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Mazzapioda et al. Energy Mater 2023;3:300019 https://dx.doi.org/10.20517/energymater.2023.03 Page 27 of 30

46. Thangadurai V, Narayanan S, Pinzaru D. Garnet-type solid-state fast Li ion conductors for Li batteries: critical review. Chem Soc Rev
2014;43:4714-27. DOI PubMed
47. Murugan R, Thangadurai V, Weppner W. Fast lithium ion conduction in garnet-type Li La Zr O . Angew Chem Int Ed
2
12
7
3
2007;46:7778-81. DOI PubMed
48. Wang W, Wang X, Gao Y, Fang Q. Lithium-ionic diffusion and electrical conduction in the Li La Ta O compounds. Solid State Ion
7 3 2 13
2009;180:1252-6. DOI
49. Mariappan CR, Gnanasekar KI, Jayaraman V, Gnanasekaran T. Lithium ion conduction in Li La Ta O and Li La Ta O garnet-
5 3 2 12 7 3 2 13
type materials. J Electroceram 2013;30:258-65. DOI
+
50. Cussen EJ. The structure of lithium garnets: cation disorder and clustering in a new family of fast Li conductors. Chem Commun
2006:412-3. DOI
51. Wu JF, Pang WK, Peterson VK, Wei L, Guo X. Garnet-type fast Li-ion conductors with high ionic conductivities for all-solid-state
batteries. ACS Appl Mater Interfaces 2017;9:12461-8. DOI
52. Xia W, Xu B, Duan H, et al. Ionic conductivity and air stability of Al-doped Li La Zr O sintered in alumina and Pt crucibles. ACS
7 3 2 12
Appl Mater Interfaces 2016;8:5335-42. DOI
53. Sharafi A, Yu S, Naguib M, et al. Impact of air exposure and surface chemistry on Li-Li La Zr O interfacial resistance. J Mater
7 3 2 12
Chem A 2017;5:13475-87. DOI
54. Sun Y, Guan P, Liu Y, Xu H, Li S, Chu D. Recent progress in lithium lanthanum titanate electrolyte towards all solid-state lithium
ion secondary battery. Crit Rev Solid State 2019;44:265-82. DOI
55. Stramare S, Thangadurai V, Weppner W. Lithium lanthanum titanates: a review. Chem Mater 2003;15:3974-90. DOI
56. Inaguma Y, Liquan C, Itoh M, et al. High ionic conductivity in lithium lanthanum titanate. Solid State Commun 1993;86:689-93.
DOI
57. Yan S, Yim C, Pankov V, et al. Perovskite solid-state electrolytes for lithium metal batteries. Batteries 2021;7:75. DOI
58. Chen C. Ionic conductivity, lithium insertion and extraction of lanthanum lithium titanate. Solid State Ion 2001;144:51-7. DOI
+
59. Hong H. Crystal structure and ionic conductivity of Li Zn(GeO ) and other new Li superionic conductors. Mater Res Bull
4 4
14
1978;13:117-24. DOI
60. West AR. Crystal chemistry of some tetrahedral oxides. Z Kristallogr 1975;141:422-36. DOI
61. Shannon R, Taylor B, English A, Berzins T. New Li solid electrolytes. Electrochim Acta 1977;22:783-96. DOI
62. Hu Y, Raistrick ID, Huggins RA. Ionic conductivity of lithium orthosilicate - lithium phosphate solid solutions. J Electrochem Soc
1977;124:1240-2. DOI
63. Lau J, Deblock RH, Butts DM, Ashby DS, Choi CS, Dunn BS. Sulfide solid electrolytes for lithium battery applications. Adv Energy
Mater 2018;8:1800933. DOI
64. Yu X, Bates JB, Jellison GE, Hart FX. A stable thin-film lithium electrolyte: lithium phosphorus oxynitride. J Electrochem Soc
1997;144:524-32. DOI
65. Oudenhoven JFM, Baggetto L, Notten PHL. All-solid-state lithium-ion microbatteries: a review of various three-dimensional
concepts. Adv Energy Mater 2011;1:10-33. DOI
66. Nowak S, Berkemeier F, Schmitz G. Ultra-thin LiPON films - fundamental properties and application in solid state thin film model
batteries. J Power Sources 2015;275:144-50. DOI
67. Bates J, Dudney N, Gruzalski G, et al. Fabrication and characterization of amorphous lithium electrolyte thin films and rechargeable
thin-film batteries. J Power Sources 1993;43:103-10. DOI
68. Cheng D, Wynn TA, Wang X, et al. Unveiling the stable nature of the solid electrolyte interphase between lithium metal and LiPON
via cryogenic electron microscopy. Joule 2020;4:2484-500. DOI
69. López-aranguren P, Reynaud M, Głuchowski P, et al. Crystalline LiPON as a bulk-type solid electrolyte. ACS Energy Lett
2021;6:445-50. DOI
70. Zhang X, Temeche E, Laine RM. Design, synthesis, and characterization of polymer precursors to Li PON and Li SiPON Glasses:
x
x
materials that enable all-solid-state batteries. Macromolecules 2020;53:2702-12. DOI
71. Lee S, Bae J, Lee H, Baik H, Lee S. Electrical conductivity in Li-Si-P-O-N oxynitride thin-films. J Power Sources 2003;123:61-4.
DOI
+
72. Su Y, Falgenhauer J, Leichtweiß T, et al. Electrochemical properties and optical transmission of high Li conducting LiSiPON
+
electrolyte films: electrochemical properties of high Li conducting LiSiPON electrolyte films. Phys Status Solidi B
2017;254:1600088. DOI
73. Wang W, Jiang B, Hu L, Jiao S. Nasicon material NaZr (PO ) : a novel storage material for sodium-ion batteries. J Mater Chem A
4 3
2
2014;2:1341-5. DOI
74. Zhao D, Xie Z, Hu J, et al. Structure determination, electronic and optical properties of NaGe P O and Cs GeP O . J Molecular
2 3 12 2 4 13
Struct 2009;922:127-34. DOI
75. Ortiz-mosquera JF, Nieto-muñoz AM, Rodrigues AC. Precursor glass stability, microstructure and ionic conductivity of glass-
ceramics from the Na Al Ge (PO ) NASICON series. J Non-Cryst Solids 2019;513:36-43. DOI
1+x
x
4 3
2-x
76. Wu M, Ni W, Hu J, Ma J. NASICON-structured NaTi (PO ) for sustainable energy storage. Nano-Micro Lett 2019;11:44. DOI
4 3
2
PubMed PMC
77. Bachman JC, Muy S, Grimaud A, et al. Inorganic solid-state electrolytes for lithium batteries: mechanisms and properties governing

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