钠金属负极人工界面保护层的研究进展

doi:10.19799/j.cnki.2095-4239.2023.0324

储能科学与技术 ›› 2023, Vol. 12 ›› Issue (5): 1380-1391.doi: 10.19799/j.cnki.2095-4239.2023.0324

• 喜迎东北大学建校百年-储能电池关键材料与循环技术专刊 • 上一篇下一篇

钠金属负极人工界面保护层的研究进展

余永诗¹(), 夏先明¹, 黄弘扬¹, 姚雨², 芮先宏¹, 钟国彬³, 苏伟³(), 余彦²()

^1.广东工业大学材料与能源学院，广东广州 510006
^2.中国科学技术大学材料科学与工程系，安徽合肥 230026
^3.南方电网电力科技股份有限公司，广东广州 510080

收稿日期:2023-05-06 修回日期:2023-05-15 出版日期:2023-05-05 发布日期:2023-05-29
通讯作者: 苏伟,余彦 E-mail:2112102083@mail2.gdut.edu.cn;jxhwsu@163.com;yanyumse@ustc.edu.cn
作者简介:余永诗（1998—），女，硕士研究生，研究方向为钠金属负极，E-mail：2112102083@mail2.gdut.edu.cn；
基金资助:
国家杰出青年科学基金项目(51925207)

Research progress on sodium metal anode modified by artificial interface layer

Yongshi YU¹(), Xianming XIA¹, Hongyang HUANG¹, Yu YAO², Xianhong RUI¹, Guobin ZHONG³, Wei SU³(), Yan YU²()

^1.School of Materials and Energy, Guangdong University of Technology, Guangzhou 510006, Guangdong, China
^2.Department of Materials Science and Engineering, University of Science and Technology of China, Hefei 230026, Anhui, China
^3.China Southern Powergrid Technology Co. , Ltd. , Guangzhou 510080, Guangdong, China

Received:2023-05-06 Revised:2023-05-15 Online:2023-05-05 Published:2023-05-29
Contact: Wei SU, Yan YU E-mail:2112102083@mail2.gdut.edu.cn;jxhwsu@163.com;yanyumse@ustc.edu.cn

摘要/Abstract

摘要：

钠金属负极由于其高的比容量、低的氧化还原电位以及资源优势被认为是钠电池极佳的负极材料。然而，不稳定的固体电解质界面(SEI)以及钠枝晶生长问题严重阻碍了其实际应用。因此，采用适当的保护策略实现钠金属负极稳定及高效循环是非常必要的。通常在钠金属负极表面构建人工界面层不仅可以有效实现钠均匀沉积/剥离，而且可有效缓解钠金属负极在电化学过程中的体积变化以及抑制钠枝晶生长。为此，该综述归纳总结了人工界面层策略改善钠金属负极的研究进展。首先讨论了自发形成的SEI膜的基本性质，其存在稳定性差、韧性差、机械强度低等问题。针对此，提出构建无机、有机和无机-有机复合人工界面层保护钠金属负极，实现无枝晶钠沉积/剥离。含钠无机材料通常具有高剪切模量、耐腐蚀、结构稳定、高离子电导率等优点，但脆性大；有机材料通常具有结构可设计性、官能团多样性以及高机械韧性特点，但稳定性较弱；无机-有机复合保护膜结合了上述两者的优势，可构建综合性能优异的人工界面层。文中详细阐述了这三种人工界面膜的实施方法与改性效果。最后，建议对人工界面膜持续优化以及采用先进表征技术、理论计算和模拟等深入研究界面稳定性机理。

关键词: 钠金属负极, 钠枝晶, 固体电解质界面, 人工界面层

Abstract:

Sodium metal anode is considered as the superior anode material due to its high specific capacity, low redox potential, and abundant resources. However, the problems of unstable solid electrolyte interface (SEI) and sodium dendritic growth have seriously hindered its practical application. It is thus essential to adopt appropriate strategies to achieve stable and efficient use of sodium metal anode. Generally, the construction of an artificial interface layer on the surface of the sodium metal anode can not only effectively achieve uniform sodium deposition, but also effectively mitigate the volume change and sodium dendrite growth during the electrochemical process. Therefore, this review focuses on the research progress on sodium metal anode modified by artificial interface layer. Firstly, the basic properties of spontaneously formed SEI films are discussed. Generally, they suffer from poor stability, poor toughness and low mechanical strength. To address these issues, the construction of inorganic, organic and inorganic-organic artificial interfacial layers to protect sodium metal anodes for dendrite-free sodium deposition/exfoliation is proposed. Sodium-contained inorganic materials usually have the advantages of high shear modulus, corrosion resistance, structural stability, and high ionic conductivity, but are brittle; organic materials usually have structural designability, functional group diversity, and high mechanical toughness, but are poorly stable; the inorganic-organic composite protective film combines the advantages of the above two and can build an artificial interface layer with excellent comprehensive performance. The implementation methods and modification effects of these three artificial interface films are elaborated in this paper. Finally, it is suggested to continuously optimize the artificial interfacial films as well as to use advanced characterization techniques, theoretical calculations and simulations to study the mechanisms of interfacial stability in depth.

Key words: sodium metal anode, sodium dendrite, solid electrolyte interface, artificial interfacial layer

中图分类号:

TM 911

余永诗, 夏先明, 黄弘扬, 姚雨, 芮先宏, 钟国彬, 苏伟, 余彦. 钠金属负极人工界面保护层的研究进展[J]. 储能科学与技术, 2023, 12(5): 1380-1391.

Yongshi YU, Xianming XIA, Hongyang HUANG, Yu YAO, Xianhong RUI, Guobin ZHONG, Wei SU, Yan YU. Research progress on sodium metal anode modified by artificial interface layer[J]. Energy Storage Science and Technology, 2023, 12(5): 1380-1391.

图/表 9

图1

图2

图3

图4

图5

图6

图7

图8

图9

参考文献 91

1	ZHANG B, KANG F Y, TARASCON J M, et al. Recent advances in electrospun carbon nanofibers and their application in electrochemical energy storage[J]. Progress in Materials Science, 2016, 76: 319-380.
2	CHEN C J, ZHANG Y, LI Y J, et al. Highly conductive, lightweight, low-tortuosity carbon frameworks as ultrathick 3D current collectors[J]. Advanced Energy Materials, 2017, 7(17): doi:10.1002/aenm. 201700595.
3	YANG Z G, ZHANG J L, KINTNER-MEYER M C W, et al. Electrochemical energy storage for green grid[J]. Chemical Reviews, 2011, 111(5): 3577-3613.
4	张平, 康利斌, 王明菊, 等. 钠离子电池储能技术及经济性分析[J]. 储能科学与技术, 2022, 11(6): 1892-1901.
	ZHANG P, KANG L B, WANG M J, et al. Technology feasibility and economic analysis of Na-ion battery energy storage[J]. Energy Storage Science and Technology, 2022, 11(6): 1892-1901.
5	王心怡, 李维杰, 韩朝, 等. 水系锌离子电池金属负极的挑战与优化策略[J]. 储能科学与技术, 2022, 11(4): 1211-1225.
	WANG X Y, LI W J, HAN (C /Z), et al. Challenges and optimization strategies of the anode of aqueous zinc-ion battery[J]. Energy Storage Science and Technology, 2022, 11(4): 1211-1225.
6	DUNN B, KAMATH H, TARASCON J M. Electrical energy storage for the grid: A battery of choices[J]. Science, 2011, 334(6058): 928-935.
7	PAN H L, HU Y S, CHEN L Q. Room-temperature stationary sodium-ion batteries for large-scale electric energy storage[J]. Energy & Environmental Science, 2013, 6(8): 2338-2360.
8	LARCHER D, TARASCON J M. Towards greener and more sustainable batteries for electrical energy storage[J]. Nature Chemistry, 2015, 7(1): 19-29.
9	YOSHINO A. The birth of the lithium-ion battery[J]. Angewandte Chemie International Edition, 2012, 51(24): 5798-5800.
10	HU L, DENG J J, LIANG Q H, et al. Engineering current collectors for advanced alkali metal anodes: A review and perspective[J]. EcoMat, 2023, 5(1): e12269.
11	ARMAND M, TARASCON J M. Building better batteries[J]. Nature, 2008, 451(7179): 652-657.
12	CUI J Y, WANG A X, LI G J, et al. Composite sodium metal anodes for practical applications[J]. Journal of Materials Chemistry A, 2020, 8(31): 15399-15416.
13	PERVEEN T, SIDDIQ M, SHAHZAD N, et al. Prospects in anode materials for sodium ion batteries-A review[J]. Renewable and Sustainable Energy Reviews, 2020, 119: doi:10.1016/j.rser.2019. 109549.
14	HWANG J Y, MYUNG S T, SUN Y K. Sodium-ion batteries: Present and future[J]. Chemical Society Reviews, 2017, 46(12): 3529-3614.
15	CHAYAMBUKA K, MULDER G, DANILOV D L, et al. From Li-ion batteries toward Na-ion chemistries: Challenges and opportunities[J]. Advanced Energy Materials, 2020, 10(38): doi: 10.1002/aenm. 202001310.
16	KIM Y J, LEE H, NOH H, et al. Enhancing the cycling stability of sodium metal electrodes by building an inorganic-organic composite protective layer[J]. ACS Applied Materials & Interfaces, 2017, 9(7): 6000-6006.
17	SEH Z W, SUN J, SUN Y M, et al. A highly reversible room-temperature sodium metal anode[J]. ACS Central Science, 2015, 1(8): 449-455.
18	WEI S Y, CHOUDHURY S, XU J, et al. Highly stable sodium batteries enabled by functional ionic polymer membranes[J]. Advanced Materials, 2017, 29(12): 1605512.
19	WU J X, LIN C, LIANG Q H, et al. Sodium-rich NASICON-structured cathodes for boosting the energy density and lifespan of sodium-free-anode sodium metal batteries[J]. InfoMat, 2022, 4(4): doi:10.1002/inf2.12288.
20	LI D C, WANG X X, GUO Q, et al. Atomically bonding Na anodes with metallized ceramic electrolytes by ultrasound welding for high-energy/power solid-state sodium metal batteries[J]. Carbon Energy, 2023, 5(2): doi: 10.1002/cey2.299.
21	WANG H, LIANG J L, WU Y, et al. Porous BN nanofibers enable long-cycling life sodium metal batteries[J]. Small, 2020, 16(34): 2002671.
22	SONG H W, SU J, WANG C X. Hybrid solid electrolyte interphases enabled ultralong life Ca-metal batteries working at room temperature[J]. Advanced Materials, 2021, 33(2): 2006141.
23	SUN B, LI P, ZHANG J Q, et al. Dendrite-free sodium-metal anodes for high-energy sodium-metal batteries[J]. Advanced Materials, 2018, 30(29): 1801334.
24	TIAN H Z, SEH Z W, YAN K, et al. Theoretical investigation of 2D layered materials as protective films for lithium and sodium metal anodes[J]. Advanced Energy Materials, 2017, 7(13): 1602528.
25	LUO W, HU L B. Na metal anode: “holy grail” for room-temperature Na-ion batteries?[J]. ACS Central Science, 2015, 1(8): 420-422.
26	WANG T S, LIU Y C, LU Y X, et al. Dendrite-free Na metal plating/stripping onto 3D porous Cu hosts[J]. Energy Storage Materials, 2018, 15: 274-281.
27	ZHANG Q, HU M, HE J, et al. A thermodynamically stable quasi-liquid interface for dendrite-free sodium metal anodes[J]. Journal of Materials Chemistry A, 2020, 8(14): 6822-6827.
28	MA C Y, XU T T, WANG Y. Advanced carbon nanostructures for future high performance sodium metal anodes[J]. Energy Storage Materials, 2020, 25: 811-826.
29	LIN Z H, XIA Q B, WANG W L, et al. Recent research progresses in ether- and ester-based electrolytes for sodium-ion batteries[J]. InfoMat, 2019, 1(3): 376-389.
30	FAN L L, LI X F. Recent advances in effective protection of sodium metal anode[J]. Nano Energy, 2018, 53: 630-642.
31	ZHAO Y, ADAIR K R, SUN X L. Recent developments and insights into the understanding of Na metal anodes for Na-metal batteries[J]. Energy & Environmental Science, 2018, 11(10): 2673-2695.
32	BAO C Y, WANG B, LIU P, et al. Solid electrolyte interphases on sodium metal anodes[J]. Advanced Functional Materials, 2020, 30(52): doi:10.1002/adfm.202004891.
33	ZHENG J M, CHEN S R, ZHAO W G, et al. Extremely stable sodium metal batteries enabled by localized high-concentration electrolytes[J]. ACS Energy Letters, 2018, 3(2): 315-321.
34	WANG H, MATIOS E, LUO J M, et al. Combining theories and experiments to understand the sodium nucleation behavior towards safe sodium metal batteries[J]. Chemical Society Reviews, 2020, 49(12): 3783-3805.
35	YE S F, WANG L F, LIU F F, et al. Integration of homogeneous and heterogeneous nucleation growth via 3D alloy framework for stable Na/K metal anode[J]. eScience, 2021, 1(1): 75-82.
36	LI N W, YIN Y X, YANG C P, et al. An artificial solid electrolyte interphase layer for stable lithium metal anodes[J]. Advanced Materials, 2016, 28(9): 1853-1858.
37	LUO W, LIN C F, ZHAO O, et al. Ultrathin surface coating enables the stable sodium metal anode[J]. Advanced Energy Materials, 2017, 7(2): doi: 10.1002/aenm.201601526.
38	YUI Y, HAYASHI M, NAKAMURA J. In situ microscopic observation of sodium deposition/dissolution on sodium electrode[J]. Scientific Reports, 2016, 6(1): 1-8.
39	CAO K S, ZHAO X T, CHEN J, et al. Hybrid design of bulk-Na metal anode to minimize cycle-induced interface deterioration of solid Na metal battery[J]. Advanced Energy Materials, 2022, 12(7): doi:10.1002/aenm.202102579.
40	WANG H, WU Y, LIU S H, et al. 3D Ag@C cloth for stable anode free sodium metal batteries[J]. Small Methods, 2021, 5(4): doi:10.1002/smtd.202001050.
41	TANG F, XIA R Q, CHEN D, et al. Rapid and reversible Na deposition onto Al nanosheet arrays[J]. Journal of Energy Chemistry, 2022, 74: 1-7.
42	CHENG H R, SUN Q J, LI L L, et al. Emerging era of electrolyte solvation structure and interfacial model in batteries[J]. ACS Energy Letters, 2022, 7(1): 490-513.
43	YU Z A, RUDNICKI P E, ZHANG Z W, et al. Rational solvent molecule tuning for high-performance lithium metal battery electrolytes[J]. Nature Energy, 2022, 7(1): 94-106.
44	ZHAO Q, STALIN S, ARCHER L A. Stabilizing metal battery anodes through the design of solid electrolyte interphases[J]. Joule, 2021, 5(5): 1119-1142.
45	WEI C L, TAN L W, ZHANG Y C, et al. Review of room-temperature liquid metals for advanced metal anodes in rechargeable batteries[J]. Energy Storage Materials, 2022, 50: 473-494.
46	CHOUDHURY S, WEI S Y, OZHABES Y, et al. Designing solid-liquid interphases for sodium batteries[J]. Nature Communications, 2017, 8(1): 1-10.
47	YANG H, HE F X, LI M H, et al. Design principles of sodium/potassium protection layer for high-power high-energy sodium/potassium-metal batteries in carbonate electrolytes: A case study of Na₂Te/K₂Te[J]. Advanced Materials, 2021, 33(48): doi:10.1002/adma.202106353.
48	LI D J, SUN Y J, LI M H, et al. Rational design of an artificial SEI: Alloy/solid electrolyte hybrid layer for a highly reversible Na and K metal anode[J]. ACS Nano, 2022, 16(10): 16966-16975.
49	LU Q Q, OMAR A, DING L, et al. A facile method to stabilize sodium metal anodes towards high-performance sodium batteries[J]. Journal of Materials Chemistry A, 2021, 9(14): 9038-9047.
50	ZHU M, WANG G Y, LIU X, et al. Dendrite-free sodium metal anodes enabled by a sodium benzenedithiolate-rich protection layer[J]. Angewandte Chemie International Edition, 2020, 59(16): 6596-6600.
51	SONI C B, SUNGJEMMENLA, VINEETH S K, et al. Patterned interlayer enables a highly stable and reversible sodium metal anode for sodium-metal batteries[J]. Sustainable Energy & Fuels, 2023, 7(8): 1908-1915.
52	CHEN Q W, HOU Z, SUN Z Z, et al. Polymer-inorganic composite protective layer for stable Na metal anodes[J]. ACS Applied Energy Materials, 2020, 3(3): 2900-2906.
53	PELED E. The electrochemical behavior of alkali and alkaline earth metals in nonaqueous battery systems—The solid electrolyte interphase model[J]. Journal of the Electrochemical Society, 1979, 126(12): 2047-2051.
54	PELED E. Film forming reaction at the lithium/electrolyte interface[J]. Journal of Power Sources, 1983, 9(3): 253-266.
55	PELED E, GOLODNITSKY D, ARDEL G. Advanced model for solid electrolyte interphase electrodes in liquid and polymer electrolytes[J]. Journal of the Electrochemical Society, 1997, 144(8): L208-L210.
56	AURBACH D, MARKOVSKY B, LEVI M D, et al. New insights into the interactions between electrode materials and electrolyte solutions for advanced nonaqueous batteries[J]. Journal of Power Sources, 1999, 81: 95-111.
57	SHI S Q, LU P, LIU Z Y, et al. Direct calculation of Li-ion transport in the solid electrolyte interphase[J]. Journal of the American Chemical Society, 2012, 134(37): 15476-15487.
58	GOODENOUGH J B, KIM Y. Challenges for rechargeable Li batteries[J]. Chemistry of Materials, 2010, 22(3): 587-603.
59	WU B B, WANG S Y, LOCHALA J, et al. The role of the solid electrolyte interphase layer in preventing Li dendrite growth in solid-state batteries[J]. Energy & Environmental Science, 2018, 11(7): 1803-1810.
60	WANG T, HUA Y B, XU Z W, et al. Recent advanced development of artificial interphase engineering for stable sodium metal anodes[J]. Small, 2022, 18(5): doi: 10.1002/smll. 2102250.
61	MA L B, CUI J, YAO S S, et al. Dendrite-free lithium metal and sodium metal batteries[J]. Energy Storage Materials, 2020, 27: 522-554.
62	CHENG X B, ZHANG R, ZHAO C Z, et al. Toward safe lithium metal anode in rechargeable batteries: A review[J]. Chemical Reviews, 2017, 117(15): 10403-10473.
63	WANG T, HUA Y B, XU Z W, et al. Recent advanced development of artificial interphase engineering for stable sodium metal anodes[J]. Small, 2022, 18(5): doi:10.1002/smll.202102250.
64	AKOLKAR R. Modeling dendrite growth during lithium electrodeposition atsub-ambient temperature[J]. Journal of Power Sources, 2014, 246: 84-89.
65	MEDENBACH L, BENDER C L, HAAS R, et al. Origins of dendrite formation in sodium-oxygen batteries and possible countermeasures[J]. Energy Technology, 2017, 5(12): 2265-2274.
66	LIN D C, LIU Y Y, CUI Y. Reviving the lithium metal anode for high-energy batteries[J]. Nature Nanotechnology, 2017, 12(3): 194-206.
67	SUN B, XIONG P, MAITRA U, et al. Design strategies to enable the efficient use of sodium metal anodes in high-energy batteries[J]. Advanced Materials, 2020, 32(18): doi:10.1002/adma.201903891.
68	ZHENG X Y, BOMMIER C, LUO W, et al. Sodium metal anodes for room-temperature sodium-ion batteries: Applications, challenges and solutions[J]. Energy Storage Materials, 2019, 16: 6-23.
69	XU R, CHENG X B, YAN C, et al. Artificial interphases for highly stable lithium metal anode[J]. Matter, 2019, 1(2): 317-344.
70	LI B, ZHANG X T, WANG T T, et al. Interfacial engineering strategy for high-performance Zn metal anodes[J]. Nano-Micro Letters, 2021, 14(1): 1-31.
71	MEYERSON M L, PAPA P E, HELLER A, et al. Recent developments in dendrite-free lithium-metal deposition through tailoring of micro- and nanoscale artificial coatings[J]. ACS Nano, 2021, 15(1): 29-46.
72	MENG X B, YANG X Q, SUN X L. Emerging applications of atomic layer deposition for lithium-ion battery studies[J]. Advanced Materials, 2012, 24(27): 3589-3615.
73	ZHAO Y, GONCHAROVA L V, LUSHINGTON A, et al. Superior stable and long life sodium metal anodes achieved by atomic layer deposition[J]. Advanced Materials, 2017, 29(18): doi:10.1002/adma.201606663.
74	IERMAKOVA D I, DUGAS R, PALACÍN M R, et al. On the comparative stability of Li and Na metal anode interfaces in conventional alkyl carbonate electrolytes[J]. Journal of the Electrochemical Society, 2015, 162(13): A7060-A7066.
75	HOU Z, WANG W H, CHEN Q W, et al. Hybrid protective layer for stable sodium metal anodes at high utilization[J]. ACS Applied Materials & Interfaces, 2019, 11(41): 37693-37700.
76	XIE Y Y, LIU C Y, ZHENG J Q, et al. NaF-rich protective layer on PTFE coating microcrystalline graphite for highly stable Na metal anodes[J].Nano Research, 2023, 16(2): 2436-2444.
77	WANG H P, ZHU C L, LIU J D, et al. Formation of NaF-rich solid electrolyte interphase on Na anode through additive-induced anion-enriched structure of Na⁺ solvation[J]. Angewandte Chemie International Edition, 2022, 61(38): doi: 10.1002/anie.202208506.
78	DUGAS R, PONROUCH A, GACHOT G, et al. Na reactivity toward carbonate-based electrolytes: The effect of FEC as additive[J]. Journal of the Electrochemical Society, 2016, 163(10): A2333-A2339.
79	WU S C, QIAO Y, JIANG K Z, et al. Tailoring sodium anodes for stable sodium-oxygen batteries[J]. Advanced Functional Materials, 2018, 28(13): doi: 10.1002/adfm.201706374.
80	XU Z X, YANG J, ZHANG T, et al. Stable Na metal anode enabled by a reinforced multistructural SEI layer[J]. Advanced Functional Materials, 2019: doi: 10.1002/adfm.201901924.
81	CHENG Y F, YANG X M, LI M H, et al. Enabling ultrastable alkali metal anodes by artificial solid electrolyte interphase fluorination[J]. Nano Letters, 2022, 22(11): 4347-4353.
82	TIAN H J, SHAO H Z, CHEN Y, et al. Ultra-stable sodium metal-iodine batteries enabled by an in situ solid electrolyte interphase[J]. Nano Energy, 2019, 57: 692-702.
83	SHI P C, ZHANG S P, LU G X, et al. Red phosphorous-derived protective layers with high ionic conductivity and mechanical strength on dendrite-free sodium and potassium metal anodes[J]. Advanced Energy Materials, 2021, 11(5): doi:10.1002/aenm. 202003381.
84	ZHENG X Y, GU Z Y, FU J, et al. Knocking down the kinetic barriers towards fast-charging and low-temperature sodium metal batteries[J]. Energy & Environmental Science, 2021, 14(9): 4936-4947.
85	LUO Z, TAO S S, TIAN Y, et al. Robust artificial interlayer for columnar sodium metal anode[J]. Nano Energy, 2022, 97: https://doi.org/10.1016/j.nanoen.2022.107203.
86	WANG S J, YANG Z, CHEN B T, et al. A highly reversible, dendrite-free zinc metal anodes enabled by a dual-layered interface[J]. Energy Storage Materials, 2022, 47: 491-499.
87	SUN Y P, ZHAO Y, WANG J W, et al. A novel organic “polyurea” thin film for ultralong-life lithium-metal anodes via molecular-layer deposition[J]. Advanced Materials, 2019, 31(4): doi:10.1002/adma. 201806541.
88	LIANG Z, ZHENG G Y, LIU C, et al. Polymer nanofiber-guided uniform lithium deposition for battery electrodes[J]. Nano Letters, 2015, 15(5): 2910-2916.
89	GREGORCZYK K, KNEZ M. Hybrid nanomaterials through molecular and atomic layer deposition: Top down, bottom up, and in-between approaches to new materials[J]. Progress in Materials Science, 2016, 75: 1-37.
90	ZHAO Y, SUN X L. Molecular layer deposition for energy conversion and storage[J]. ACS Energy Letters, 2018, 3(4): 899-914.
91	ZHAO Y, GONCHAROVA L V, ZHANG Q, et al. Inorganic-organic coating via molecular layer deposition enables long life sodium metal anode[J]. Nano Letters, 2017, 17(9): 5653-5659.

[1]	时文超, 刘宇, 张博冕, 李琪, 韩春华, 麦立强. 电解液添加剂稳定水系电池锌负极界面的研究进展[J]. 储能科学与技术, 2023, 12(5): 1589-1603.
[2]	张慧敏, 王京, 王一博, 郑家新, 邱景义, 曹高萍, 张浩. 锂离子电池SEI多尺度建模研究展望[J]. 储能科学与技术, 2023, 12(2): 366-382.
[3]	翁素婷, 刘泽鹏, 杨高靖, 张思蒙, 张啸, 方遒, 李叶晶, 王兆翔, 王雪锋, 陈立泉. 冷冻电镜表征锂电池中的辐照敏感材料[J]. 储能科学与技术, 2022, 11(3): 760-780.
[4]	林乙龙, 肖敏, 韩东梅, 王拴紧, 孟跃中. 锂离子电池化成技术研究进展[J]. 储能科学与技术, 2021, 10(1): 50-58.
[5]	吴洁, 江小标, 杨旸, 吴勇民, 朱蕾, 汤卫平. NASICON结构Li₁₊_xAl_xTi₂_-_x(PO₄)₃（0≤x≤0.5）固体电解质研究进展[J]. 储能科学与技术, 2020, 9(5): 1472-1488.
[6]	高翔, 朱紫瑞. 原子力显微镜在锂离子电池研究中的应用[J]. 储能科学与技术, 2019, 8(1): 75-82.

钠金属负极人工界面保护层的研究进展

Research progress on sodium metal anode modified by artificial interface layer

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 9

参考文献 91

相关文章 6

编辑推荐

Metrics

本文评价