浅析电解质中离子输运的微观物理图像

任元; 邹喆乂; 赵倩; 王达; 喻嘉; 施思齐

doi:10.7498/aps.69.20201519

摘要

解析离子在电解质中的输运特征所表现出的微观物理图像, 对于调控离子传导行为具有重要的指导意义. 本文系统总结了离子在液态、有机聚合物和无机固态电解质中的离子输运物理图像及其影响因素, 通过分析各种输运物理模型并比较三类电解质中的离子输运机制, 提炼出勾勒离子输运物理图像的相关描述因子. 输运介质的物理形态从连续流体到柔性载体再到刚性骨架的演变过程中, 离子输运图像由各类电解质的固有属性与外部条件共同刻画, 其中介质无序性占据主导作用. 揭示电解质结构和离子电导率及输运过程等动力学行为之间的科学规律, 有利于发展基于离子输运微观物理图像的传导离子动力学性能调控方法.

关键词:

Abstract

Analyzing the microscopic physical image of the ion transport characteristics has important guiding significance for improving the ion conduction behavior in the electrolytes. In this article, we summarize the factors influencing the physical images of ion transport in liquid, organic polymer and inorganic solid electrolytes. The descriptive factors relating to the ion transport physical image are refined by analyzing various transport physical models and comparing the ion transport mechanisms in the three types of electrolytes. In the evolution of the physical state from continuous fluid to flexible carrier to rigid framework, the ion transport image is characterized by the inherent properties of various electrolytes and external conditions, in which the disorder of the medium plays a dominant role. Revealing the relationships between the electrolyte structure and dynamic behaviors with the ion conductivity and transport process is conducive to the development of the method of controlling the dynamic performance of conducting ion based on the microphysical image of ion transport.

Keywords:

作者及机构信息

1.
上海大学材料科学与工程学院, 上海　200444

2.
内蒙古科技大学机械工程学院, 包头　014010

3.
湘潭大学材料科学与工程学院，湘潭　411105

4.
上海大学材料基因组工程研究院, 上海　200444

通信作者: 施思齐, sqshi@shu.edu.cn

基金项目: 国家自然科学基金(批准号: 11874254, 51702170, 51802187, 51622207)、上海市青年科技英才扬帆计划(批准号: 18YF1408700)和内蒙古自然科学基金(批准号: 2020MS05036)资助的课题

Authors and contacts

1.
School of Materials Science and Engineering, Shanghai University, Shanghai 200444, China

2.
School of Mechanical Engineering, Inner Mongolia University of Science & Technology, Baotou, Inner Mongolia 014010, China

3.
School of Materials Science and Engineering, Xiangtan University, Xiangtan, Hunan 411105, China

4.
Materials Genome Institute, Shanghai University, Shanghai 200444, China

Corresponding author: Shi Si-Qi, sqshi@shu.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 11874254, 51702170, 51802187, 51622207), the Sailing Program of Shanghai, China (Grant No. 18YF1408700), and the Natural Science Foundation of Inner Mongolia Autonomous Region, China (Grant No. 2020MS05036)

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参考文献

[1]	Mehrer H 2007 Diffusion in Solids: Fundamentals, Methods, Materials, Diffusion- Controlled Processes (Springer: Berlin, Heidelberg) pp27−36
[2]	Chen R S, Li Q H, Yu X Q, Chen L Q, Li H 2020 Chem. Rev. 120 6820 Google Scholar
[3]	Xu K 2004 Chem. Rev. 104 4303 Google Scholar
[4]	Xu K, Lam Y, Zhang S S, Jow T R, Curtis T B 2007 J. Phys. Chem. C 111 7411 Google Scholar
[5]	Xu K 2014 Chem. Rev. 114 11503 Google Scholar
[6]	Winter M, Barnett B, Xu K 2018 Chem. Rev. 118 11433 Google Scholar
[7]	Li M, Wang C S, Chen Z W, Xu K, Lu J 2020 Chem. Rev. 120 6783 Google Scholar
[8]	Zou Z Y, Li Y J, Lu Z H, Wang D, Cui Y H, Guo B K, Li Y J, Liang X M, Feng J W, Li H, Nan C W, Armand M, Chen L Q, Xu K, Shi S Q 2020 Chem. Rev. 120 4169 Google Scholar
[9]	Gao Y R, Nolan A M, Du P, Wu Y F, Yang C, Chen Q L, Mo Y F, Bo S H 2020 Chem. Rev. 120 5954 Google Scholar
[10]	Borodin O, Self J L, Persson K A, Wang C S, Xu K 2020 Joule 4 69 Google Scholar
[11]	Wang C W, Fu K, Kammampata S P, McOwen D W, Samson A J, Zhang L, Hitz G T, Nolan A M, Wachsman E D, Mo Y F, Thangadurai V, Hu L B 2020 Chem. Rev. 120 4257 Google Scholar
[12]	Fick A 1855 Annalen der Physik und Chemie 94 59
[13]	Park M, Zhang X C, Chung M, Less G B, Sastry A M 2010 J. Power Sources 195 7904 Google Scholar
[14]	Wilkinson DS 2000 Mass Transport in Solid and Fluids (Cambridge: Cambridge University Press) pp47−50
[15]	Aziz S B, Woo T J, Kadir M F Z, Ahmed H M 2018 J. Sci.-Adv. Mater. Dev. 3 1
[16]	Quartarone E, Mustarelli P 2011 Chem. Soc. Rev. 40 2525 Google Scholar
[17]	Catlow C R A 1983 Solid State Ionics 8 89 Google Scholar
[18]	Vargas-Barbosa N M, Roling B 2020 ChemElectroChem 7 367 Google Scholar
[19]	Le Claire A 1970 In Diffusion in Solids: Fundamentals, Methods, Materials, Diffusion Controlled Processes (Heidelberg: Springer) p10
[20]	Zhao Q, Pan L, Li Y J, Chen L Q, Shi S Q 2018 Rare Met. 37 497 Google Scholar
[21]	Shi S Q, Lu P, Liu Z Y, Qi Y, Hector Jr. L G, Li H, Harris S J 2012 J. Am. Chem. Soc. 134 15476 Google Scholar
[22]	Zhang L W, He B, Zhao Q, Zou Z Y, Chi S T, Mi P H, Ye A J, Li Y J, Wang D, Avdeev M, Adams S, Shi S Q 2020 Adv. Funct. Mater. 30 2003087 Google Scholar
[23]	Zou Z Y, Ma N Y, Wang A P, Ran Y B, Song T, Jiao Y, Liu J P, Zhou H, Shi W, He B, Wang D, Li Y J, Avdeev M, Shi S Q 2020 Adv. Energy Mater. 10 2001486 Google Scholar
[24]	Cresce A v W, Xu K 2011 J. Electrochem. Soc. 158 A337 Google Scholar
[25]	Xu K 2007 J. Electrochem. Soc. 154 A162 Google Scholar
[26]	Zheng J X, Hou Y Y, Duan Y D, Song X H, Wei Y, Liu T C, Hu J T, Guo H, Zhuo Z Q, Liu L L, Chang Z, Wang X W, Zherebetskyy D, Fang Y Y, Lin Y, Xu K, Wang L W, Wu Y P, Pan F 2015 Nano Lett. 15 6102 Google Scholar
[27]	Ratner M A, Shriver D F 1988 Chem. Rev. 88 109 Google Scholar
[28]	MacGlashan G S, Andreev Y G, Bruce P G 1999 Nature 398 792 Google Scholar
[29]	Xue Z, He D, Xie X 2015 J. Mater. Chem. A 3 19218 Google Scholar
[30]	陈立坤, 胡懿, 马家宾, 黄妍斐, 俞静, 贺艳兵, 康飞宇 2020 化学工业与工程 37 2 Chen L K, Hu Y, Ma J B, Huang Y F, Yu J, He Y B, Kang F Y 2020 Chem Industry And Engineering 37 2
[31]	Meyer W H 1998 Adv. Mater. 10 439 Google Scholar
[32]	Adachi G Y, Imanaka N, Aono H 1996 Adv. Mater. 8 127 Google Scholar
[33]	Fleig J 2003 Solid State Ionics 161 279 Google Scholar
[34]	Wang S F, Chen L Q 2016 Chin. Phys. B 25 018202 Google Scholar
[35]	Pan J, Zhang Q L, Xiao X C, Cheng Y T, Qi Y 2016 ACS Appl. Mater. Interfaces 8 5687 Google Scholar
[36]	Ren Y, Qi Z H, Zhang C, Yang S B, Ma X Y, Liu X J, Tan X, Sun S Y, Cao Y N 2020 Comput. Mater. Sci. 176 109535 Google Scholar
[37]	Li Y T, Xu B Y, Xu H H, Duan H N, Lü X J, Xin S, Zhou W D, Xue L G, Fu G T, Manthiram A, Goodenough J B 2017 Angew. Chem. Int. Ed. 56 753 Google Scholar
[38]	Wert C 1950 Phys. Rev. 79 601 Google Scholar
[39]	Vineyard G 1957 J. Phys. Chem. Sol. 3 121 Google Scholar
[40]	Funke K 1993 Prog. Solid State Chem. 22 111 Google Scholar
[41]	He X F, Zhu Y Z, Mo Y F 2017 Nat. Commun. 8 15893 Google Scholar
[42]	Zhang B K, Yang L Y, Wang L W, Pan F 2019 Nano Energy 62 844 Google Scholar
[43]	de Klerk N J J, van der Maas E, Wagemaker M 2018 ACS Appl. Energy Mater. 1 3230 Google Scholar
[44]	Zhu Z, Chu I H, Deng Z, Ong S P 2015 Chem. Mater. 27 8318 Google Scholar
[45]	Zhang Z Z, Zou Z Y, Kaup K, Xiao R J, Shi S Q, Avdeev M, Hu Y S, Wang D, He B, Li H, Huang X J, Nazar L F, Chen L Q 2019 Adv. Energy Mater. 9 1902373 Google Scholar
[46]	Agmon N 1995 Chem. Phys. Lett. 244 456 Google Scholar
[47]	Lang B, Ziebarth B, Elsässer C 2015 Chem. Mater. 27 5040 Google Scholar
[48]	Hu P, Zou Z Y, Sun X W, Wang D, Ma J, Kong Q Y, Xiao D D, Gu L, Zhou X H, Zhao J W, Dong S M, He B, Avdeev M, Shi S Q, Cui G L, Chen L Q 2020 Adv. Mater. 32 1907526 Google Scholar
[49]	Li J, Guan M X, Nan P F, Wang J, Ge B H, Qiao K M, Zhang H R, Liang W H, Hao J Z, Zhou H B, Shen F R, Liang F X, Zhang C, Liu M, Meng S, Zhu T, X Hu F, Wu T, Guo J D, Sun J R, Shen B G 2020 Nano Energy 78 105215 Google Scholar
[50]	Yamada Y, Wang J, Ko S, Watanabe E, Yamada A 2019 Nat. Energy 4 269 Google Scholar
[51]	Geoffroy I, Willmann P, Mesfar K, CarréB, Lemordant D 2000 Electrochim. Acta 45 2019 Google Scholar
[52]	Ding M S, Jow T R 2003 J. Electrochem. Soc. 150 A620 Google Scholar
[53]	Blint R J 1995 J. Electrochem. Soc. 142 696 Google Scholar
[54]	Chagnes A, Carré B, Willmann P, Lemordant D 2002 J. Power Sources 109 203 Google Scholar
[55]	Hayamizu K, Aihara Y 2004 Electrochim. Acta 49 3397 Google Scholar
[56]	Brodd R J, Huang W, Akridge J R 2000 Macromol. Symp. 159 229 Google Scholar
[57]	Yang Y Y C, Davies D M, Yin Y J, Borodin O, Lee J Z, Fang C C, Olguin M, Zhang Y H, Sablina E S, Wang X F, Rustomji C S, Meng Y S 2019 Joule 3 1 Google Scholar
[58]	Lukatskaya M R, Feldblyum J I, Mackanic D G, Lissel F, Michels D L, Cui Y, Bao Z N 2018 Energy Environ. Sci. 11 2876 Google Scholar
[59]	Ohno H 2005 Electrochemical Aspects of Ionic Liquids (Wiley Interscience) pp1−3
[60]	Webber A, Blomgren G E 2002 Advances in Lithium-Ion Batteries (Kluwer: Academic/Plenum Publishers) pp185−232
[61]	Lee J S, Bae J Y, Lee H, Quan N D, Kim H S, Kim H 2004 J. Ind. Eng. Chem. 10 1086
[62]	Ishikawa M, Sugimoto T, Kikuta M, Ishiko E, Kono M 2006 J. Power Sources 162 658
[63]	Zhang X Q, Chen X, Hou L P, Li B Q, Cheng X B, Huang J Q, Zhang Q 2019 ACS Energy Lett. 4 411 Google Scholar
[64]	Chang Z, Qiao Y, Deng H, Yang H J, He P, Zhou H S 2020 Joule 4 1 Google Scholar
[65]	Suo L M, Hu Y S, Li H, Armand M, Chen L Q 2013 Nat. Commun. 4 1481 Google Scholar
[66]	Suo L M, Fang Z, Hu Y S, Chen L Q 2016 Chin. Phys. B 25 016101 Google Scholar
[67]	Guo Z L, Wang T S, Wei H H, Long Y Z, Yang C, Wang D, Lang J L, Huang K, Hussain N, Song C X, Guan B, Ge B H, Zhang Q F, Wu H 2019 Angew. Chem. Int. Ed. 131 12699 Google Scholar
[68]	Fenton D E, Parker J M, Wright P V 1973 Polymer 14 589 Google Scholar
[69]	Armand M B, Chabagno J M, Duclot M J 1979 Fast Ion Transport in Solids (New York: Elsevier) p131
[70]	Cho Y G, Hwang C, Cheong D S, Kim Y S, Song H K 2019 Adv. Mater. 31 1804909 Google Scholar
[71]	Zhou D, He Y B, Liu R L, Liu M, Du H D, Li B H, Cai Q, Yang Q H, Kang F Y 2015 Adv. Energy Mater. 5 1500353 Google Scholar
[72]	Bouchet R, Maria S, Meziane R, Aboulaich A, Lienafa L, Bonnet J-P, Phan T N T, Bertin D, Gigmes D, Devaux D, Denoyel R, Armand M 2013 Nat. Mater. 12 452 Google Scholar
[73]	Yu Z, Mackanic D G, Michaels W, Lee M, Pei A, Feng D W, Zhang Q H, Tsao Y C, Amanchukwu C V, Yan X Z, Wang H S, Chen S C, Liu K, Kang J H, Qin J, Cui Y, Bao Z N 2019 Joule 3 2761 Google Scholar
[74]	Amanchukwu C, Yu Z, Kong X, Qin J, Cui Y, Bao Z N 2020 J. Am. Chem. Soc. 142 7393 Google Scholar
[75]	Mackanic D G, Michaels W, Lee M, Feng D W, Lopez J, Qin J, Cui Y, Bao Z N 2018 Adv. Energy Mater. 8 1800703 Google Scholar
[76]	Lopez J, Sun Y M, Mackanic D G, Lee M, Foudeh A M, Song M S, Cui Y, Z N Bao 2018 Adv. Mater. 30 1804142 Google Scholar
[77]	Mackanic D G, Yan X Z, Zhang Q H, Matsuhisa N J, Yu Z, Jiang Y W, Manika T, Lopez J, Yan H P, Liu K, Chen X D, Cui Y, Bao Z N 2019 Nat. Commun. 10 5384 Google Scholar
[78]	Wan J Y, Xie J, Kong X, Liu Z, Liu K, Shi F F, Pei A, Chen H, Chen W, Chen J, Zhang X K, Zong L Q, Wang J Y, Chen L Q, Qin J, Cui Y 2019 Nat. Nanotechnol. 14 705 Google Scholar
[79]	Kato T, Yoshio M, Ichikawa T, Soberats B, Ohno H, Funahashi M 2017 Nat. Rev. Mater. 2 17001 Google Scholar
[80]	Kimura K, M Hirao, Yokoyama M 1991 J. Mater. Chem. 1 293 Google Scholar
[81]	李昕桐, 张霖琛, 张焕瑞, 张波涛, 崔光磊 2020 储能科学与技术 9 1595 Li X T, Zhang L C, Zhang H R, Zhang B T, Cui G L 2020 Energy Storage Sci. Technol. 9 1595
[82]	Chen L, Li Y T, Li S P, Fan L Z, Nan C W, Goodenough J B 2018 Nano Energy 46 176 Google Scholar
[83]	赵宁, 李忆秋, 张静娴, 狄增峰, 郭向欣 2016 储能科学与技术 5 754 Google Scholar Zhao N, Li Y Q, Zhang J X, Di Z F, Guo X X 2016 Energy Storage Sci. Technol. 5 754 Google Scholar
[84]	Huo H Y, Li X N, Chen Y, Liang J N, Deng S X, Gao X J, Kieran Doyle-Davis, Li R Y, Guo X X, Shen Y, Nan C W, Sun X L 2020 Energy Storage Mater. 29 361 Google Scholar
[85]	林祖纕, 郭祝崑, 孙成文, 李世椿, 陈昆刚, 田顺宝, 严东生 1983 快离子导体(固体电解质)基础、材料、应用(上海: 上海科学技术出版社) 第1—4页 Li Z X, Guo Z K, Sun C W, Li S C, Chen K G, Tian S B, Yan D S 1983 Fast ion conductor (solid electrolyte) basis, material, application (Shanghai: Shanghai Science and Technology Press) pp1–4 (in Chinese）[
[86]	萨拉蒙M B著 (王刚刘长乐译, 陈立泉校) 1984 快离子导体物理(北京: 科学出版社)第1—4页 Salamon M B (translated by Wang G Liu C L, Proof by Chen L Q)1984 Physics of Superionic Conductors (Beijing: Science Press) pp1–4 (in Chinese）[
[87]	Murugan R, Thangadurai V, Weppner W 2007 Angew. Chem. Int. Ed. 46 7778 Google Scholar
[88]	Du F M, Zhao N, Li Y Q, Chen C, Liu Z W, Guo X X 2015 J. Power Sources 300 24 Google Scholar
[89]	Jalem R, Yamamoto Y, Shiiba H, Nakayama M, Munakata H, Kasuga T, Kanamura K 2013 Chem. Mater. 25 425 Google Scholar
[90]	Zhao N, Khokhar W, Bi Z J, Shi C, Guo X X, Fan L Z, Nan C W 2019 Joule 3 1190 Google Scholar
[91]	Hong H Y P 1976 Mater. Res. Bull. 11 173 Google Scholar
[92]	Hong Y P, Kafalas J A, Bayard M 1978 Mater. Res. Bull. 13 757 Google Scholar
[93]	Goodenough J B, Hong H Y P, Kafalas J A 1976 Mater. Res. Bull. 11 203 Google Scholar
[94]	Zhang Z Z, Zhang Q H, Shi J N, Chu Y S, Yu X Q, Xu K Q, Ge M Y, Yan H F, Li W J, Gu L, Hu Y S, Li H, Yang X Q, Chen L Q, Huang X J 2016 Adv. Energy Mater. 7 1601196 Google Scholar
[95]	Aono H, Sugimoto E, Sadaoka Y, Imanaka N, Adachi G 1990 J. Electrochem. Soc. 137 1023 Google Scholar
[96]	Lin Z, Li S, Tian S, Yu H 1984 Sci. Sin. (Ser. A) 27 889
[97]	Lu X, Wang S H, Xiao R J, Shi S Q, Li H, Chen L Q 2017 Nano Energy 41 626 Google Scholar
[98]	Bay M C, Wang M, Grissa R, Heinz M V F, Sakamoto J, Battaglia C 2020 Adv. Energy Mater. 10 1902899 Google Scholar
[99]	Lei D, He Y B H, Huang, Yuan Y, Zhong G, Zhao Q, Hao X, Zhang D, Lai C, Zhang S 2019 Nat. Commun. 10 4244 Google Scholar
[100]	Sudworth J L 1984 J. Power Sources 11 143 Google Scholar
[101]	Jolly D S, Ning Z, Darnbrough J E, Kasemchainan J, Hartley G O, Adamson P, Armstrong D E J, Marrow J, Bruce P G 2020 ACS Appl. Mater. Interfaces 12 678 Google Scholar
[102]	Kanno R, Murayama M 2001 J. Electrochem. Soc. 148 A742 Google Scholar
[103]	Kamaya N, Homma K, Yamakawa Y, Hirayama M, Kanno R, Yonemura M, Kamiyama T, Kato Y, Hama S, Kawamoto K, Mitsui A 2011 Nat. Mater. 10 682 Google Scholar
[104]	Kato Y, Hori S, Saito T, Suzuki K, Hirayama M, Mitsui A, Yonemura M, Iba H, Kanno R 2016 Nat. Energy 1 16030 Google Scholar
[105]	刘丽露, 吴凡, 李泓, 陈立泉 2019 硅酸盐学报 47 1367 Liu L L, Wu F, Li H, Chen L Q 2019 J. Chin. Ceram. Soc. 47 1367
[106]	Wang X L, Xiao R J, Li H, Chen L Q 2017 Phys. Rev. Lett. 118 195901 Google Scholar
[107]	Takagi S, Ikeshoji T, Sato T, Orimo S 2020 Appl. Phys. Lett. 116 173901 Google Scholar
[108]	Smith J G, Siegel D J 2020 Nat. Commun. 11 1483 Google Scholar
[109]	Li X N, Liang J W, Yang X F, Adair K R, Wang C S, Zhao F P, Sun X L 2020 Energy Environ. Sci. 13 1429 Google Scholar
[110]	Asano T, Sakai A, Ouchi S, Sakaida M, Miyazaki A, Hasegawa S 2018 Adv. Mater. 30 1803075 Google Scholar
[111]	Wang S, Bai Q, Nolan A M, Liu Y S, Gong S, Sun Q, Mo Y F 2019 Angew. Chem. Int. Ed. 58 8039 Google Scholar
[112]	Schlem R, Muy S, Prinz N, Banik A, Horn Y, Zobel M, Zeier W 2019 Adv. Energy Mater. 10 1903719 Google Scholar
[113]	Liang J W, Li X N, Wang S, Adair K R, Li W H, Zhao Y, Wang C H, Hu Y F, Zhang L, Zhao S Q, Lu S G, Huang H, Li R Y, Mo Y F, Sun X L 2020 J. Am. Chem. Soc. 142 7012 Google Scholar
[114]	Park K, Kaup K, Assoud A, Zhang Q, Wu X, Nazar L 2020 ACS Energy Lett. 5 533 Google Scholar
[115]	Ming J, Cao Z, Wahyudi W, Li M L, Kumar P, Wu Y Q, Hwang J Y, Hedhili M N, Cavallo L, Sun Y K, Li L J 2018 ACS Energy Lett. 3 335 Google Scholar
[116]	Rolland J, Poggi E, Vlad A, Gohy J F 2015 Polymer 68 344 Google Scholar
[117]	Shi S Q, Gao J, Liu Y, Zhao Y, Wu Q, Ju W W, Ouyang C Y, Xiao R J 2016 Chin. Phys. B 25 018212 Google Scholar
[118]	Gao J, Zhao Y S, Shi S Q, Li H 2016 Chin. Phys. B 25 018211 Google Scholar
[119]	Lou S F, Yu Z J, Liu Q S, Wang H, Chen M, Wang J J 2020 Chem. 6 1 Google Scholar
[120]	He B, Chi S T, Ye A J, Mi P H, Zhang L W, Pu B W, Zou Z Y, Ran Y B, Zhao Q, Wang D, Zhang W Q, Zhao J T, Adams S, Avdeev M, Shi S Q 2020 Sci. Data 7 151 Google Scholar
[121]	He B, Ye A J, Chi S T, Mi P H, Ran Y B, Zhang L W, Zou X X, Pu B W, Zhao Q, Zou Z Y, Wang D, Zhang W Q, Zhao J T, Avdeev M, Shi S Q 2020 Sci. Data 7 153 Google Scholar
[122]	He B, Mi P H, Ye A J, Chi S T, Jiao Y, Zhang L W, Pu B W, Zou Z Y, Zhang W Q, Avdeev M, Adams S, Zhao J T, Shi S Q 2021 Acta Mater. 203 116490 (SPSE 平台https://matgen.nscc-gz.cn/solidElectrolyte/
[123]	Pan L, Zhang LW, Ye A J, Chi S T, Zou Z Y, He B, Chen L L, Zhao Q, Wang D, Shi S Q 2019 J. Materiomics 5 688 Google Scholar
[124]	Yang Y H, Wu Q, Cui Y H, Chen Y C, Shi S Q, Wang R Z, Yan H 2016 ACS Appl. Mater. Interfaces 8 25229 Google Scholar
[125]	Li Y J, Zhao Y, Cui Y H, Zou Z Y, Wang D, Shi S Q 2018 Comput. Mater. Sci. 144 338 Google Scholar
[126]	Famprikis T, Canepa P, Dawson J A, Islam M S, Masquelier C 2019 Nat. Mater. 18 1278 Google Scholar
[127]	Huang Y W, He Y, Sheng H, Lu X, Dong H N, Samanta S, Dong H L, Li X F, Kim D Y, Mao H K, Liu Y Z, Li H P, Li H, Wang L 2019 Natl. Sci. Rev. 6 239 Google Scholar
[128]	Zhang T F, Wang Y M, Song T, Miyaoka H, Shinzato K, Miyaoka H, Ichikawa T, Shi S Q, Zhang X G, Isobe S, Hashimoto N, Kojima Y 2018 Joule 2 1 Google Scholar
[129]	Lu X, Wang S H, Xiao R J, Shi S Q, Li H, Chen L Q 2017 Nano Energy. 41 626
[130]	Shi S Q, Xu L F, Ouyang C Y, Wang Z X, Chen L Q 2006 Ionics 12 343 Google Scholar
[131]	Liu F C, Shadike Z, Wang X F, Shi S Q, Zhou Y N, Chen G Y, Yang X Q, Weng L H, Zhao J T, Fu Z W 2016 Inorg. Chem. 55 6504 Google Scholar
[132]	Liu Y, Zhao T L, Ju W W, Shi S Q 2017 J. Materiomics 3 159 Google Scholar
[133]	Liu Y, Guo B R, Zou X X, Li Y J, Shi S Q 2020 Energy Storage Mater. 31 434 Google Scholar
[134]	张更, 王巧, 沙立婷, 李亚捷, 王达, 施思齐 2020 物理学报 69 226401 Zhang G, Wang Q, Sha L T, Li Y J, Wang D, Shi S Q 2020 Acta Phys. Sin. 69 226401

施引文献

图 1 可供离子输运的电解质, 包括: 液态电解质、聚合物基固态电解质、无机固态电解质以及复合固态电解质

Fig. 1. The electrolytes for ion transport: liquid electrolyte, polymer-based solid electrolyte, inorganic solid electrolyte and composite solid electrolyte.

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图 2 影响离子输运微观物理图像的因素包括输运机制与描述因子. 如: 左上角knock-off离子输运^[21]; 右上角: BVSE方法描述离子输运通道^[22]; 左下角: NASICON中多离子协同输运^[23]; 复合结构电解质离子输运^[8]

Fig. 2. The factors affecting the microscopic physical image of ion transport: transport mechanism and description factors. For example: knock-off ion transport^[21], BVSE method based ion transport channel description^[22], multi-ion coordinated transport in NASICON^[23], mobile ion in composite solids^[8].

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图 3 液态电解质溶剂化与去溶剂化动力学过程中携带式离子输运方式示意图

Fig. 3. The schematic diagram of portable ion transport in the kinetic process of solvation and desolvation of liquid electrolyte.

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图 4 有机聚合物基固态电解质中离子在配位之间传递输运方式示意图

Fig. 4. The schematic diagram of ion transport between coordination in the organic polymer-based solid electrolyte.

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图 5 无机固态电解质中离子输运方式:　(a)传导离子在晶体内输运方式示意图; (b)传导离子沿晶界输运方式示意图; (c)传导离子跨晶界输运方式示意图

Fig. 5. The ion transport in the inorganic solid electrolytes: (a) The ion transport in the bulk; (b) the ion transport along the grain boundaries; (c) the ion transport across the grain boundaries.

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图 6 无机固态电解质中晶体内离子间隙扩散输运方式：(a)离子直接在间隙中迁移示意图; (b)离子在空位之间迁移示意图

Fig. 6. The ion interstitial diffusion transport in the inorganic solid electrolytes: (a) The interstitial ion transport; (b) the vacant ion transport.

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图 7 无机固态电解质中输运离子与骨架离子换位协同输运示意图

Fig. 7. The concerted and coordinated diffusion of transport ion and skeleton ion in the inorganic solid electrolytes.

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图 8 电解质中主导离子输运微观物理图像的因素由结构主导作用到介质主导作用的演变过程^[10]

Fig. 8. The evolution process between structural and vehicular effect the microscopic physical image of the contribution to the ion transport in the electrolytes^[10].

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图 9 “聚合物陶瓷”和“陶瓷聚合物”电解质系统中可能的离子传输机制^[82]

Fig. 9. The schematic diagram of possible ion transport mechanisms in "ceramic-in-polymer" and "polymer-in-ceramic" electrolyte system^[82].

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图 10 传导离子在LTMH (Li₃TMCl₆)中输运特性　(a) Li⁺在$ P\bar 3 m1$ Li₃YCl₆中输运路径^[110]; (b) Li⁺在hcp阴离子晶格Li₃YCl₆中输运路径^[111]; (c) Li⁺在Li₃ErCl₆和Li₃YCl₆中的输运行为^[112]; (d) Li⁺在ccp阴离子晶格Li₃ScCl₆中输运路径^[113]

Fig. 10. Transport characteristics of conductive ions in LTMH (Li₃TMCl₆): (a) The ion transport in Li₃YCl₆ with space group $P\bar 3 m1$^[110]; (b) the ion transport in Li₃YCl₆ with hcp-like Anion lattice^[111]; (c) the ion transport in Li₃MCl₆ (M = Y, Er) with space group $P\bar 3 m1$^[112]; (d) the ion transport in Li₃ScCl₆ with ccp Anion lattice^[113].

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图 11 液态、聚合物以及无机固态电解质离子运输形式　(a) 液态电解质中溶剂分子协调离子输运^[115]; (b) 聚合物基电解质中链段运动与离子输运^[116]; (c) 具有骨架通道NASICON中多离子协同输运^[23]

Fig. 11. Transport form of ion in the liquid, organic polymer and inorganic solid electrolytes: (a) Li⁺ coordination in electrolyte^[115]; (b) Ion coordinated transport in the single-ion solid-state polymer electrolytes^[116]; (c) Concerted migration of multi-ion in NASICON with framework channels^[23].

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[1]	Mehrer H 2007 Diffusion in Solids: Fundamentals, Methods, Materials, Diffusion- Controlled Processes (Springer: Berlin, Heidelberg) pp27−36
[2]	Chen R S, Li Q H, Yu X Q, Chen L Q, Li H 2020 Chem. Rev. 120 6820 Google Scholar
[3]	Xu K 2004 Chem. Rev. 104 4303 Google Scholar
[4]	Xu K, Lam Y, Zhang S S, Jow T R, Curtis T B 2007 J. Phys. Chem. C 111 7411 Google Scholar
[5]	Xu K 2014 Chem. Rev. 114 11503 Google Scholar
[6]	Winter M, Barnett B, Xu K 2018 Chem. Rev. 118 11433 Google Scholar
[7]	Li M, Wang C S, Chen Z W, Xu K, Lu J 2020 Chem. Rev. 120 6783 Google Scholar
[8]	Zou Z Y, Li Y J, Lu Z H, Wang D, Cui Y H, Guo B K, Li Y J, Liang X M, Feng J W, Li H, Nan C W, Armand M, Chen L Q, Xu K, Shi S Q 2020 Chem. Rev. 120 4169 Google Scholar
[9]	Gao Y R, Nolan A M, Du P, Wu Y F, Yang C, Chen Q L, Mo Y F, Bo S H 2020 Chem. Rev. 120 5954 Google Scholar
[10]	Borodin O, Self J L, Persson K A, Wang C S, Xu K 2020 Joule 4 69 Google Scholar
[11]	Wang C W, Fu K, Kammampata S P, McOwen D W, Samson A J, Zhang L, Hitz G T, Nolan A M, Wachsman E D, Mo Y F, Thangadurai V, Hu L B 2020 Chem. Rev. 120 4257 Google Scholar
[12]	Fick A 1855 Annalen der Physik und Chemie 94 59
[13]	Park M, Zhang X C, Chung M, Less G B, Sastry A M 2010 J. Power Sources 195 7904 Google Scholar
[14]	Wilkinson DS 2000 Mass Transport in Solid and Fluids (Cambridge: Cambridge University Press) pp47−50
[15]	Aziz S B, Woo T J, Kadir M F Z, Ahmed H M 2018 J. Sci.-Adv. Mater. Dev. 3 1
[16]	Quartarone E, Mustarelli P 2011 Chem. Soc. Rev. 40 2525 Google Scholar
[17]	Catlow C R A 1983 Solid State Ionics 8 89 Google Scholar
[18]	Vargas-Barbosa N M, Roling B 2020 ChemElectroChem 7 367 Google Scholar
[19]	Le Claire A 1970 In Diffusion in Solids: Fundamentals, Methods, Materials, Diffusion Controlled Processes (Heidelberg: Springer) p10
[20]	Zhao Q, Pan L, Li Y J, Chen L Q, Shi S Q 2018 Rare Met. 37 497 Google Scholar
[21]	Shi S Q, Lu P, Liu Z Y, Qi Y, Hector Jr. L G, Li H, Harris S J 2012 J. Am. Chem. Soc. 134 15476 Google Scholar
[22]	Zhang L W, He B, Zhao Q, Zou Z Y, Chi S T, Mi P H, Ye A J, Li Y J, Wang D, Avdeev M, Adams S, Shi S Q 2020 Adv. Funct. Mater. 30 2003087 Google Scholar
[23]	Zou Z Y, Ma N Y, Wang A P, Ran Y B, Song T, Jiao Y, Liu J P, Zhou H, Shi W, He B, Wang D, Li Y J, Avdeev M, Shi S Q 2020 Adv. Energy Mater. 10 2001486 Google Scholar
[24]	Cresce A v W, Xu K 2011 J. Electrochem. Soc. 158 A337 Google Scholar
[25]	Xu K 2007 J. Electrochem. Soc. 154 A162 Google Scholar
[26]	Zheng J X, Hou Y Y, Duan Y D, Song X H, Wei Y, Liu T C, Hu J T, Guo H, Zhuo Z Q, Liu L L, Chang Z, Wang X W, Zherebetskyy D, Fang Y Y, Lin Y, Xu K, Wang L W, Wu Y P, Pan F 2015 Nano Lett. 15 6102 Google Scholar
[27]	Ratner M A, Shriver D F 1988 Chem. Rev. 88 109 Google Scholar
[28]	MacGlashan G S, Andreev Y G, Bruce P G 1999 Nature 398 792 Google Scholar
[29]	Xue Z, He D, Xie X 2015 J. Mater. Chem. A 3 19218 Google Scholar
[30]	陈立坤, 胡懿, 马家宾, 黄妍斐, 俞静, 贺艳兵, 康飞宇 2020 化学工业与工程 37 2 Chen L K, Hu Y, Ma J B, Huang Y F, Yu J, He Y B, Kang F Y 2020 Chem Industry And Engineering 37 2
[31]	Meyer W H 1998 Adv. Mater. 10 439 Google Scholar
[32]	Adachi G Y, Imanaka N, Aono H 1996 Adv. Mater. 8 127 Google Scholar
[33]	Fleig J 2003 Solid State Ionics 161 279 Google Scholar
[34]	Wang S F, Chen L Q 2016 Chin. Phys. B 25 018202 Google Scholar
[35]	Pan J, Zhang Q L, Xiao X C, Cheng Y T, Qi Y 2016 ACS Appl. Mater. Interfaces 8 5687 Google Scholar
[36]	Ren Y, Qi Z H, Zhang C, Yang S B, Ma X Y, Liu X J, Tan X, Sun S Y, Cao Y N 2020 Comput. Mater. Sci. 176 109535 Google Scholar
[37]	Li Y T, Xu B Y, Xu H H, Duan H N, Lü X J, Xin S, Zhou W D, Xue L G, Fu G T, Manthiram A, Goodenough J B 2017 Angew. Chem. Int. Ed. 56 753 Google Scholar
[38]	Wert C 1950 Phys. Rev. 79 601 Google Scholar
[39]	Vineyard G 1957 J. Phys. Chem. Sol. 3 121 Google Scholar
[40]	Funke K 1993 Prog. Solid State Chem. 22 111 Google Scholar
[41]	He X F, Zhu Y Z, Mo Y F 2017 Nat. Commun. 8 15893 Google Scholar
[42]	Zhang B K, Yang L Y, Wang L W, Pan F 2019 Nano Energy 62 844 Google Scholar
[43]	de Klerk N J J, van der Maas E, Wagemaker M 2018 ACS Appl. Energy Mater. 1 3230 Google Scholar
[44]	Zhu Z, Chu I H, Deng Z, Ong S P 2015 Chem. Mater. 27 8318 Google Scholar
[45]	Zhang Z Z, Zou Z Y, Kaup K, Xiao R J, Shi S Q, Avdeev M, Hu Y S, Wang D, He B, Li H, Huang X J, Nazar L F, Chen L Q 2019 Adv. Energy Mater. 9 1902373 Google Scholar
[46]	Agmon N 1995 Chem. Phys. Lett. 244 456 Google Scholar
[47]	Lang B, Ziebarth B, Elsässer C 2015 Chem. Mater. 27 5040 Google Scholar
[48]	Hu P, Zou Z Y, Sun X W, Wang D, Ma J, Kong Q Y, Xiao D D, Gu L, Zhou X H, Zhao J W, Dong S M, He B, Avdeev M, Shi S Q, Cui G L, Chen L Q 2020 Adv. Mater. 32 1907526 Google Scholar
[49]	Li J, Guan M X, Nan P F, Wang J, Ge B H, Qiao K M, Zhang H R, Liang W H, Hao J Z, Zhou H B, Shen F R, Liang F X, Zhang C, Liu M, Meng S, Zhu T, X Hu F, Wu T, Guo J D, Sun J R, Shen B G 2020 Nano Energy 78 105215 Google Scholar
[50]	Yamada Y, Wang J, Ko S, Watanabe E, Yamada A 2019 Nat. Energy 4 269 Google Scholar
[51]	Geoffroy I, Willmann P, Mesfar K, CarréB, Lemordant D 2000 Electrochim. Acta 45 2019 Google Scholar
[52]	Ding M S, Jow T R 2003 J. Electrochem. Soc. 150 A620 Google Scholar
[53]	Blint R J 1995 J. Electrochem. Soc. 142 696 Google Scholar
[54]	Chagnes A, Carré B, Willmann P, Lemordant D 2002 J. Power Sources 109 203 Google Scholar
[55]	Hayamizu K, Aihara Y 2004 Electrochim. Acta 49 3397 Google Scholar
[56]	Brodd R J, Huang W, Akridge J R 2000 Macromol. Symp. 159 229 Google Scholar
[57]	Yang Y Y C, Davies D M, Yin Y J, Borodin O, Lee J Z, Fang C C, Olguin M, Zhang Y H, Sablina E S, Wang X F, Rustomji C S, Meng Y S 2019 Joule 3 1 Google Scholar
[58]	Lukatskaya M R, Feldblyum J I, Mackanic D G, Lissel F, Michels D L, Cui Y, Bao Z N 2018 Energy Environ. Sci. 11 2876 Google Scholar
[59]	Ohno H 2005 Electrochemical Aspects of Ionic Liquids (Wiley Interscience) pp1−3
[60]	Webber A, Blomgren G E 2002 Advances in Lithium-Ion Batteries (Kluwer: Academic/Plenum Publishers) pp185−232
[61]	Lee J S, Bae J Y, Lee H, Quan N D, Kim H S, Kim H 2004 J. Ind. Eng. Chem. 10 1086
[62]	Ishikawa M, Sugimoto T, Kikuta M, Ishiko E, Kono M 2006 J. Power Sources 162 658
[63]	Zhang X Q, Chen X, Hou L P, Li B Q, Cheng X B, Huang J Q, Zhang Q 2019 ACS Energy Lett. 4 411 Google Scholar
[64]	Chang Z, Qiao Y, Deng H, Yang H J, He P, Zhou H S 2020 Joule 4 1 Google Scholar
[65]	Suo L M, Hu Y S, Li H, Armand M, Chen L Q 2013 Nat. Commun. 4 1481 Google Scholar
[66]	Suo L M, Fang Z, Hu Y S, Chen L Q 2016 Chin. Phys. B 25 016101 Google Scholar
[67]	Guo Z L, Wang T S, Wei H H, Long Y Z, Yang C, Wang D, Lang J L, Huang K, Hussain N, Song C X, Guan B, Ge B H, Zhang Q F, Wu H 2019 Angew. Chem. Int. Ed. 131 12699 Google Scholar
[68]	Fenton D E, Parker J M, Wright P V 1973 Polymer 14 589 Google Scholar
[69]	Armand M B, Chabagno J M, Duclot M J 1979 Fast Ion Transport in Solids (New York: Elsevier) p131
[70]	Cho Y G, Hwang C, Cheong D S, Kim Y S, Song H K 2019 Adv. Mater. 31 1804909 Google Scholar
[71]	Zhou D, He Y B, Liu R L, Liu M, Du H D, Li B H, Cai Q, Yang Q H, Kang F Y 2015 Adv. Energy Mater. 5 1500353 Google Scholar
[72]	Bouchet R, Maria S, Meziane R, Aboulaich A, Lienafa L, Bonnet J-P, Phan T N T, Bertin D, Gigmes D, Devaux D, Denoyel R, Armand M 2013 Nat. Mater. 12 452 Google Scholar
[73]	Yu Z, Mackanic D G, Michaels W, Lee M, Pei A, Feng D W, Zhang Q H, Tsao Y C, Amanchukwu C V, Yan X Z, Wang H S, Chen S C, Liu K, Kang J H, Qin J, Cui Y, Bao Z N 2019 Joule 3 2761 Google Scholar
[74]	Amanchukwu C, Yu Z, Kong X, Qin J, Cui Y, Bao Z N 2020 J. Am. Chem. Soc. 142 7393 Google Scholar
[75]	Mackanic D G, Michaels W, Lee M, Feng D W, Lopez J, Qin J, Cui Y, Bao Z N 2018 Adv. Energy Mater. 8 1800703 Google Scholar
[76]	Lopez J, Sun Y M, Mackanic D G, Lee M, Foudeh A M, Song M S, Cui Y, Z N Bao 2018 Adv. Mater. 30 1804142 Google Scholar
[77]	Mackanic D G, Yan X Z, Zhang Q H, Matsuhisa N J, Yu Z, Jiang Y W, Manika T, Lopez J, Yan H P, Liu K, Chen X D, Cui Y, Bao Z N 2019 Nat. Commun. 10 5384 Google Scholar
[78]	Wan J Y, Xie J, Kong X, Liu Z, Liu K, Shi F F, Pei A, Chen H, Chen W, Chen J, Zhang X K, Zong L Q, Wang J Y, Chen L Q, Qin J, Cui Y 2019 Nat. Nanotechnol. 14 705 Google Scholar
[79]	Kato T, Yoshio M, Ichikawa T, Soberats B, Ohno H, Funahashi M 2017 Nat. Rev. Mater. 2 17001 Google Scholar
[80]	Kimura K, M Hirao, Yokoyama M 1991 J. Mater. Chem. 1 293 Google Scholar
[81]	李昕桐, 张霖琛, 张焕瑞, 张波涛, 崔光磊 2020 储能科学与技术 9 1595 Li X T, Zhang L C, Zhang H R, Zhang B T, Cui G L 2020 Energy Storage Sci. Technol. 9 1595
[82]	Chen L, Li Y T, Li S P, Fan L Z, Nan C W, Goodenough J B 2018 Nano Energy 46 176 Google Scholar
[83]	赵宁, 李忆秋, 张静娴, 狄增峰, 郭向欣 2016 储能科学与技术 5 754 Google Scholar Zhao N, Li Y Q, Zhang J X, Di Z F, Guo X X 2016 Energy Storage Sci. Technol. 5 754 Google Scholar
[84]	Huo H Y, Li X N, Chen Y, Liang J N, Deng S X, Gao X J, Kieran Doyle-Davis, Li R Y, Guo X X, Shen Y, Nan C W, Sun X L 2020 Energy Storage Mater. 29 361 Google Scholar
[85]	林祖纕, 郭祝崑, 孙成文, 李世椿, 陈昆刚, 田顺宝, 严东生 1983 快离子导体(固体电解质)基础、材料、应用(上海: 上海科学技术出版社) 第1—4页 Li Z X, Guo Z K, Sun C W, Li S C, Chen K G, Tian S B, Yan D S 1983 Fast ion conductor (solid electrolyte) basis, material, application (Shanghai: Shanghai Science and Technology Press) pp1–4 (in Chinese）[
[86]	萨拉蒙M B著 (王刚刘长乐译, 陈立泉校) 1984 快离子导体物理(北京: 科学出版社)第1—4页 Salamon M B (translated by Wang G Liu C L, Proof by Chen L Q)1984 Physics of Superionic Conductors (Beijing: Science Press) pp1–4 (in Chinese）[
[87]	Murugan R, Thangadurai V, Weppner W 2007 Angew. Chem. Int. Ed. 46 7778 Google Scholar
[88]	Du F M, Zhao N, Li Y Q, Chen C, Liu Z W, Guo X X 2015 J. Power Sources 300 24 Google Scholar
[89]	Jalem R, Yamamoto Y, Shiiba H, Nakayama M, Munakata H, Kasuga T, Kanamura K 2013 Chem. Mater. 25 425 Google Scholar
[90]	Zhao N, Khokhar W, Bi Z J, Shi C, Guo X X, Fan L Z, Nan C W 2019 Joule 3 1190 Google Scholar
[91]	Hong H Y P 1976 Mater. Res. Bull. 11 173 Google Scholar
[92]	Hong Y P, Kafalas J A, Bayard M 1978 Mater. Res. Bull. 13 757 Google Scholar
[93]	Goodenough J B, Hong H Y P, Kafalas J A 1976 Mater. Res. Bull. 11 203 Google Scholar
[94]	Zhang Z Z, Zhang Q H, Shi J N, Chu Y S, Yu X Q, Xu K Q, Ge M Y, Yan H F, Li W J, Gu L, Hu Y S, Li H, Yang X Q, Chen L Q, Huang X J 2016 Adv. Energy Mater. 7 1601196 Google Scholar
[95]	Aono H, Sugimoto E, Sadaoka Y, Imanaka N, Adachi G 1990 J. Electrochem. Soc. 137 1023 Google Scholar
[96]	Lin Z, Li S, Tian S, Yu H 1984 Sci. Sin. (Ser. A) 27 889
[97]	Lu X, Wang S H, Xiao R J, Shi S Q, Li H, Chen L Q 2017 Nano Energy 41 626 Google Scholar
[98]	Bay M C, Wang M, Grissa R, Heinz M V F, Sakamoto J, Battaglia C 2020 Adv. Energy Mater. 10 1902899 Google Scholar
[99]	Lei D, He Y B H, Huang, Yuan Y, Zhong G, Zhao Q, Hao X, Zhang D, Lai C, Zhang S 2019 Nat. Commun. 10 4244 Google Scholar
[100]	Sudworth J L 1984 J. Power Sources 11 143 Google Scholar
[101]	Jolly D S, Ning Z, Darnbrough J E, Kasemchainan J, Hartley G O, Adamson P, Armstrong D E J, Marrow J, Bruce P G 2020 ACS Appl. Mater. Interfaces 12 678 Google Scholar
[102]	Kanno R, Murayama M 2001 J. Electrochem. Soc. 148 A742 Google Scholar
[103]	Kamaya N, Homma K, Yamakawa Y, Hirayama M, Kanno R, Yonemura M, Kamiyama T, Kato Y, Hama S, Kawamoto K, Mitsui A 2011 Nat. Mater. 10 682 Google Scholar
[104]	Kato Y, Hori S, Saito T, Suzuki K, Hirayama M, Mitsui A, Yonemura M, Iba H, Kanno R 2016 Nat. Energy 1 16030 Google Scholar
[105]	刘丽露, 吴凡, 李泓, 陈立泉 2019 硅酸盐学报 47 1367 Liu L L, Wu F, Li H, Chen L Q 2019 J. Chin. Ceram. Soc. 47 1367
[106]	Wang X L, Xiao R J, Li H, Chen L Q 2017 Phys. Rev. Lett. 118 195901 Google Scholar
[107]	Takagi S, Ikeshoji T, Sato T, Orimo S 2020 Appl. Phys. Lett. 116 173901 Google Scholar
[108]	Smith J G, Siegel D J 2020 Nat. Commun. 11 1483 Google Scholar
[109]	Li X N, Liang J W, Yang X F, Adair K R, Wang C S, Zhao F P, Sun X L 2020 Energy Environ. Sci. 13 1429 Google Scholar
[110]	Asano T, Sakai A, Ouchi S, Sakaida M, Miyazaki A, Hasegawa S 2018 Adv. Mater. 30 1803075 Google Scholar
[111]	Wang S, Bai Q, Nolan A M, Liu Y S, Gong S, Sun Q, Mo Y F 2019 Angew. Chem. Int. Ed. 58 8039 Google Scholar
[112]	Schlem R, Muy S, Prinz N, Banik A, Horn Y, Zobel M, Zeier W 2019 Adv. Energy Mater. 10 1903719 Google Scholar
[113]	Liang J W, Li X N, Wang S, Adair K R, Li W H, Zhao Y, Wang C H, Hu Y F, Zhang L, Zhao S Q, Lu S G, Huang H, Li R Y, Mo Y F, Sun X L 2020 J. Am. Chem. Soc. 142 7012 Google Scholar
[114]	Park K, Kaup K, Assoud A, Zhang Q, Wu X, Nazar L 2020 ACS Energy Lett. 5 533 Google Scholar
[115]	Ming J, Cao Z, Wahyudi W, Li M L, Kumar P, Wu Y Q, Hwang J Y, Hedhili M N, Cavallo L, Sun Y K, Li L J 2018 ACS Energy Lett. 3 335 Google Scholar
[116]	Rolland J, Poggi E, Vlad A, Gohy J F 2015 Polymer 68 344 Google Scholar
[117]	Shi S Q, Gao J, Liu Y, Zhao Y, Wu Q, Ju W W, Ouyang C Y, Xiao R J 2016 Chin. Phys. B 25 018212 Google Scholar
[118]	Gao J, Zhao Y S, Shi S Q, Li H 2016 Chin. Phys. B 25 018211 Google Scholar
[119]	Lou S F, Yu Z J, Liu Q S, Wang H, Chen M, Wang J J 2020 Chem. 6 1 Google Scholar
[120]	He B, Chi S T, Ye A J, Mi P H, Zhang L W, Pu B W, Zou Z Y, Ran Y B, Zhao Q, Wang D, Zhang W Q, Zhao J T, Adams S, Avdeev M, Shi S Q 2020 Sci. Data 7 151 Google Scholar
[121]	He B, Ye A J, Chi S T, Mi P H, Ran Y B, Zhang L W, Zou X X, Pu B W, Zhao Q, Zou Z Y, Wang D, Zhang W Q, Zhao J T, Avdeev M, Shi S Q 2020 Sci. Data 7 153 Google Scholar
[122]	He B, Mi P H, Ye A J, Chi S T, Jiao Y, Zhang L W, Pu B W, Zou Z Y, Zhang W Q, Avdeev M, Adams S, Zhao J T, Shi S Q 2021 Acta Mater. 203 116490 (SPSE 平台https://matgen.nscc-gz.cn/solidElectrolyte/
[123]	Pan L, Zhang LW, Ye A J, Chi S T, Zou Z Y, He B, Chen L L, Zhao Q, Wang D, Shi S Q 2019 J. Materiomics 5 688 Google Scholar
[124]	Yang Y H, Wu Q, Cui Y H, Chen Y C, Shi S Q, Wang R Z, Yan H 2016 ACS Appl. Mater. Interfaces 8 25229 Google Scholar
[125]	Li Y J, Zhao Y, Cui Y H, Zou Z Y, Wang D, Shi S Q 2018 Comput. Mater. Sci. 144 338 Google Scholar
[126]	Famprikis T, Canepa P, Dawson J A, Islam M S, Masquelier C 2019 Nat. Mater. 18 1278 Google Scholar
[127]	Huang Y W, He Y, Sheng H, Lu X, Dong H N, Samanta S, Dong H L, Li X F, Kim D Y, Mao H K, Liu Y Z, Li H P, Li H, Wang L 2019 Natl. Sci. Rev. 6 239 Google Scholar
[128]	Zhang T F, Wang Y M, Song T, Miyaoka H, Shinzato K, Miyaoka H, Ichikawa T, Shi S Q, Zhang X G, Isobe S, Hashimoto N, Kojima Y 2018 Joule 2 1 Google Scholar
[129]	Lu X, Wang S H, Xiao R J, Shi S Q, Li H, Chen L Q 2017 Nano Energy. 41 626
[130]	Shi S Q, Xu L F, Ouyang C Y, Wang Z X, Chen L Q 2006 Ionics 12 343 Google Scholar
[131]	Liu F C, Shadike Z, Wang X F, Shi S Q, Zhou Y N, Chen G Y, Yang X Q, Weng L H, Zhao J T, Fu Z W 2016 Inorg. Chem. 55 6504 Google Scholar
[132]	Liu Y, Zhao T L, Ju W W, Shi S Q 2017 J. Materiomics 3 159 Google Scholar
[133]	Liu Y, Guo B R, Zou X X, Li Y J, Shi S Q 2020 Energy Storage Mater. 31 434 Google Scholar
[134]	张更, 王巧, 沙立婷, 李亚捷, 王达, 施思齐 2020 物理学报 69 226401 Zhang G, Wang Q, Sha L T, Li Y J, Wang D, Shi S Q 2020 Acta Phys. Sin. 69 226401

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[20]	朱斌, 王大志, 俞文海. 蒙脱石固体电解质的高价离子导电性. 物理学报, 1988, 37(8): 1307-1314. doi: 10.7498/aps.37.1307

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浅析电解质中离子输运的微观物理图像