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NTIS 바로가기멤브레인 = Membrane Journal, v.31 no.6, 2021년, pp.417 - 425
이상현 (광운대학교 화학공학과) , 최상석 (광운대학교 화학공학과) , 김동언 (광운대학교 화학공학과) , 현준혁 (광운대학교 화학공학과) , 박용욱 (광운대학교 화학공학과) , 유진성 (광운대학교 화학공학과) , 전소윤 (광운대학교 화학공학과) , 박중원 (광운대학교 화학공학과) , 신원호 (광운대학교 화학공학과) , 손희상 (광운대학교 화학공학과)
As the demand for high-capacity batteries increases, there has been growing researches on the lithium metal anode with a capacity (3,860 mAh/g) of higher than that of conventional one and a low electrochemical potential (-3.040 V). In this study, using the anatase phased TiO2 nanoparticles synthesiz...
B. A. Korgel, "Nanomaterials developments for higher-performance lithium ion batteries", J. Phys. Chem. Lett., 5, 749 (2014).
L. Yue, J. Ma, J. Zhang, J. Zhao, S. Dong, Z. Liu, G. Cui, and L. Chen, "All solid-state polymer electrolytes for high-performance lithium ion batteries", Energy Storage Mater., 5, 139 (2016).
A. Eftekhari, "Lithium batteries for electric vehicles: From economy to research strategy", ACS Sustain. Chem. Eng., 7, 5602 (2019).
D. Seok, Y. Jeong, K. Han, D. Y. Yoon, and H. Sohn, "Recent progress of electrochemical energy devices: Metal oxide-carbon nanocomposites as materials for next-generation chemical storage for renewable energy", Sustainability, 11, 3694 (2019).
H. Jung, M. Park, Y.-G. Yoon, G.-B. Kim, and S.-K. Joo, "Amorphous silicon anode for lithiumion rechargeable batteries", J. Power Sources, 115, 346 (2003).
J. Xiao, W. Xu, D. Wang, D. Choi, W. Wang, X. Li, G. L. Graff, J. Liu, and J.-G. Zhang, "Stabilization of silicon anode for Li-ion batteries", J. Electrochem. Soc., 157, A1047 (2010).
G. Huang, J. Han, Z. Lu, D. Wei, H. Kashani, K. Watanabe, and M. Chen, "Ultrastable silicon anode by three-dimensional nanoarchitecture design", ACS Nano, 14, 4374 (2020).
K. Hwang, N. Kim, Y. Jeong, H. Sohn, and S. Yoo, "Controlled nanostructure of a graphene nano-sheet-TiO 2 composite fabricated via mediation of organic ligands for high-performance Li storage applications", Int. J. Energy Res., 45, 16189 (2021).
D. Seok, W. H. Shin, S. W. Kang, and H. Sohn, "Piezoelectric composite of BaTiO 3 -coated SnO 2 microsphere: Li-ion battery anode with enhanced electrochemical performance based on accelerated Li + mobility", J. Alloys Compd., 870, 159267 (2021).
H. Ota, K. Shima, M. Ue, and J.-i. Yamaki, "Effect of vinylene carbonate as additive to electrolyte for lithium metal anode", Electrochim. Acta, 49, 565 (2004).
F. Dai, R. Yi, H. Yang, Y. Zhao, L. Luo, M. L. Gordin, H. Sohn, S. Chen, C. Wang, S. Zhang, and D. Wang, "Minimized volume expansion in hierarchical porous silicon upon lithiation", ACS Appl. Mater. Interfaces, 11, 13257 (2019).
K. Hwang, H. Sohn, and S. Yoon, "Mesostructured niobium-doped titanium oxide-carbon (Nb-TiO 2 -C) composite as an anode for high-performance lithium-ion batteries", J. Power Sources, 378, 225 (2018).
H. Sohn, D. H. Kim, R. Yi, D. Tang, S.-E. Lee, Y. S. Jung, and D. Wang, "Semimicro-size agglomerate structured silicon-carbon composite as an anode material for high performance lithium-ion batteries", J. Power Sources, 334, 128 (2016).
H. Sohn, Z. Chen, Y. S. Jung, Q. Xiao, M. Cai, H. Wang, and Y. Lu, "Robust lithium-ion anodes based on nanocomposites of iron oxide-carbon-silicate", J. Mater. Chem. A, 1, 4539 (2013).
Y. Jeong, J. Park, S. Lee, S. H. Oh, W. J. Kim, Y. J. Ji, G. Y. Park, D. Seok, W. H. Shin, J.-M. Oh, T. Lee, C. Park, A. Seubsai, and H. Sohn, "Iron oxide-carbon nanocomposites modified by organic ligands: Novel pore structure design of anode materials for lithium-ion batteries", J. Elec. Anal. Chem., 904, 115905 (2022).
B. Liu, J.-G. Zhang, and W. Xu, "Advancing lithium metal batteries", Joule, 2, 833 (2018).
S. Park, H.-J. Jin, and Y. S. Yun, "Advances in the design of 3D-structured electrode materials for lithium-metal anodes", Adv. Mater., 32, 2002193 (2020).
H. Sohn, M. L. Gordin, M. Regula, D. H. Kim, Y. S. Jung, J. Song, and D. Wang, "Porous spherical polyacryonitrile-carbon nanocomposite with high loading of sulfur for lithium-sulfur batteries", J. Power Sources, 302, 70 (2016).
F. Ding, W. Xu, G. L. Graff, J. Zhang, M. L. Sushko, X. Chen, Y. Shao, M. H. Engelhard, Z. Nie, J. Xiao, X. Liu, P. V. Sushko, J. Liu, and J.-G. Zhang, "Dendrite-free lithium deposition via self-healing electrostatic shield mechanism", J. Am. Chem. Soc., 135, 4450 (2013).
J. Z. Hu, Z. Zhao, M. Y. Hu, J. Feng, X. Deng, X. Chen, W.Xu, J. Liu, and J.-G. Zhang, "In situ 7 Li and 133 Cs nuclear magnetic resonance investigations on the role of Cs + additive in lithium-metal deposition process", J. Power Sources, 304, 51 (2016).
C. Yan, X.-B. Cheng, Y. Tian, X. Chen, X.-Q. Zhang, W.-J. Li, J.-Q. Huang, and Q. Zhang, "Dual-layered film protected lithium metal anode to enable dendrite-free lithium deposition", Adv. Mater., 30, 1707629 (2018).
H. Liu, H. Zhou, B.-S. Lee, X. Xing, M. Gonzalez, and P. Liu, "Suppressing lithium dendrite growth with a single-component coating", ACS Appl. Mater. Interfaces, 9, 30635 (2017).
G. Yang, J. Chen, P. Xiao, P. O. Agboola, I. Shakir, and Y. Xu, "Graphene anchored on Cu foam as a lithiophilic 3D current collector for a stable and dendrite-free lithium metal anode", J. Mater. Chem. A, 6, 9899 (2018).
Y. Cheng, X. Ke, Y. Chen, X. Huang, Z. Shi, and Z. Guob, "Lithiophobic-lithiophilic composite architecture through co-deposition technology toward high-performance lithium metal batteries", Nano Energy, 63, 103854 (2019).
H. Liu, X. Wang, H. Zhou, H.-D. Lim, X. Xing, Q. Yan, Y. S. Meng, and P. Liu, "Structure and solution dynamics of lithium methyl carbonate as a protective layer for lithium metal", ACS Appl. Energy Mater., 1, 1864 (2018).
Y. Zhong, Y. Chen, Y. Cheng, Q. Fan, H. Zhao, H. Shao, Y. Lai, Z. Shi, X. Ke, and Z. Guo, "Li alginate-based artificial SEI layer for stable lithium metal anodes", ACS Appl. Mater. Interfaces, 11, 37726 (2019).
W. Liu, W. Li, D. Zhuo, G. Zheng, Z. Lu, K. Liu, and Y. Cui, "Core-shell nanoparticle coating as an interfacial layer for dendrite-free lithium metal anodes", ACS Cent. Sci., 3, 135 (2017).
Z. Wen, Y. Peng, J. Cong, H. Hua, Y. Lin, J. Xiong, J. Zeng, and J. Zhao, "A stable artificial protective layer for high capacity dendrite-free lithium metal anode", Nano Res. 12, 2535 (2019).
H. Xie, Z. Tang, Z. Li, Y. He, Y. Liu, and H. Wang, "PVDF-HFP composite polymer electrolyte with excellent electrochemical properties for Li-ion batteries", J. Solid State Electrochem., 12, 1497 (2008).
A. M. Stephan, K. S. Nahm, M. A. Kulandainathan, G. Ravi, and J. Wilson, "Poly (vinylidene fluoridehexafluoropropylene)(PVdF-HFP) based composite electrolytes for lithium batteries", Eur. Polym. J., 42, 1728 (2006).
B. Zhu, Y. Jin, X. Hu, Q. Zheng, S. Zhang, Q. Wang, and J. Zhu, "Poly (dimethylsiloxane) thin film as a stable interfacial layer for high-performance lithium-metal battery anodes", Adv. Mater., 29, 1603755 (2017).
Y. Nan, S. Li, B. Li, and S. Yang, "An artificial TiO 2 /lithium n-butoxide hybrid SEI layer with facilitated lithium-ion transportation ability for stable lithium anodes", Nanoscale, 11, 2194 (2019).
X. Lu, P. Hao, G. Xie, J. Duan, L. Gao, and B. Liu, "A sensor array realized by a single flexible TiO 2 /POMs film to contactless detection of triacetone triperoxide", Sensors, 19, 915 (2019).
M. Xie, L. Jing, J. Zhou, J. Lin, and H. Fu, "Synthesis of nanocrystalline anatase TiO 2 by one-pot two-phase separated hydrolysis-solvothermal processes and its high activity for photocatalytic degradation of rhodamine B", J. Hazard. Mater., 176, 139 (2010).
K. Hwang, N. Kim, Y. Jeong, H. Sohn, and S. Yoon, "Controlled nanostructure of a graphene nanosheet-TiO 2 composite fabricated via mediation of organic ligands for high-performance Li storage applications", Int. J. Energy Res., 45, 16189 (2021).
H. Sohn, D. Kim, J. Lee, and S. Yoon, "Facile synthesis of a mesostructured TiO 2 -graphitized carbon (TiO 2 -gC) composite through the hydrothermal process and its application as the anode of lithium ion batteries", RSC Adv., 6, 39484 (2016).
Singh, V. Kumar, and R. K. Singh., "Development of ion conducting polymer gel electrolyte membranes based on polymer PVdF-HFP, BMIMTFSI ionic liquid and the Li-salt with improved electrical, thermal and structural properties", J. Mater. Chem. C, 3, 7305 (2015).
M. Wang, X. Cheng, T. Cao, J. Niu, R. Wu, X. Liu, Y. Zhang, "Constructing ultrathin TiO 2 protection layers via atomic layer deposition for stable lithium metal anode cycling", J. Alloys Compd., 865, 158748 (2021).
R. Zhang, X.-R. Chen, X. Chen, X.-B. Cheng, X.-Q. Zhang, C. Yan, and Q. Zhang, "Lithiophilic sites in doped graphene guide uniform lithium nucleation for dendrite-free lithium metal anodes", Angew. Chem., Int. Ed., 129, 7872 (2017).
L. Pan, Z. Luo, Y. Zhang, W. Chen, Z. Zhao, Y. Li, J. Wan, D. Yu, H. He, and D. Wang, "Seed-free selective deposition of lithium metal into tough graphene framework for stable lithium metal anode", ACS Appl. Mater. Interfaces, 11, 44383 (2019).
R. Xu, X.-Q. Zhang, X.-B. Cheng, H.-J. Peng, C.-Z. Zhao, C. Yan, and J.-Q. Huang, "Artificial soft-rigid protective layer for dendrite-free lithium metal anode", Adv. Funct. Mater., 28, 1705838 (2018).
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