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J. Phys. Energy 2 (2020) 032008 M Pasta et al [63] Liu J et al 2020 The Interface between Li6.5La3Zr1.5Ta0.5O12 and Liquid Electrolyte Joule 4 1–8 [64] Naguib M, Sharafi A, Self E C, Meyer H M, Sakamoto J and Nanda J 2019 Interfacial Reactions and Performance of Li7La3Zr2O12-Stabilized Li-Sulfur Hybrid Cell ACS Appl. Mater. Interfaces 11 42042–8 [65] Peled E and Menkin S 2017 Review—SEI: past, present and future J. Electrochem. Soc. 164 A1703–19 [66] Lu J, Wu T and Amine K 2017 State-of-the-art characterization techniques for advanced lithium-ion batteries Nature Energy 2 17011 [67] Moulder J F, Stickle W F, Sobol P E and Bomben K D 1992 Handbook of X-ray Photoelectron Spectroscopy (Waltham, MA: Perkin-Elmer Corporation) [68] Yoon I, Jurng S, Abraham D P, Lucht B L and Guduru P R 2020 Measurement of mechanical and fracture properties of solid electrolyte interphase on lithium metal anodes in lithium ion batteries Energy Storage Mater. 25 296–304 [69] Forsyth M, Porcarelli L, Wang X, Goujon N and Mecerreyes D 2019 Innovative electrolytes based on ionic liquids and polymers for next-generation solid-state batteries Acc. Chem. Res. 52 686–94 [70] Jeong K, Park S and Lee S Y 2019 Revisiting polymeric single lithium-ion conductors as an organic route for all-solid-state lithium ion and metal batteries J. Mater. Chem. 7 1917–35 [71] Lopez J, Mackanic D G, Cui Y and Bao Z 2019 Designing polymers for advanced battery chemistries Nature Rev. Mater. 4 312–30 [72] Mindemark J, Lacey M J, Bowden T and Brandell D 2018 Beyond PEO—Alternative host materials for Li+-conducting solid polymer electrolytes Prog. Polym. Sci. 81 114–43 [73] Cao X H, Li J H, Yang M J, Yang J L, Wang R Y, Zhang X H and Xu J T 2020 Simultaneous improvement of ionic conductivity and mechanical strength in block copolymer electrolytes with double conductive nanophases Macromolecular Rapid Commun. 41 1900622 [74] Bergfelt A, Hern ́andez G, Mogensen R, Lacey M J, Mindemark J, Brandell D and Bowden T M 2020 Mechanically robust yet highly conductive diblock copolymer solid polymer electrolyte for ambient temperature battery applications ACS Applied Polymer Materials 2 939–48 [75] Meabe L, Goujon N, Li C, Armand M, Forsyth M and Mecerreyes D 2020 Single-ion conducting poly(ethylene oxide carbonate) as solid polymer electrolyte for lithium batteries Batteries Supercaps 3 68–75 [76] Porcarelli L, Aboudzadeh M A, Rubatat L, Nair J R, Shaplov A S, Gerbaldi C and Mecerreyes D 2017 Single-ion triblock copolymer electrolytes based on poly(ethylene oxide) and methacrylic sulfonamide blocks for lithium metal batteries J. Power Sources 364 191–9 [77] Meabe L et al 2019 UV-cross-linked poly(ethylene oxide carbonate) as free standing solid polymer electrolyte for lithium batteries Electrochim. Acta 302 414–21 [78] Deng K, Wang S, Ren S, Han D, Xiao M and Meng Y 2016 A novel single-ion-conducting polymer electrolyte derived from CO2-based multifunctional polycarbonate ACS Appl. Mater. Interfaces 8 33642–8 [79] Zhang J et al 2017 High-voltage and free-standing poly(propylene carbonate)/Li6.75La3Zr1.75Ta0.25O12 composite solid electrolyte for wide temperature range and flexible solid lithium ion battery J. Mater. Chem. A 5 4940–8 [80] Hatakeyama-Sato K, Tezuka T, Umeki M and Oyaizu K 2020 AI-Assisted Exploration of Superionic Glass-Type Li+ Conductors with Aromatic Structures J. Am. Chem. Soc. 142 3301–5 [81] Ebadi M, Marchiori C, Mindemark J, Brandell D and Araujo C M 2019 Assessing structure and stability of polymer/lithium-metal interfaces from first-principles calculations J. Mater. Chem. 7 8394–404 [82] Tominaga Y, Kinno Y and Kimura K 2019 An end-capped poly(ethylene carbonate)-based concentrated electrolyte for stable cyclability of lithium battery Electrochim. Acta 302 286–90 [83] Thangadurai V, Kaack H and Weppner W J 2003 Novel fast lithium ion conduction in garnet-type Li5La3M2O12 (M = Nb, Ta) J. Am. Ceram. Soc. 86 437–40 [84] Murugan R, Thangadurai V and Weppner W 2007 Fast lithium ion conduction in garnet-type Li7La3Zr2O12 Angewandte Chemie - Int. edn 46 7778–81 [85] Awaka J, Kijima N, Hayakawa H and Akimoto J 2009 Synthesis and structure analysis of tetragonal Li7La3Zr2O12 with the garnet-related type structure J. Solid State Chem. 182 2046–52 [86] Cussen E J 2010 Structure and ionic conductivity in lithium garnets J. Mater. Chem. 20 5167–73 [87] Samson A J, Hofstetter K, Bag S and Thangadurai V 2019 A bird’s-eye view of Li-stuffed garnet-type Li7La3Zr2O12 ceramic electrolytes for advanced all-solid-state Li batteries Energy Environ. Sci. 12 2957–75 [88] Schwietert T K et al 2020 Clarifying the relationship between redox activity and electrochemical stability in solid electrolytes Nat. Mater. 19 428–35 [89] Thompson T, Sharafi A, Johannes M D, Huq A, Allen J L, Wolfenstine J and Sakamoto J 2015 A tale of two sites: On defining the carrier concentration in Garnet-based ionic conductors for advanced Li batteries Adv. Energy Mater. 5 1500096 [90] Kim Y, Yoo A, Schmidt R, Sharafi A, Lee H, Wolfenstine J and Sakamoto J 2016 Electrochemical stability of Li6.5La3Zr1.5M0.5O12 (M = Nb or Ta) against metallic lithium Frontiers in Energy Research 4 1–7 [91] Liu B, Yang J, Yang H, Ye C, Mao Y, Wang J, Shi S, Yang J and Zhang W 2019 Rationalizing the interphase stability of Li doped-Li7La3Zr2O12: Via automated reaction screening and machine learning J. Mater. Chem. A 7 19961–9 [92] Huo H, Luo J, Thangadurai V, Guo X, Nan C W and Sun X 2020 Li2CO3: a critical issue for developing solid garnet batteries ACS Energy Letters 5 252–62 [93] Amores M, Ashton T E, Baker P J, Cussen E J and Corr S A 2016 Fast microwave-assisted synthesis of Li-stuffed garnets and insights into Li diffusion from muon spin spectroscopy J. Mater. Chem. A 4 1729–36 [94] Li Y et al 2017 Hybrid polymer/garnet electrolyte with a small interfacial resistance for lithium-ion batteries Angewandte Chemie - Int. edn 56 753–6 [95] Han F et al 2019 High electronic conductivity as the origin of lithium dendrite formation within solid electrolytes Nature Energy 4 187–96 [96] Shen H, Yi E, Cheng L, Amores M, Chen G, Sofie S W and Doeff M M 2019 Solid-state electrolyte considerations for electric vehicle batteries Sustainable Energy and Fuels 3 1647–59 [97] El-Shinawi H, Paterson G W, MacLaren D A, Cussen E J and Corr S A 2017 Low-temperature densification of Al-doped Li7La3Zr2O12 a reliable and controllable synthesis of fast-ion conducting garnets J. Mater. Chem. A 5 319–29 [98] El-Shinawi H, Regoutz A, Payne D J, Cussen E J and Corr S A 2018 NASICON LiM2(PO4)3 electrolyte (M = Zr) and electrode (M = Ti) materials for all solid-state Li-ion batteries with high total conductivity and low interfacial resistance J. Mater. Chem. A 6 5296–303 [99] Ma C et al 2016 Interfacial stability of Li metal-solid electrolyte elucidated via in situ electron microscopy Nano Lett. 16 7030–6 50PDF Image | 2020 roadmap on solid-state batteries
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