固态锂电池十年（2011—2021）回顾与展望

doi:10.19799/j.cnki.2095-4239.2022.0309

储能科学与技术 ›› 2022, Vol. 11 ›› Issue (9): 2713-2745.doi: 10.19799/j.cnki.2095-4239.2022.0309

固态锂电池十年（2011—2021）回顾与展望

吴敬华¹^,²(), 杨菁¹, 刘高瞻¹, 王脂胭¹^,², 张秩华¹, 俞海龙²^,³, 姚霞银¹^,²(), 黄学杰²^,³()

^1.中国科学院宁波材料技术与工程研究所，浙江宁波 315201
^2.中国科学院大学，北京 100049
^3.中国科学院物理研究所，北京 100190

收稿日期:2022-06-10 修回日期:2022-07-29 出版日期:2022-09-05 发布日期:2022-08-30
通讯作者: 姚霞银,黄学杰 E-mail:wujh@nimte.ac.cn;yaoxy@nimte.ac.cn;xjhuang@iphy.ac.cn
作者简介:吴敬华（1982—），男，博士，副研究员，研究方向为正极材料与电池界面，E-mail：wujh@nimte.ac.cn；
基金资助:
国家重点研发计划(2018YFB0104100);中国科学院青年创新促进会(Y2021080)

Review and prospective of solid-state lithium batteries in the past decade （2011—2021）

Jinghua WU¹^,²(), Jing YANG¹, Gaozhan LIU¹, Zhiyan WANG¹^,², Zhihua ZHANG¹, Hailong YU²^,³, Xiayin YAO¹^,²(), Xuejie HUANG²^,³()

^1.Ningbo Institute of Materials Technology and Engineering, Chinese Academy of Sciences, Ningbo 315201, Zhejiang, China
^2.University of Chinese Academy of Sciences, Beijing 100049, China
^3.Institute of Physics, Chinese Academy of Sciences, Beijing 100190, China

Received:2022-06-10 Revised:2022-07-29 Online:2022-09-05 Published:2022-08-30
Contact: Xiayin YAO, Xuejie HUANG E-mail:wujh@nimte.ac.cn;yaoxy@nimte.ac.cn;xjhuang@iphy.ac.cn

摘要/Abstract

摘要：

采用固体电解质取代液态有机电解液的固态锂电池，有望使用更高比容量的正、负极材料，从而实现更高比能量的电池体系，同时可彻底解决电池的安全性问题，符合未来二次电池发展的方向，是电动汽车和规模化储能的理想电源。为了实现兼具高比能量、高安全性、长寿命等特性的固态电池，进而推进全固态锂电池的实用化，2011—2021年间各国的科学家做了大量工作，并取得了许多突破性进展。本文以固态锂电池关键材料为出发点，回顾了2011—2021年以来固态电池的研究进展，包括锂离子固体电解质材料，电极/电解质界面调控，固态电池技术等方面，总结了现在存在的挑战及解决方案，并对该领域未来可能的发展提出了展望。

关键词: 固态锂电池, 固体电解质, 界面

Abstract:

Solid-state lithium batteries with solid electrolyte rather than traditional liquid organic electrolyte could employ high specific capacity cathodes and anodes, resulting in high energy density devices with high safety, which is consistent with the future development direction of power sources for electric vehicles and large-scale energy storage. To accelerate the practical application of both solid-state and all-solid-state lithium batteries with high energy density, high safety, and long service life, scientists from all over the world have done a lot of work and made many breakthroughs from 2011 to 2022. Herein, in view of the challenges and opportunities for solid-state lithium batteries, the research progress of solid-state lithium batteries in the last decade, including solid electrolyte materials, electrode/electrolyte interface regulation, and solid-state battery technology, was reviewed. Finally, possible research directions and development trends for solid-state lithium batteries are also discussed.

Key words: solid-state lithium batteries, solid electrolytes, interface

中图分类号:

O 63

吴敬华, 杨菁, 刘高瞻, 王脂胭, 张秩华, 俞海龙, 姚霞银, 黄学杰. 固态锂电池十年（2011—2021）回顾与展望[J]. 储能科学与技术, 2022, 11(9): 2713-2745.

Jinghua WU, Jing YANG, Gaozhan LIU, Zhiyan WANG, Zhihua ZHANG, Hailong YU, Xiayin YAO, Xuejie HUANG. Review and prospective of solid-state lithium batteries in the past decade （2011—2021）[J]. Energy Storage Science and Technology, 2022, 11(9): 2713-2745.

图/表 18

表1

图1

表2

图2

图3

图4

图5

图6

图7

图 8

图 9

表3

不同类固体电解质的离子电导率以及制备方法"

电解质种类	电解质分子式	离子电导率/(S/cm)	制备方法	文献
NASICON结构	Li_1.3Al_0.3Ti_1.7(PO₄)₃	1.0×10^-3	溶胶-凝胶法	[114]
	Li_1.3Al_0.3Ti_1.7(PO₄)₃	6.22×10^-4	喷雾干燥法	[115]
	Li_1.3Al_0.3Ti_1.7(PO₄)₃	1.21×10^-3	液相法	[116]
	Li_1.35Al_0.35Ge_0.2Ti_1.45(PO₄)₃	1.58×10^-3	固相法	[117]
	Li_1.5Al_0.5Ge_1.5(PO₄)₃-7.5 wt% TiO₂	1.07×10^-3	固相法	[118]
石榴石结构	Li_6.55La₃Zr₂Ga_0.15□_0.30O₁₂	1.3×10^-3	溶胶-凝胶法/氧气烧结	[119]
	Li_6.20Ga_0.30La_2.95Rb_0.05Zr₂O₁₂	1.62×10^-3	固相法	[120]
	Li_6.25Ga_0.25La₃Zr₂O₁₂	1.46×10^-3	固相法	[121]
	Li_6.25Fe_0.25La₃Zr₂O₁₂	1.38×10^-3	固相法	[122]
	Li_6.5La₃Zr_1.5Ta_0.5O₁₂	8.4×10^-4	固相法	[123]
	Li_6.5La₃Zr_1.75Te_0.25O₁₂	1.02×10^-3	固相法	[124]
	Li_6.65Ga_0.15La₃Zr_1.90Sc_0.10O₁₂	1.8×10^-3	溶胶-凝胶法	[125]
	Li_6.5La₃Zr_1.5Ta_0.5O₁₂	1.0×10^-3	快速高温烧结法	[126]
钙钛矿结构	Li_0.375Sr_0.4375Hf_0.25Ta_0.75O₃	3.8×10^-4	固相法	[127]
钙钛矿结构	Li_0.38Sr_0.44Hf_0.3Ta_0.7O_2.95F_0.05	4.8×10^-4	固相法	[128]
Li-P-S体系	Li₃PS₄	1.6×10^-4	液相法	[53]
	Li₇P₂S₈I	6.3×10^-4	固相法	[54]
	Li₇P₃S₁₁	1.7×10^-2	热压法	[55]
	Li₇P₃S₁₁	1.5×10^-3	液相法	[56]
Li_11-_x M_2-_x P₁₊_x S₁₂体系	Li₁₀GeP₂S₁₂	1.2×10^-2	固相法	[57]
	Li_9.54Si_1.74P_1.44S_11.7Cl_0.3	2.5×10^-2	固相法	[58]
	Li_9.54Si_1.74P_1.44S_11.4Cl_0.3O_0.3	(28±3)×10^-3	固相法	[59]
	Li₁₀SnP₂S₁₂	7×10^-3	固相法	[60]
Li₆PS₅X体系	Li_5.5PS_4.5Cl_1.5	(12.0±0.2)×10^-3	固相法(真空)	[64]
	Li_5.3PS_4.3ClBr_0.7	24×10^-3	固相法(真空)	[65]
	Li_6.6P_0.4Ge_0.6S₅I	(18.4±2.7)×10^-3	固相法(真空)	[66]
	Li_6.6Si_0.6Sb_0.4S₅I	24×10^-3	固相法(真空)	[67]
聚合物	PVDF-LiClO₄	2.03×10^-4	涂布	[72]
	PVDF-HFP-[Li(DMF)₃][TFSI]	1.55×10^-3	浇铸	[73]
	PEGDMA-LiTFSI	2.85×10^-4(60 ℃)	紫外光辐照	[91]
	PVCA-LiDFOB	9.82×10^-5(50 ℃)	原位聚合	[75]
	PPC-LiTFSI	3×10^-4	涂布	[76]
	TEGDME-PEO-NC-LiClO₄	10^-4	涂布	[81]
	PE-PEO cross-linked	>1.0×10^-4	浇铸	[82]
	PEO-LiTFSI-PI	2.3×10^-4	模板浇铸	[83]
	PEO-LiTFSI-PE	1.54×10^-4(60 ℃)	浇铸	[84]
	PEGMEA-LiTFSI-(PE-PMMA-PS)	4.53×10^-5( 60 ℃)	隔膜原位热固化	[85]
	PEO-LiTFSI-LLTO	2.04×10^-4	浇铸	[129]
	PAN/LiClO₄∶LLZTO	1.18×10^-3	静电纺丝	[90]
卤化物	Li₃InCl₆	1.49×10^-3	固相法(真空)	[130]
		2.04×10^-3	液相法	[110]
	Li₃YCl₆	0.51×10^-3	固相法(真空)	[105]
		1.25×10^-3	铵辅助合成法	[44]
	Li₃YBr₆	3.3×10^-3	固相法	[131]
	Li₃ScCl₆	3×10^-3	固相法(真空)	[132]
	Li₂Sc_2/3Cl₄	1.5×10^-3	固相法	[133]
	Li₃Y_0.1In_0.9Cl₆	1.26×10^-3	固相法(真空)	[134]
	Li₃YBr₃Cl₃	7.2×10^-3	热压法	[135]
	Li_2.5Y_0.5Zr_0.5Cl₆	1.4×10^-3	固相法(真空)	[106]
	Li₃YBr_5.7F_0.3	1.8×10^-3	固相法(真空)	[136]

表3

图10

图11

图12

图13

图14

表4

国内外企业固态电池产业化进展"

	公司名称	可能的技术路线	开展时间	业务情况	链接地址
国外车企	丰田	硫化物	2008	2020年6月开始为概念车LQ配备全固态电池	https://www.toyota.ie/world-of-toyota/articles-news-events/2021/solid-state-batteries.json
	丰田	硫化物	2008	计划在2025年，实现全固态电池的小规模量产；到2030年，实现全固态电池持续的、稳定的量产
	本田	硫化物	2017	2017年自研固态电池	https://asia.nikkei.com/Business/Business-Spotlight/Can-Japan-and-Toyota-win-the-solid-state-battery-race
	本田	硫化物	2017	计划在 2022年3月底之前通过试生产线验证其全固态产品。目标在2030年将该产品商业化	https://www.protocol.com/bulletins/honda-ev-plan
	雷诺-三菱-日产联盟	硫化物	2017	2018年与丰田日产松下合作研发固态电池，从日本经济产业省获得了1400万美元的资金支持	https://asia.nikkei.com/Spotlight/Most-read-in-2020/Toyota-s-game-changing-solid-state-battery-en-route-for-2021-debut
	雷诺-三菱-日产联盟	硫化物	2017	2022年1月宣布在未来五年内向电动汽车投资230亿欧元(合259亿美元)，作为已有联盟的一部分。除了投资现有技术，该联盟的目标是在2028年年中实现全固态电池的大规模商业生产	https://www.motorauthority.com/news/1134880_renault-nissan-mitsubishi-alliance-plans-35-evs-solid-state-batteries-by-2030
	现代	硫化物、聚合物	2017	投资固态电池初创企业Ionic Materials	https://news.hyundaimotorgroup.com/MediaCenter/News/Press-Releases/hmc-CRADLE-180710
			2018	与三星SDI联合投资了Solid Power	https://www.hyundaimotorgroup.com/news/newsMain
			2021	2021年投资solid energy systems	https://www.hyundaimotorgroup.com/news/newsMain
	宝马	硫化物	2018	投资固态电池初创企业Solid Power	https://www.press.bmwgroup.com/global/article/detail/T0331495EN/bmw-group-strengthens-leadership-position-in-battery-technology-with-investment-in-solid-state-innovator-solid-power?language=en
	福特	硫化物	2019	投资固态电池初创企业Solid Power	https://media.ford.com/content/fordmedia/fna/us/en/news/2021/05/03/ford-boosts-investment-in-solid-power.html
	大众	氧化物	2018	投资固态电池初创企业QuantumScape 1亿美元，2020年追加2亿美元投资	https://fortune.com/2021/07/13/volkswagen-us-market-share-evs-autonomous-vehicles-tesla/
	博洛雷	聚合物	2008	2020年已获得欧洲109辆全固态电池大巴Bluebus订单	https://www.blue-solutions.com/en/media/
国外供应商	Quantum Scape	氧化物	2018	获大众集团(2018年向该公司投资1亿美元)、上汽集团、比尔·盖茨等的投资，2020年11月通过SPAC方式上市，计划2024年建立1 GWh试生产线。	https://www.autoevolution.com/news/quantumscape-will-now-sell-its-solid-state-batteries-to-a-fourth-carmaker-182980.html
	松下	卤化物	—	与丰田合作研究生产全固态电池，在中国投资9.1亿美元创办Prime Planet Energy & Solutions合资公司，业务包含全固态电池	https://asia.nikkei.com/Spotlight/Most-read-in-2020/Toyota-s-game-changing-solid-state-battery-en-route-for-2021-debut
	LG	—	—	计划2025年年底实现锂硫电池商业化，并在2025—2027年间实现全固态电池商业化	https://equalocean.com/briefing/20210429230043768
	富士通FDK	氧化物	—	2920万美元投资FDK开发固态电池，已启动超小型全固态电池的样品供货	https://www.fdk.com/whatsnew-e/release20190509-e.html
	OHARA	氧化物	—	开发基于玻璃陶瓷LICGC的全固态电池	https://www.oharacorp.com/lic-gc.html
	日立造船	硫化物	—	2018财年在太空领域投入使用，2020年后期量产电动汽车	https://asia.nikkei.com/Business/Energy/World-s-highest-capacity-solid-state-battery-developed-in-Japan
	三洋化成工业	聚合物	—	已布局全树脂固态电池，福井县越前市，将于2021年投产，总建筑面积约为8600平方米	https://www.sanyo-chemical.co.jp/eng/products_info/development/battery
	出光兴产	硫化物	—	2021年量产固态电池电解质，2023年EV固态电池实用，硫化物电解质专利全球第二	https://www.greencarcongress.com/2010/03/idemitsu-sulfide-20100307.html
	村田制作所	氧化物	—	滋贺县的工厂投入数亿日元制造全固体电池	https://www.murata.com/en-us/news/batteries/solid_state/2019/0626
	Ionic Materials	聚合物	1982	雷诺三菱日产联盟、韩国三星、英国戴森等科技业巨头已集体向Ionic Materials投资超过6500 万美元	https://www.idtechex.com/en/research-article/solid-state-battery-market-will-grow-to-8-billion-by-2031/24051
	Solid Energy Systems	—	2012	电池制造商SES Holdings Pte.已同意与艾芬豪资本收购公司(Ivanhoe Capital Acquisition Corp.)合并上市，合并后的公司估值约为36亿美元	https://www.bloomberg.com/news/articles/2021-07-13/ev-battery-maker-ses-said-to-agree-to-go-public-via-ivanhoe-spac
	Solid Power Battery	硫化物	2012	获得福特，A123，宝马等投资1.3亿美元	https://www.greencarcongress.com/2021/05/20210504-solidpower.html
	Solid Power Battery	硫化物	2012	2021年在纳斯达克上市	https://www.globenewswire.com/news-release/2021/12/08/2348686/0/en/Solid-Power-to-Trade-on-Nasdaq-as-SLDP-After-Completing-Business-Combination-with-Decarbonization-Plus-Acquisition-Corporation-III.html
	BlueSolutions (Bollore)	聚合物	2012	Bollore集团持续投资	https://www.electrive.com/2021/03/03/actually-we-are-the-pioneer-of-solid-state-battery/
	三星SDI	硫化物、聚合物	—	投资Solid Power，Ionic Materials，与LG，SK合作投入9000万美元研发电池技术	https://www.greentechmedia.com/articles/read/industry-giants-samsung-and-hyundai-invest-in-solid-state-batteries
	三星SDI	硫化物、聚合物	—	2022年3月14日分别宣布在其位于京畿道水原市Yeongtong-gu的一条占地6500平方米的全固态电池试验线“S-Line”动工	https://www.samsungsdi.com/sdi-news/2602.html?idx=2602
国内企业	清陶能源	—	2002	2002年创始人团队开始研发固态电池	http://www.jsqingtao.com/company.asp?ID=1
			2018	2018年建成国内第一条固态电池生产线，推出的高安全性、高能量密度、柔性化等固态电池产品，已在特种电源、高端数码等领域成功应用，在新能源汽车领域先行先试。	http://www.jsqingtao.com/chanye.asp?ID=48
			2022	2022年2月26日上午，总投资50亿元的清陶新能源固态锂电池产业化项目在昆山开发区破土动工，预计此次开工的固态锂电池产业化项目建成投产之后，将达到100亿瓦时年装机量	http://www.ks.gov.cn/kss/qzkx/202202/64d6a63da4424efd8255e390e175fdc0.shtml
	赣锋锂业	—	2017	56 Ah固态锂离子电池，能量密度240±5 Wh/kg，循环寿命≥1500次 10 Ah固态锂金属电池，能量密度350±5 Wh/kg，循环寿命≥300次固态锂电池模组，能量密度 ≥210 Wh/kg	http://www.ganfenglithium.com/product11/typeid/26.html
	赣锋锂业	—	2022	赣锋锂电已交付东风汽车50辆固态电池电动汽车	https://finance.eastmoney.com/a/202201232257768534.html
	辉能科技	—	2013	2013年实现固态电池量产在台湾建成1 GWh工厂	https://prologium.com/the-landing-of-solidstate-battery-car-is-on-the-clock-with-a-strong-entry-of-nio-together-with-prologium/
				2019年与蔚来汽车达成合作意向
				2022年获得梅赛德斯-奔驰数百万欧元投资，双方将共同开发下一代电动汽车固态电池电芯
	蜂巢能源	—	2018	蜂巢能源的原型样件能量密度达到350 Wh/kg，通过针刺和200 ℃热箱实验，预测循环寿命超过1000次；基于果冻电池技术的NCM短刀L600电池已经成功通过针刺试验，不起火，不冒烟，能量密度达到230 Wh/kg	https://www.thepaper.cn/newsDetail_forward_15972955
	卫蓝新能源	—	2016	2016年创办	http://www.solidstatelion.com/history/
				2019年溧阳产线开工，已于2020年7月投产
				2021年5月公司发明专利突破200件
				2022年2月25日下午，在山东淄博市齐鲁储能谷开工建设100 GWh固态锂电池项目，总投资400亿元

表4

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电解质材料	界面层材料	界面层种类	界面层制备方法
Li_1.5Al_0.5Ge_1.5(PO₄)₃^[21]	Ge	非晶	溅射
Li_1.5Al_0.5Ge_1.5(PO₄)₃^[22]	LiF/Li₃N	氟化物/氮化物	电化学预循环
Li_1.3Al_0.3Ti_1.7(PO₄)₃^[23]	BN	氮化物	CVD
Li_1.4Al_0.4Ti_1.6(PO₄)₃^[16]	ZnO	氧化物	溅射
Li_1.5Al_0.5Ti_1.5(PO₄)₃^[17]	Al₂O₃	氧化物	ALD
Li_1.5Al_0.5Ti_1.5(PO₄)₃^[24]	Li₃PO₄	氧化物	电解液浸泡
Li_1.4Ti₂Si_0.4P_2.6O₁₂-AlPO₄^[18]	LiPON	电解质	溅射
Li_1.5Al_0.5Ti_1.5(PO₄)₃^[19]	PEO	电解质	涂覆

电解质材料	润湿层材料	界面层种类	界面层制备方法
Li_6.375La₃Zr_1.375Nb_0.625O₁₂^[39]	Sn	金属	溅射
Li_6.85La_2.9Ca_0.1Zr_1.75Nb_0.25O₁₂^[38]	Si	非金属	CVD
Li_5.9Al_0.2La₃Zr_1.75W_0.25O₁₂^[39]	C	非金属	涂覆
Li₇La₃Zr₂O₁₂^[40]	Au	金属	溅射
Li_6.85La_2.9Ca_0.1Zr_1.75Nb_0.25O₁₂^[41]	Ge	金属	热蒸镀
Li₇La_2.75Ca_0.25Zr_1.75Nb_0.25O₁₂^[37]	Al₂O₃	氧化物	ALD
Li_6.5La₃Zr_1.5Ta_0.5O₁₂^[42]	MoS₂	硫化物	涂覆
Li_6.5La₃Zr_1.5Ta_0.5O₁₂^[43]	Li₃N	氮化物	原位反应
Li_6.4La₃Zr_1.4Ta_0.6O₁₂^[44]	LiF	氟化物	热蒸镀

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固态锂电池十年（2011—2021）回顾与展望

Review and prospective of solid-state lithium batteries in the past decade （2011—2021）

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