Enhanced electrochemical performance of garnet-based solid-state lithium metal battery with modified anodic and cathodic interfaces

doi:10.1016/j.cjche.2021.03.030

Chinese Journal of Chemical Engineering ›› 2022, Vol. 44 ›› Issue (4): 140-147.DOI: 10.1016/j.cjche.2021.03.030

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Enhanced electrochemical performance of garnet-based solid-state lithium metal battery with modified anodic and cathodic interfaces

Deen Yan¹, Huangwang Mai², Wen Chen¹, Wei Yang¹, Hanbo Zou¹, Shengzhou Chen¹

1 School of Chemistry and Chemical Engineering, Guangzhou University, Guangzhou 510006, China;
2 Guangzhou Tinci Materials Technology Co., Ltd., Guangzhou 510760, China

Received:2020-11-14 Revised:2021-02-25 Online:2022-06-18 Published:2022-04-28
Contact: Hanbo Zou,E-mail:zouhb@gzhu.edu.cn;Shengzhou Chen,E-mail:szchen@gzhu.edu.cn
Supported by:
This work was subsidized by the National Natural Science Foundation of China (21776051), the Nation Science Foundation of Guangdong (2018A030313423), and the College Students' Innovation and Entrepreneurship Training Program (S201911078039).

Enhanced electrochemical performance of garnet-based solid-state lithium metal battery with modified anodic and cathodic interfaces

Deen Yan¹, Huangwang Mai², Wen Chen¹, Wei Yang¹, Hanbo Zou¹, Shengzhou Chen¹

1 School of Chemistry and Chemical Engineering, Guangzhou University, Guangzhou 510006, China;
2 Guangzhou Tinci Materials Technology Co., Ltd., Guangzhou 510760, China

通讯作者: Hanbo Zou,E-mail:zouhb@gzhu.edu.cn;Shengzhou Chen,E-mail:szchen@gzhu.edu.cn
基金资助:
This work was subsidized by the National Natural Science Foundation of China (21776051), the Nation Science Foundation of Guangdong (2018A030313423), and the College Students' Innovation and Entrepreneurship Training Program (S201911078039).

Abstract

Abstract: Due to high ionic conductivity and wide electrochemical window, the garnet solid electrolyte is considered as the most promising candidate electrolyte for solid-state lithium metal batteries. However, the high contact impedance between metallic lithium and the garnet solid electrolyte surface seriously hampers its further application. In this work, a Li-(ZnO)_x anode is prepared by the reaction of zinc oxide with metallic lithium and in situ coated on the surface of Li_6.8La₃Zr_1.8Ta_0.2O₁₂(LLZTO). The anode can be perfectly bound to the surface of LLZTO solid electrolyte, and the anode/electrolyte interfacial resistance was reduced from 2319 to 33.75 Ω·cm². The Li-(ZnO)_0.15|LLZTO|Li-(ZnO)_0.15 symmetric battery exhibits a stable Li striping/plating process during charge-discharging at a constant current density of 0.1 mA·cm^-2 for 100 h at room temperature. Moreover, a Li-(ZnO)_0.15|LLZTO-SPE|LFP full battery, comprised of a polyethylene oxide-based solid polymer electrolyte (SPE) film as an interlayer between LiFePO₄ (LFP) cathode and LLZTO solid electrolyte, presents an excellent performance at 60 ℃. The discharge capacity of the full battery reaches 140 mA·h·g^-1 at 0.1 C and the capacity attenuation is less than 3% after 50 cycles.

Key words: Lithium metal battery, Solid-state electrolyte, Li-ZnO anode

摘要： Due to high ionic conductivity and wide electrochemical window, the garnet solid electrolyte is considered as the most promising candidate electrolyte for solid-state lithium metal batteries. However, the high contact impedance between metallic lithium and the garnet solid electrolyte surface seriously hampers its further application. In this work, a Li-(ZnO)_x anode is prepared by the reaction of zinc oxide with metallic lithium and in situ coated on the surface of Li_6.8La₃Zr_1.8Ta_0.2O₁₂(LLZTO). The anode can be perfectly bound to the surface of LLZTO solid electrolyte, and the anode/electrolyte interfacial resistance was reduced from 2319 to 33.75 Ω·cm². The Li-(ZnO)_0.15|LLZTO|Li-(ZnO)_0.15 symmetric battery exhibits a stable Li striping/plating process during charge-discharging at a constant current density of 0.1 mA·cm^-2 for 100 h at room temperature. Moreover, a Li-(ZnO)_0.15|LLZTO-SPE|LFP full battery, comprised of a polyethylene oxide-based solid polymer electrolyte (SPE) film as an interlayer between LiFePO₄ (LFP) cathode and LLZTO solid electrolyte, presents an excellent performance at 60 ℃. The discharge capacity of the full battery reaches 140 mA·h·g^-1 at 0.1 C and the capacity attenuation is less than 3% after 50 cycles.

关键词: Lithium metal battery, Solid-state electrolyte, Li-ZnO anode

Deen Yan, Huangwang Mai, Wen Chen, Wei Yang, Hanbo Zou, Shengzhou Chen. Enhanced electrochemical performance of garnet-based solid-state lithium metal battery with modified anodic and cathodic interfaces[J]. Chinese Journal of Chemical Engineering, 2022, 44(4): 140-147.

References

[1] G.V. Alexander, N.C. Rosero-Navarro, A. Miura, K. Tadanaga, R. Murugan. Electrochemical performance of a garnet solid electrolyte based lithium metal battery with interface modification, J. Mater. Chem. A. 6 (42) (2018) 21018-21028
[2] A. Lassagne, E. Beaudoin, A. Ferrand, T.N.T. Phan, P. Davidson, C. Iojoiu, R. Bouchet, New approach to design solid block copolymer electrolytes for 40℃ lithium metal battery operation, Electrochimica Acta 238 (2017) 21-29
[3] N.W. Li, Y.X. Yin, C.P. Yang, Y.G. Guo, An artificial solid electrolyte interphase layer for stable lithium metal anodes, Adv Mater 28 (9) (2016) 1853-1858
[4] B. Dunn, H. Kamath, J.M. Tarascon, Electrical energy storage for the grid:A battery of choices, Science 334 (6058) (2011) 928-935
[5] K. Liu, R.H. Zhang, M.C. Wu, H.R. Jiang, T.S. Zhao, Ultra-stable lithium plating/stripping in garnet-based lithium-metal batteries enabled by a SnO₂ nanolayer, J. Power Sources 433 (2019) 226691
[6] J.F. Wu, X.Y. Li, Y.Z. Zhao, L. Liu, W.J. Qu, R. Luo, R.J. Chen, Y.J. Li, Q. Chen, Interface engineering in solid state Li metal batteries by quasi-2D hybrid perovskites, J. Mater. Chem. A 6 (42) (2018) 20896-20903
[7] C.W. Wang, Y.H. Gong, B.Y. Liu, K. Fu, Y.G. Yao, E. Hitz, Y.J. Li, J.Q. Dai, S.M. Xu, W. Luo, E.D. Wachsman, L.B. Hu, Conformal, nanoscale ZnO surface modification of garnet-based solid-state electrolyte for lithium metal anodes, Nano Lett 17 (1) (2017) 565-571
[8] X. Han, Y. Gong, K.K. Fu, X. He, G.T. Hitz, J. Dai, A. Pearse, B. Liu, H. Wang, G. Rubloff, Y. Mo, V. Thangadurai, E.D. Wachsman, L. Hu, Negating interfacial impedance in garnet-based solid-state Li metal batteries, Nat Mater 16 (5) (2017) 572-579
[9] Y. Chen, M.H. He, N. Zhao, J.M. Fu, H.Y. Huo, T. Zhang, Y.Q. Li, F.F. Xu, X.X. Guo, Nanocomposite intermediate layers formed by conversion reaction of SnO₂ for Li/garnet/Li cycle stability, J. Power Sources 420 (2019) 15-21
[10] J.M. Su, X. Huang, Z. Song, T.P. Xiu, M.E. Badding, J. Jin, Z.Y. Wen, Overcoming the abnormal grain growth in Ga-doped Li₇La₃Zr₂O₁₂ to enhance the electrochemical stability against Li metal, Ceram. Int. 45 (12) (2019) 14991-14996
[11] C.W. Wang, H. Xie, L. Zhang, Y.H. Gong, G. Pastel, J.Q. Dai, B.Y. Liu, E.D. Wachsman, L.B. Hu, Universal soldering of lithium and sodium alloys on various substrates for batteries, Adv. Energy Mater. 8 (6) (2018) 1701963
[12] C.P. Yang, H. Xie, W.W. Ping, K. Fu, B.Y. Liu, J.C. Rao, J.Q. Dai, C.W. Wang, G. Pastel, L.B. Hu, An electron/ion dual-conductive alloy framework for high-rate and high-capacity solid-state lithium-metal batteries, Adv Mater 31 (3) (2019) e1804815
[13] W.D. Zhou, S.F. Wang, Y.T. Li, S. Xin, A. Manthiram, J.B. Goodenough, Plating a dendrite-free lithium anode with a polymer/ceramic/polymer sandwich electrolyte, J Am Chem Soc 138 (30) (2016) 9385-9388
[14] S.S. Chi, Y.C. Liu, N. Zhao, X.X. Guo, C.W. Nan, L.Z. Fan, Solid polymer electrolyte soft interface layer with 3D lithium anode for all-solid-state lithium batteries, Energy Storage Mater. 17 (2019) 309-316
[15] H. Duan, Y.X. Yin, Y. Shi, P.F. Wang, X.D. Zhang, C.P. Yang, J.L. Shi, R. Wen, Y.G. Guo, L.J. Wan, Dendrite-free Li-metal battery enabled by a thin asymmetric solid electrolyte with engineered layers, J Am Chem Soc 140 (1) (2018) 82-85
[16] S. Laruelle, S. Grugeon, P. Poizot, M. Dollé, L. Dupont, J.M. Tarascon, On the origin of the extra electrochemical capacity displayed by MO/Li cells at low potential, J. Electrochem. Soc. 149 (5) (2002):A627
[17] D.W. Zhang, S.Q. Zhang, Y. Jin, T.H. Yi, S. Xie, C.H. Chen, Li₂SnO₃ derived secondary Li-Sn alloy electrode for lithium-ion batteries, J. Alloy. Compd. 415 (1-2) (2006) 229-233
[18] Y. Yu, C.H. Chen, Y. Shi, A tin-based amorphous oxide composite with a porous, spherical, multideck-cage morphology as a highly reversible anode material for lithium-ion batteries, Adv. Mater. 19 (7) (2007) 993-997
[19] X. Huang, Y. Lu, H.J. Guo, Z. Song, T.P. Xiu, M.E. Badding, Z.Y. Wen, None-mother-powder method to prepare dense Li-garnet solid electrolytes with high critical current density, ACS Appl. Energy Mater. 1 (10) (2018) 5355-5365
[20] J. Wolfenstine, J.L. Allen, J. Read, J. Sakamoto, Chemical stability of cubic Li₇La₃Zr₂O₁₂ with molten lithium at elevated temperature, J. Mater. Sci. 48 (17) (2013) 5846-5851
[21] Y. Meesala, Y.K. Liao, A. Jena, N.H. Yang, W.K. Pang, S.F. Hu, H. Chang, C.E. Liu, S.C. Liao, J.M. Chen. An efficient multi-doping strategy to enhance Li-ion conductivity in the garnet-type solid electrolyte Li₇La₃Zr₂O₁₂, J. Mater. Chem. 7 (14) (2019) 8589-8601
[22] L.X. Yuan, X.P. Qiu, L.Q. Chen, W.T. Zhu, New insight into the discharge process of sulfur cathode by electrochemical impedance spectroscopy, J. Power Sources 189 (1) (2009) 127-132
[23] L. Wang, J.S. Zhao, X.M. He, C.R. Wan, Kinetic investigation of sulfurized polyacrylonitrile cathode material by electrochemical impedance spectroscopy, Electrochimica Acta 56 (14) (2011) 5252-5256
[24] V.S. Kolosnitsyn, E.V. Kuzmina, E.V. Karaseva, S.E. Mochalov, A study of the electrochemical processes in lithium-sulphur cells by impedance spectroscopy, J. Power Sources 196 (3) (2011) 1478-1482
[25] W. Ahn, K.B. Kim, K.N. Jung, K.H. Shin, C.S. Jin, Synthesis and electrochemical properties of a sulfur-multi walled carbon nanotubes composite as a cathode material for lithium sulfur batteries, J. Power Sources 202 (2012) 394-399
[26] G.V. Alexander, O.V. Sreejith, M.S. Indu, R. Murugan, Interface-compatible and high-cyclability lithiophilic lithium-zinc alloy anodes for garnet-structured solid electrolytes, ACS Appl. Energy Mater. 3 (9) (2020) 9010-9017
[27] M. Trybula, T. Gancarz, W. Gasior, A. Pasturel, Bulk and surface properties of liquid Al-Li and Li-Zn alloys, Metall. Mater. Trans. A 45 (12) (2014) 5517-5530
[28] W.L. Huang, N. Zhao, Z.J. Bi, C. Shi, X.X. Guo, L.Z. Fan, C.W. Nan, Can we find solution to eliminate Li penetration through solid garnet electrolytes?Mater. Today Nano 10 (2020) 100075
[29] F.M. Du, N. Zhao, Y.Q. Li, C. Chen, Z.W. Liu, X.X. Guo, All solid state lithium batteries based on lamellar garnet-type ceramic electrolytes, J. Power Sources 300 (2015) 24-28
[30] M.M. Hiller, M. Joost, H.J. Gores, S. Passerini, H.D. Wiemhöfer, The influence of interface polarization on the determination of lithium transference numbers of salt in polyethylene oxide electrolytes, Electrochimica Acta 114 (2013) 21-29

Enhanced electrochemical performance of garnet-based solid-state lithium metal battery with modified anodic and cathodic interfaces

Enhanced electrochemical performance of garnet-based solid-state lithium metal battery with modified anodic and cathodic interfaces

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