Fluorine-Doped High-Performance Li6PS5Cl Electrolyte by Lithium Fluoride Nanoparticles for All-Solid-State Lithium-Metal Batteries

Xiaorou Cao; Shijie Xu; Yuzhe Zhang; Xiaohu Hu; Yifan Yan; Yanru Wang; Haoran Qian; Jiakai Wang; Haolong Chang; Fangyi Cheng; Yongan Yang

doi:10.1007/s12209-024-00394-1

Transactions of Tianjin University ›› 2024, Vol. 30 ›› Issue (3) : 250 -261. DOI: 10.1007/s12209-024-00394-1

Research Article

Fluorine-Doped High-Performance Li₆PS₅Cl Electrolyte by Lithium Fluoride Nanoparticles for All-Solid-State Lithium-Metal Batteries

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Abstract

All-solid-state lithium-metal batteries (ASSLMBs) are widely considered as the ultimately advanced lithium batteries owing to their improved energy density and enhanced safety features. Among various solid electrolytes, sulfide solid electrolyte (SSE) Li₆PS₅Cl has garnered significant attention. However, its application is limited by its poor cyclability and low critical current density (CCD). In this study, we introduce a novel approach to enhance the performance of Li₆PS₅Cl by doping it with fluorine, using lithium fluoride nanoparticles (LiFs) as the doping precursor. The F-doped electrolyte Li₆PS₅Cl-0.2LiF(nano) shows a doubled CCD, from 0.5 to 1.0 mA/cm² without compromising the ionic conductivity; in fact, conductivity is enhanced from 2.82 to 3.30 mS/cm, contrary to the typical performance decline seen in conventionally doped Li₆PS₅Cl electrolytes. In symmetric Li|SSE|Li cells, the lifetime of Li₆PS₅Cl-0.2LiF(nano) is 4 times longer than that of Li₆PS₅Cl, achieving 1500 h vs. 371 h under a charging/discharging current density of 0.2 mA/cm². In Li|SSE|LiNbO₃@NCM721 full cells, which are tested under a cycling rate of 0.1 C at 30 °C, the lifetime of Li₆PS₅Cl-0.2LiF(nano) is four times that of Li₆PS₅Cl, reaching 100 cycles vs. 26 cycles. Therefore, the doping of nano-LiF offers a promising approach to developing high-performance Li₆PS₅Cl for ASSLMBs.

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Sulfide solid electrolyte / All-solid-state lithium batteries / Li₆PS₅Cl / Lithium fluoride / F-doping

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Xiaorou Cao, Shijie Xu, Yuzhe Zhang, Xiaohu Hu, Yifan Yan, Yanru Wang, Haoran Qian, Jiakai Wang, Haolong Chang, Fangyi Cheng, Yongan Yang. Fluorine-Doped High-Performance Li₆PS₅Cl Electrolyte by Lithium Fluoride Nanoparticles for All-Solid-State Lithium-Metal Batteries. Transactions of Tianjin University, 2024, 30(3): 250-261 DOI:10.1007/s12209-024-00394-1

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References

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[1]	Guo Y, Wu S, He YB, et al. Solid-state lithium batteries: safety and prospects. eScience, 2022, 2(2): 138-163.

[2]	Li L, Yao J, Xu R, et al. Highly stable and encapsulation-microstructural cathode derived by self-pressurization behavior in Na-halides-based all-solid-state batteries. Energy Storage Mater, 2023, 63.

[3]	Yan H, Yao J, Ye Z et al (2024) Al-F co-doping towards enhanced electrolyte-electrodes interface properties for halide and sulfide solid electrolytes. Chin Chemical Lett 109568

[4]	Manthiram A, Yu X, Wang S Lithium battery chemistries enabled by solid-state electrolytes. Nat Rev Mater, 2017, 2(4): 16103.

[5]	Chen S, Xie D, Liu G, et al. Sulfide solid electrolytes for all-solid-state lithium batteries: structure, conductivity, stability and application. Energy Storage Mater, 2018, 14: 58-74.

[6]	Liu H, Liang Y, Wang C, et al. Priority and prospect of sulfide-based solid-electrolyte membrane. Adv Mater, 2023, 35(50

[7]	Park KH, Bai Q, Kim DH, et al. Design strategies, practical considerations, and new solution processes of sulfide solid electrolytes for all-solid-state batteries. Adv Energy Mater, 2018, 8(18): 1800035.

[8]	Narayanan S, Ulissi U, Gibson JS, et al. Effect of current density on the solid electrolyte interphase formation at the lithium∣Li₆PS₅Cl interface. Nat Commun, 2022, 13(1): 7237.

[9]	Otto SK, Riegger LM, Fuchs T, et al. In situ investigation of lithium metal–solid electrolyte anode interfaces with ToF-SIMS. Adv Materials Inter, 2022, 9(13): 2102387.

[10]	Wu M, Liu G, Yao X Oxygen doped argyrodite electrolyte for all-solid-state lithium batteries. Appl Phys Lett, 2022, 121(20

[11]	Kim T, Kim K, Lee S, et al. Thermal runaway behavior of Li₆PS₅Cl solid electrolytes for LiNi_0.8Co_0.1Mn_0.1O₂ and LiFePO₄ in all-solid-state batteries. Chem Mater, 2022, 34(20): 9159-9171.

[12]	Wang S, Wu Y, Ma T, et al. Thermal stability between sulfide solid electrolytes and oxide cathode. ACS Nano, 2022, 16(10): 16158-16176.

[13]	Song R, Yao J, Xu R, et al. Metastable decomposition realizing dendrite-free solid-state Li metal batteries. Adv Energy Mater, 2023, 13(9): 2203631.

[14]	Yadav NG, Folastre N, Bolmont M, et al. Study of failure modes in two sulphide-based solid electrolyte all-solid-state batteries via in situ SEM. J Mater Chem A, 2022, 10(33): 17142-17155.

[15]	Xu R, Han F, Ji X, et al. Interface engineering of sulfide electrolytes for all-solid-state lithium batteries. Nano Energy, 2018, 53: 958-966.

[16]	Fan X, Ji X, Han F, et al. Fluorinated solid electrolyte interphase enables highly reversible solid-state Li metal battery. Sci Adv, 2018, 4(12): eaau9245.

[17]	Hood ZD, Mane AU, Sundar A, et al. Multifunctional coatings on sulfide-based solid electrolyte powders with enhanced processability, stability, and performance for solid-state batteries. Adv Mater, 2023, 35(21

[18]	Arnold W, Shreyas V, Li Y, et al. Synthesis of fluorine-doped lithium argyrodite solid electrolytes for solid-state lithium metal batteries. ACS Appl Mater Interfaces, 2022, 14(9): 11483-11492.

[19]	Liu C, Chen B, Zhang T, et al. Electron redistribution enables redox-resistible Li₆PS₅Cl towards high-performance all-solid-state lithium batteries. Angew Chem Int Ed, 2023, 62(22

[20]	Liu H, Zhu Q, Wang C, et al. High air stability and excellent Li metal compatibility of argyrodite-based electrolyte enabling superior all-solid-state Li metal batteries. Adv Funct Mater, 2022, 32(32): 2203858.

[21]	Sang J, Pan K, Tang B, et al. One stone, three birds: an air and interface stable argyrodite solid electrolyte with multifunctional nanoshells. Adv Sci, 2023, 10(32

[22]	Wang C, Hao J, Wu J et al (2024) Enhanced air stability and Li metal compatibility of Li-argyrodite electrolytes triggered by In₂O₃ co-doping for all-solid-state Li metal batteries. Adv Funct Mater 2313308

[23]	Zeng D, Yao J, Zhang L, et al. Promoting favorable interfacial properties in lithium-based batteries using chlorine-rich sulfide inorganic solid-state electrolytes. Nat Commun, 2022, 13(1): 1909.

[24]	Zhao F, Sun Q, Yu C, et al. Ultrastable anode interface achieved by fluorinating electrolytes for all-solid-state Li metal batteries. ACS Energy Lett, 2020, 5(4): 1035-1043.

[25]	Cho JU, Rajagopal R, Yoon DH, et al. Control of side reactions using LiNbO₃ mixed/doped solid electrolyte for enhanced sulfide-based all-solid-state batteries. Chem Eng J, 2023, 452.

[26]	Shi J, Li P, Han K, et al. High-rate and durable sulfide-based all-solid-state lithium battery with in situ Li₂O buffering. Energy Storage Mater, 2022, 51: 306-316.

[27]	Shi J, Ma Z, Wu D, et al. Low-cost BPO₄ in situ synthetic Li₃PO₄ coating and B/P-doping to boost 4.8 V cyclability for sulfide-based all-solid-state lithium batteries. Small, 2024, 20(13): e2307030.

[28]	Han A, Xu S, Wang X et al (2023) Toward high-quality sulfide solid electrolytes: a liquid-phase approach featured with an interparticle coupled unification effect. Small e2307997

[29]	Li S, Lin J, Schaller M, et al. High-entropy lithium argyrodite solid electrolytes enabling stable all-solid-state batteries. Angew Chem Int Ed, 2023, 62(50

[30]	Adeli P, Bazak JD, Park KH, et al. Boosting solid-state diffusivity and conductivity in lithium superionic argyrodites by halide substitution. Angew Chem Int Ed, 2019, 58(26): 8681-8686.

[31]	Huang W, Wang H, Boyle DT, et al. Resolving nanoscopic and mesoscopic heterogeneity of fluorinated species in battery solid-electrolyte interphases by cryogenic electron microscopy. ACS Energy Lett, 2020, 5(4): 1128-1135.

[32]	Wan H, Wang Z, Liu S, et al. Critical interphase overpotential as a lithium dendrite-suppression criterion for all-solid-state lithium battery design. Nat Energy, 2023, 8: 473-481.

[33]	Ning Z, Li G, Melvin DLR, et al. Dendrite initiation and propagation in lithium metal solid-state batteries. Nature, 2023, 618(7964): 287-293.

[34]	Arnold W, Shreyas V, Akter S, et al. Highly conductive Iodine and fluorine dual-doped argyrodite solid electrolyte for lithium metal batteries. J Phys Chem C, 2023, 127(25): 11801-11809.

[35]	Indrawan RF, Matsuda R, Hikima K, et al. Enhanced electrochemistry stability of oxygen doped Li₆PS₅Cl argyrodite solid electrolyte by liquid-phase synthesis. Solid State Ion, 2023, 401.

[36]	Liu H, Zhu Q, Liang Y, et al. Versatility of Sb-doping enabling argyrodite electrolyte with superior moisture stability and Li metal compatibility towards practical all-solid-state Li metal batteries. Chem Eng J, 2023, 462.

[37]	Wei C, Yu C, Wang R, et al. Sb and O dual doping of Chlorine-rich lithium argyrodite to improve air stability and lithium compatibility for all-solid-state batteries. J Power Sources, 2023, 559.

[38]	Yuvaraj S, Rajesh R, Sung K, et al. Enhancement of lithium argyrodite interface stability through MoO₂ substitution and its application in lithium solid state batteries. J Alloys Compd, 2022, 925.

[39]	Yu C, Ganapathy S, Eck ERHV, et al. Accessing the bottleneck in all-solid state batteries, lithium-ion transport over the solid-electrolyte-electrode interface. Nat Commun, 2017, 8(1): 1086.

[40]	Liu X, Garcia-Mendez R, Lupini AR, et al. Local electronic structure variation resulting in Li 'filament' formation within solid electrolytes. Nat Mater, 2021, 20(11): 1485-1490.

[41]	Sushko ML, Rosso KM, Liu J Size effects on Li⁺/electron conductivity in TiO₂ nanoparticles. J Phys Chem Lett, 2010, 1(13): 1967-1972.

[42]	Gombotz M, Wilkening HMR Fast Li ion dynamics in the mechanosynthesized nanostructured form of the solid electrolyte Li₃YBr₆. ACS Sustainable Chem Eng, 2021, 9(2): 743-755.