Zhang Z, Wang S, Huang J, Cui K, Wang H. An ultrahigh modulus gel electrolytes reforming the growing pattern of Li
dendrites for interfacially stable lithium-metal batteries. Adv Mater 2024;36:e2309677. DOI
37. Cavers H, Molaiyan P, Abdollahifar M, Lassi U, Kwade A. Perspectives on improving the safety and sustainability of high voltage
lithium-ion batteries through the electrolyte and separator region. Adv Energy Mater 2022;12:2200147. DOI
38. Lee S, Park K, Koo B, et al. Safe, stable cycling of lithium metal batteries with low-viscosity, fire-retardant locally concentrated ionic
liquid electrolytes. Adv Funct Mater 2020;30:2003132. DOI
39. Zhang L, Min F, Luo Y, et al. Practical 4.4 V Li||NCM811 batteries enabled by a thermal stable and HF free carbonate-based
electrolyte. Nano Energy 2022;96:107122. DOI
40. Hu L, Wang J, Wang K, et al. A cost-effective, ionically conductive and compressible oxychloride solid-state electrolyte for stable all-
solid-state lithium-based batteries. Nat Commun 2023;14:3807. DOI PubMed PMC
41. Wang C, Xu BB, Zhang X, et al. Ion hopping: design principles for strategies to improve ionic conductivity for inorganic solid
electrolytes. Small 2022;18:e2107064. DOI
42. Zhao C, Pan Y, Li R, et al. A safe anode-free lithium metal pouch cell enabled by integrating stable quasi-solid electrolytes with
oxygen-free cathodes. Chem Eng J 2023;463:142386. DOI
43. Jia H, Onishi H, Wagner R, Winter M, Cekic-Laskovic I. Intrinsically safe gel polymer electrolyte comprising flame-retarding polymer
matrix for lithium ion battery application. ACS Appl Mater Interfaces 2018;10:42348-55. DOI PubMed
44. Liu K, Liu W, Qiu Y, et al. Electrospun core-shell microfiber separator with thermal-triggered flame-retardant properties for lithium-
ion batteries. Sci Adv 2017;3:e1601978. DOI PubMed PMC
45. Jaumaux P, Liu Q, Zhou D, et al. Deep-eutectic-solvent-based self-healing polymer electrolyte for safe and long-life lithium-metal
batteries. Angew Chem Int Ed 2020;59:9134-42. DOI
46. Son K, Hwang SM, Woo S, Paik M, Song EH, Kim Y. Thermal and chemical characterization of the solid-electrolyte interphase in
Li-ion batteries using a novel separator sampling method. J Power Sources 2019;440:227083. DOI
47. Zhang Q, Zhang X, Yuan H, Huang J. Thermally stable and nonflammable electrolytes for lithium metal batteries: progress and
perspectives. Small Science 2021;1:2100058. DOI
48. Bandhauer TM, Garimella S, Fuller TF. A critical review of thermal issues in lithium-ion batteries. J Electrochem Soc 2011;158:R1.
DOI
49. Fu C, Venturi V, Kim J, et al. Universal chemomechanical design rules for solid-ion conductors to prevent dendrite formation in
lithium metal batteries. Nat Mater 2020;19:758-66. DOI
50. Chen J, Cheng Z, Liao Y, Yuan L, Li Z, Huang Y. Selection of redox mediators for reactivating dead Li in lithium metal batteries. Adv
Energy Mater 2022;12:2201800. DOI
51. Gan Y, Liu M, Tan R, et al. Flame-retardant crosslinked polymer stabilizes graphite-silicon composite anode for self-extinguishing
lithium-ion batteries. Adv Energy Mater 2022;12:2202779. DOI
52. Tian X, Yi Y, Fang B, et al. Design strategies of safe electrolytes for preventing thermal runaway in lithium ion batteries. Chem Mater

205 206 207 208 209 210 211 212 213 214 215