Progress on High Voltage PEO-based Polymer Solid Electrolytes in Lithium Batteries

doi:10.1007/s40242-022-2065-2

高等学校化学研究 ›› 2022, Vol. 38 ›› Issue (3): 735-743.doi: 10.1007/s40242-022-2065-2

Progress on High Voltage PEO-based Polymer Solid Electrolytes in Lithium Batteries

HOU Wenhui, OU Yu and LIU Kai

Department of Chemical Engineering, Tsinghua University, Beijing 100084, P. R. China

收稿日期:2022-02-28 修回日期:2022-04-08 出版日期:2022-06-01 发布日期:2022-05-26
通讯作者: LIU Kai E-mail:liukai2019@tsinghua.edu.cn
基金资助:
This work was supported by the National Natural Science Foundation of China (No.22071133), the China Postdoctoral Science Foundation(No.2021M691763), the Tsinghua-Foshan Innovation Special Fund(TFISF), China (No.2020THFS0130), and the Fund of the Tsinghua University-China Petrochemical Corporation Joint Institute for Green Chemical Engineering (No.421120).

Progress on High Voltage PEO-based Polymer Solid Electrolytes in Lithium Batteries

HOU Wenhui, OU Yu and LIU Kai

Department of Chemical Engineering, Tsinghua University, Beijing 100084, P. R. China

Received:2022-02-28 Revised:2022-04-08 Online:2022-06-01 Published:2022-05-26
Contact: LIU Kai E-mail:liukai2019@tsinghua.edu.cn
Supported by:
This work was supported by the National Natural Science Foundation of China (No.22071133), the China Postdoctoral Science Foundation(No.2021M691763), the Tsinghua-Foshan Innovation Special Fund(TFISF), China (No.2020THFS0130), and the Fund of the Tsinghua University-China Petrochemical Corporation Joint Institute for Green Chemical Engineering (No.421120).

摘要/Abstract

摘要： Polymer electrolytes have attracted great interest for next-generation lithium-based batteries on account of safety and high energy density. In this review, we assess recent progress on the design of poly(ethylene oxide)(PEO)-based solid polymer electrolytes in high voltage lithium batteries and identify possible side reactions between PEO-based electrolytes and existing cathodes. We provide an overview of the ways to enhance high voltage resistance of PEO-based electrolytes. Those include components blend, molecular design and interface modification. With these efforts, we want to present new insights into rational design of PEO-based electrolytes to develop solid-state lithium batteries for advanced performance.

关键词: Poly(ethylene oxide), Lithium battery, High voltage, Molecular design, Interface modification

Abstract: Polymer electrolytes have attracted great interest for next-generation lithium-based batteries on account of safety and high energy density. In this review, we assess recent progress on the design of poly(ethylene oxide)(PEO)-based solid polymer electrolytes in high voltage lithium batteries and identify possible side reactions between PEO-based electrolytes and existing cathodes. We provide an overview of the ways to enhance high voltage resistance of PEO-based electrolytes. Those include components blend, molecular design and interface modification. With these efforts, we want to present new insights into rational design of PEO-based electrolytes to develop solid-state lithium batteries for advanced performance.

Key words: Poly(ethylene oxide), Lithium battery, High voltage, Molecular design, Interface modification

HOU Wenhui, OU Yu and LIU Kai. Progress on High Voltage PEO-based Polymer Solid Electrolytes in Lithium Batteries[J]. 高等学校化学研究, 2022, 38(3): 735-743.

HOU Wenhui, OU Yu and LIU Kai. Progress on High Voltage PEO-based Polymer Solid Electrolytes in Lithium Batteries[J]. Chemical Research in Chinese Universities, 2022, 38(3): 735-743.

参考文献

[1] Tarascon J. M., Armand M., Nature,2001, 414(6861), 359
[2] Yuan M. Q., Liu K., Journal of Energy Chemistry, 2020, 43(4), 70
[3] Liu K., Liu Y. Y., Lin D. C., Pei A., Cui Y., Science Advances, 2018, 4(6), 9820
[4] Dong H., Wang P. C., Yan S. S., Xia Y. C., Wang B. G., Wang X. L., Liu K., Journal of Energy Chemistry,2021, 62, 423
[5] Liu K., Liu W., Qiu Y. C., Kong B., Sun Y. M., Chen Z., Zhuo D., Lin D. C., Cui Y., Science Advances,2017,3, e1601978
[6] Chen X. X., Yan S. S., Tan T. H., Zhou P., Hou J. X., Feng X. N., Dong H., Wang P. C., Wang B. G., Ouyang M. G., Liu K., Energy Storage Materials, 2022, 45, 182
[7] Yan S. S., Chen X. X., Zhou P., Wang P. C., Zhou H. Y., Zhang W. L., Xia Y. C., Liu K., Journal of Energy Chemistry, 2022, 67, 467
[8] Liu K., Pei A., Lee H. R., Kong B., Liu N., Lin D. C., Liu Y. Y., Liu C., Hsu P. C., Bao Z. C., Cui Y., Journal of the American Chemical Society, 2017, 139(13), 4815
[9] Chen S., Wen K., Fan J., Bando Y., Golberg D., Journal of Materials Chemistry A,2018, 6(25), 11631
[10] Arya A., Sharma A. L., Journal of Materials Science,2020, 55(15), 6242
[11] Xue Z., He D., Xie X., Journal of Materials Chemistry A,2015, 3(38), 19218
[12] MacGlashan G. S., Andreev Y. G., Bruce P. G., Nature,1999, 398(6730), 792
[13] Homann G., Stolz L., Nair J., Laskovic I. C., Winter M., Kasnatscheew J., Sci. Rep.,2020, 10(1), 4390
[14] Xia Y. Y., Fujieda T., Tatsumi K., Prosini P. P., Sakai T., Journal of Power Sources,2001, 92(1/2), 234
[15] Zhu Y., He X., Mo Y., Journal of Materials Chemistry A,2016, 4(9), 3253
[16] Nie K. H., Wang X. L., Qiu J. L., Wang Y., Yang Q., Xu J. J., Yu X. Q., Li H., Huang X. J., Chen L. Q., ACS Energy Lett.,2020, 5(3), 826
[17] Judez X., Zhang H., Li C., Eshetu G. G., González-Marcos J. A., Armand M., Rodriguez-Martinez L. M., Journal of The Electrochemical Society,2017, 165(1), A6008
[18] Zhou Q., Ma J., Dong S., Li X., Cui G., Adv. Mater.,2019, 31(50), e1902029
[19] Guo X. Q., Peng W. J., Wu Y. Q., Guo H. J., Wang Z. X., Li X. H., Ke Y., Wu L. J., Fu H. K., Wang J. X., Sci. China Mater.,2021, 64(2), 296
[20] Li X. L., Yang L., Shao D. S., Luo K. L., Liu L., Wu Z. Y., Luo Z. G., Wang X. Y., J. Appl. Polym. Sci.,2020, 137(24), 48810
[21] Choudhury S., Stalin S., Deng Y., Archer L. A., Chemistry of Materials,2018, 30(17), 5996
[22] Tang C., Hackenberg K., Fu Q., Ajayan P. M., Ardebili H., Nano Lett.,2012, 12(3), 1152
[23] Li X. L., Wang X. Y., Shao D. S., Liu L., Yang L., J. Appl. Polym. Sci.,2019, 136(19), 47498
[24] Arya A., Sharma A. L., J. Phys. D:Appl. Phys.,2018, 51, 045504
[25] Lopez-Aranguren P., Judez X., Chakir M., Armand M., Buannic L., Journal of the Electrochemical Society,2020, 167(2), 020548
[26] Homann G., Meister P., Stolz L., Brinkmann J. P., Kulisch J., Adermann T., Winter M., Kasnatscheew J., ACS Appl. Energ. Mater.,2020, 3(4), 3162
[27] Richards W. D., Miara L. J., Wang Y., Kim J. C., Ceder G., Chemistry of Materials,2015, 28(1), 266
[28] Xu H. H., Chien P. H., Shi J. J., Li Y. T., Wu N., Liu Y. Y., Hu Y. Y., Goodenough J. B., Proc. Natl. Acad. Sci. USA,2019, 116(38), 18815
[29] Chen L., Qiu X., Bai Z., Fan L. Z., Journal of Energy Chemistry,2021, 52, 210
[30] Xue X. L., Zhang X. X., Lin J. H., Chen S. J., Chen Y. Q., Liu Y. C., Zhang Y. N., Chinese J. Struc. Chem.,2020, 39(11), 1941
[31] Liu C., Wang J. X., Kou W. J., Yang Z. H., Zhai P. F., Liu Y., Wu W. J., Wang J. T., Chemical Engineering Journal,2021, 404, 126517
[32] Deb D., Bose P., Bhattacharya S., Int. J. Energ Res.,2020, 44(13), 10506
[33] Liu W., Deng F., Song S. F., Ji G. P., Hu N., Xu C. H., Mater. Technol.,2020, 35(9/10), 618
[34] Balo L., Gupta H., Singh S. K., Singh V. K., Kataria S., Singh R. K., J. Ind. Eng. Chem.,2018, 65, 137
[35] Uludag A. A., Akbulut H., Tokur M., Algul H., Cetinkaya T., Uysal M., Microsyst. Technol.,2016, 22(5), 953
[36] Fedeli E., Kvasha A., Gigmes D., Phan T. N. T., Appl. Sci.-Basel,2020, 10(21), 7724
[37] Kumar Y., Hashmi S. A., Pandey G. P., Solid State Ionics,2011, 201(1), 73
[38] Li D., Chen L., Wang T. S., Fan L. Z., ACS Appl. Mater. Inter.,2018, 10(8), 7069
[39] Lin Y., Cheng Y., Li J., Miller J. D., Liu J., Wang X. M., Rsc. Adv.,2017, 7(40), 24856
[40] Xu N., Zhou H. B., Liao Y. H., Li G. J., Xu M. Q., Li W. S., Solid State Ionics,2019, 341, 115049
[41] Arya A., Sharma A. L., Polym. Bull.,2020, 77(6), 2965
[42] Putri R. M., Sundari C. D. D., Floweri O., Mayangsari T. R., Ivansyah A. L., Santosa S. P., Arcana I. M., Iskandar F., J. Non-Cryst. Solids,2021, 556, 120549
[43] Bai C. J., Wu Z. G., Xiang W., Wang G. K., Liu Y. X., Zhong Y. J., Chen B. T., Liu R. D., He F. R., Guo X. D., Journal of Power Sources,2020, 472,
[44] Wang Z. J., Yang K., Song Y. L., Lin H., Li K., Cui Y. H., Yang L. Y., Pan F. Nano Res.,2020, 13(9), 2431
[45] Meabe L., Pena S. R., Martinez-Ibanez M., Zhang Y., Lobato E., Manzano H., Armand M., Carrasco J., Zhang H. J. Phys. Chem. C,2020, 124(33), 17981
[46] Liao Y., Li G., Xu N., Chen T., Wang X., Li W., Solid State Ionics,2019, 329, 31
[47] Yahata Y., Marukane S., Sato T., Tsujii Y., Ohno K., Langmuir,2019, 35(45), 14566
[48] Ma J., Liu Z., Chen B., Wang L., Yue L., Liu H., Zhang J., Liu Z., Cui G., Journal of The Electrochemical Society,2017, 164(14), A3454
[49] Yuan F., Chi S., Dong S., Zou X., Lv S., Bao L., Wang J., Electrochimica Acta,2019, 294, 249
[50] Yuan F., Yang L., Zou X., Dong S., Chi S., Xie J., Xing H., Bian L., Bao L., Wang J., Journal of Power Sources,2019, 444, 227305
[51] Feng Y. C., Tan R., Zhao Y., Gao R. T., Yang L. Y., Yang J. L., Li H., Zhou G. F., Chen H. B., Pan F., Nanoscale,2018, 10(13), 5975
[52] He W. S., Cui Z. L., Liu X. C., Cui Y. Y., Chai J. C., Zhou X. H., Liu Z. H., Cui G. L., Electrochimica Acta,2017, 225, 151
[53] Pandian S., Adiga S. P., Tagade P., Hariharan K. S., Mayya K. S., Lee Y. G., Journal of Power Sources,2018, 393, 204
[54] Li G. B., Chen X., Miao L. X., Chen J. T., Zheng J. R., Journal of Power Sources,2018, 394, 26
[55] Xu W., Belieres J.-P., Angell C. A., Chemistry of Materials,2001, 13(2), 575
[56] Nair J. R., Shaji I., Ehteshami N., Thum A., Diddens D., Heuer A., Winter M., Chemistry of Materials,2019, 31(9), 3118
[57] Zhang J. F., Ma C., Hou H., Li X. F., Chen L. B., Ivey D. G., Wei W. F., J. Membrane Sci.,2018, 552, 107
[58] Deng K. R., Zeng Q. G., Wang D., Liu Z., Qiu Z. P., Zhang Y. F., Xiao M., Meng Y. Z., Journal of Materials Chemistry A,2020, 8(4), 1557
[59] Steinle D., Chen Z., Nguyen H. D., Kuenzel M., Iojoiu C., Passerini S., Bresser D., Journal of Solid State Electrochemistry,2022, 26, 97
[60] Zhan X. L., Zhang J. W., Liu M. Z., Lu J. G., Zhang Q. H., Chen F. Q., ACS Appl. Energ. Mater.,2019, 2(3), 1685
[61] Zheng P. X., Wang X. W., Wang D., Yu Z. W., Acta Polym. Sin.,2021, 52(1), 94
[62] Kumar P. S., Sakunthala A., Reddy M. V., Shanmugam S., Prabu M. Journal Of Solid State Electrochemistry,2016, 20(7), 1865
[63] Hallinan D. T., Rausch A., McGill B., Chem. Eng. Sci.,2016, 154, 34
[64] Han J. H., Lee J. Y., Suh D. H., Hong Y. T., Kim T. H., ACS Appl. Mater. Inter.,2017, 9(39), 33913
[65] Tang S., Lan Q., Xu L., Liang J. Y., Lou P., Liu C., Mai L. Q., Cao Y. C., Cheng S. J., Nano Energy,2020, 71, 104600
[66] Yoshizawa-Fujita M., Ishii J., Takeoka Y., Rikukawa M., Polymers-Basel,2021, 13(5), 800
[67] Hernandez G., Casado N., Coste R., Shanmukaraj D., Rubatat L., Armand M., Mecerreyes D., Rsc. Adv.,2015, 5(22), 17096
[68] Zhang B. H., Zhang Y. H., Zhang N., Liu J., Cong L. N., Liu J., Sun L. Q., Mauger A., Julien C. M., Xie H. M., Pan X. M., Journal of Power Sources,2019, 428, 93
[69] Jo G., Jeon H., Park M. J., ACS Macro. Lett.,2015, 4(2), 225
[70] Homann G., Stolz L., Neuhaus K., Winter M., Kasnatscheew J., Advanced Functional Materials,2020, 30(46), 2006289
[71] Homann G., Stolz L., Winter M., Kasnatscheew J., Iscience,2020, 23(6), 101225
[72] Fedeli E., Garcia-Calvo O., Thieu T., Phan T. N. T., Gigmes D., Urdampilleta I., Kvasha A., Electrochimica Acta,2020, 353, 136481
[73] Zeng X. X., Yin Y. X., Li N. W., Du W. C., Guo Y. G., Wan L. J., Journal of the American Chemical Society,2016, 138(49), 15825
[74] Nguyen T. M., Suk J., Kang Y., J. Electrochem. Sci. Te.,2019, 10(2), 250
[75] Tsao C. H., Ueda M., Kuo P. L., J. Polym. Sci. Pol. Chem.,2016, 54(3), 352
[76] Baik J. H., Kim D. G., Shim J., Lee J. H., Choi Y. S., Lee J. C., Polymer,2016, 99, 704
[77] Villaluenga I., Wujcik K. H., Tong W., Devaux D., Wong D. H., DeSimone J. M., Balsara N. P., Proc. Natl. Acad. Sci. USA,2016, 113(1), 52
[78] Yang X., Jiang M., Gao X., Bao D., Sun Q., Holmes N., Duan H., Mukherjee S., Adair K., Zhao C., Liang J., Li W., Li J., Liu Y., Huang H., Zhang L., Lu S., Lu Q., Li R., Singh C. V., Sun X., Energ. Environ. Sci.,2020, 13(5), 1318
[79] Wang H., Wang Q., Cao X., He Y., Wu K., Yang J., Zhou H., Liu W., Sun X., Advanced Materials,2020, 32(37), 2001259
[80] 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., Nature Materials,2013, 12(5), 452
[81] Hu P., Chai J., Duan Y., Liu Z., Cui G., Chen L., Journal of Materials Chemistry A,2016, 4(26), 10070
[82] Yang Q., Huang J., Li Y., Wang Y., Qiu J., Zhang J., Yu H., Yu X., Li H., Chen L., Journal of Power Sources,2018, 388, 65
[83] Wang Y., Liu B.-N., Zhou G., Nie K.-H., Zhang J.-N., Yu X.-Q., Li H., Chinese Physics B,2019, 28(6), 068202
[84] Morimoto H., Awano H., Terashima J., Shindo Y., Nakanishi S., Ito N., Ishikawa K., Tobishima S.-I., Journal of Power Sources,2013, 240, 636
[85] Shim J. H., Han J. M., Lee J. H., Lee S., ACS Appl Mater Interfaces,2016, 8(19), 12205
[86] Li Z., Li A., Zhang H., Lin R., Jin T., Cheng Q., Xiao X., Lee W.-K., Ge M., Zhang H., Zangiabadi A., Waluyo I., Hunt A., Zhai H., Borovilas J. J., Wang P., Yang X.-Q., Chuan X., Yang Y., Nano Energy,2020, 72, 104655
[87] Liang J., Hwang S., Li S., Luo J., Sun Y., Zhao Y., Sun Q., Li W., Li M., Banis M. N., Li X., Li R., Zhang L., Zhao S., Lu S., Huang H., Su D., Sun X., Nano Energy,2020, 78
[88] Zhou W., Wang Z., Pu Y., Li Y., Xin S., Li X., Chen J., Goodenough J. B., Adv. Mater.,2019, 31(4), e1805574
[89] Yu X. Li J. Manthiram A., ACS Mater. Lett.,2020, 2(4), 317
[90] Fu C., Lou S., Xu X., Cui C., Li C., Zuo P., Ma Y., Yin G., Gao Y., Chemical Engineering Journal,2020, 392, 123665

Progress on High Voltage PEO-based Polymer Solid Electrolytes in Lithium Batteries

Progress on High Voltage PEO-based Polymer Solid Electrolytes in Lithium Batteries

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