Page 77 - Read Online
P. 77
Page 28 of 30 Mazzapioda et al. Energy Mater 2023;3:300019 https://dx.doi.org/10.20517/energymater.2023.03
ion conduction. Chem Rev 2016;116:140-62. DOI
78. Tan G, Wu F, Li L, Liu Y, Chen R. Magnetron sputtering preparation of nitrogen-incorporated lithium-aluminum-titanium phosphate
based thin film electrolytes for all-solid-state lithium ion batteries. J Phys Chem C 2012;116:3817-26. DOI
79. Illbeigi M, Fazlali A, Kazazi M, Mohammadi AH. Effect of simultaneous addition of aluminum and chromium on the lithium ionic
conductivity of LiGe (PO ) NASICON-type glass-ceramics. Solid State Ion 2016;289:180-7. DOI
2 4 3
80. Kamaya N, Homma K, Yamakawa Y, et al. A lithium superionic conductor. Nat Mater 2011;10:682-6. DOI
81. Mo Y, Ong SP, Ceder G. First principles study of the Li GeP S lithium super ionic conductor material. Chem Mater 2012;24:15-7.
2 12
10
DOI
82. Adams S, Prasada Rao R. Structural requirements for fast lithium ion migration in Li GeP S . J Mater Chem 2012;22:7687. DOI
10 2 12
83. Hu C, Wang Z, Sun Z, Ouyang C. Insights into structural stability and Li superionic conductivity of Li GeP S from first-principles
10 2 12
calculations. Chem Phys Lett 2014;591:16-20. DOI
84. Chen S, Xie D, Liu G, et al. Sulfide solid electrolytes for all-solid-state lithium batteries: structure, conductivity, stability and
application. Energy Stor Mater 2018;14:58-74. DOI
85. Dietrich C, Weber DA, Sedlmaier SJ, et al. Lithium ion conductivity in Li S-P S glasses - building units and local structure evolution
2 2 5
during the crystallization of superionic conductors Li PS , Li P S and Li P S . J Mater Chem A 2017;5:18111-9. DOI
3
4
4 2 7
7 3 11
86. Wang G, Lin C, Gao C, et al. Hydrolysis-resistant and anti-dendritic halide composite Li PS -LiI solid electrolyte for all-solid-state
4
3
lithium batteries. Electrochim Acta 2022;428:140906. DOI
87. Calpa M, Rosero-navarro NC, Miura A, Jalem R, Tateyama Y, Tadanaga K. Chemical stability of Li PS I solid electrolyte against
4 4
hydrolysis. Appl Mater Today 2021;22:100918. DOI
88. Rao RP, Adams S. Studies of lithium argyrodite solid electrolytes for all-solid-state batteries: studies of lithium argyrodite solid
electrolytes. Phys Status Solidi A 2011;208:1804-7. DOI
89. Boulineau S, Courty M, Tarascon J, Viallet V. Mechanochemical synthesis of Li-argyrodite Li PS X (X = Cl, Br, I) as sulfur-based
6 5
solid electrolytes for all solid state batteries application. Solid State Ion 2012;221:1-5. DOI
90. Deiseroth H, Maier J, Weichert K, Nickel V, Kong S, Reiner C. Li PS and Li PS X (X: Cl, Br, I): possible three-dimensional
6
6
7
5
diffusion pathways for lithium ions and temperature dependence of the ionic conductivity by impedance measurements. Z Anorg Allg
Chem 2011;637:1287-94. DOI
+
91. Deiseroth HJ, Kong ST, Eckert H, et al. Li PS X: a class of crystalline Li-rich solids with an unusually high Li mobility. Angew
6 5
Chem Int Ed 2008;47:755-8. DOI
92. Zhu Y, He X, Mo Y. First principles study on electrochemical and chemical stability of solid electrolyte-electrode interfaces in all-
solid-state Li-ion batteries. J Mater Chem A 2016;4:3253-66. DOI
93. Wang S, Wu Y, Ma T, Chen L, Li H, Wu F. Thermal stability between sulfide solid electrolytes and oxide cathode. ACS Nano
2022;16:16158-76. DOI
94. Paul PP, Chen B, Langevin SA, Dufek EJ, Nelson Weker J, Ko JS. Interfaces in all solid state Li-metal batteries: a review on
instabilities, stabilization strategies, and scalability. Energy Stor Mater 2022;45:969-1001. DOI
95. Pervez SA, Cambaz MA, Thangadurai V, Fichtner M. Interface in solid-state lithium battery: challenges, progress, and outlook. ACS
Appl Mater Interfaces 2019;11:22029-50. DOI PubMed
96. Goodenough JB, Kim Y. Challenges for rechargeable Li batteries. Chem Mater 2010;22:587-603. DOI
97. Banerjee A, Wang X, Fang C, Wu EA, Meng YS. Interfaces and interphases in all-solid-state batteries with inorganic solid
electrolytes. Chem Rev 2020;120:6878-933. DOI
98. Wenzel S, Leichtweiss T, Krüger D, Sann J, Janek J. Interphase formation on lithium solid electrolytes - an in situ approach to study
interfacial reactions by photoelectron spectroscopy. Solid State Ion 2015;278:98-105. DOI
99. Zhu Y, He X, Mo Y. Origin of outstanding stability in the lithium solid electrolyte materials: insights from thermodynamic analyses
based on first-principles calculations. ACS Appl Mater Interfaces 2015;7:23685-93. DOI PubMed
100. Wenzel S, Weber DA, Leichtweiss T, Busche MR, Sann J, Janek J. Interphase formation and degradation of charge transfer kinetics
between a lithium metal anode and highly crystalline Li P S solid electrolyte. Solid State Ion 2016;286:24-33. DOI
7 3 11
101. Wenzel S, Randau S, Leichtweiß T, et al. Direct observation of the interfacial instability of the fast ionic conductor Li GeP S at the
10 2 12
lithium metal anode. Chem Mater 2016;28:2400-7. DOI
102. Cheng L, Crumlin EJ, Chen W, et al. The origin of high electrolyte-electrode interfacial resistances in lithium cells containing garnet
type solid electrolytes. Phys Chem Chem Phys 2014;16:18294-300. DOI
103. Aatiq A, Ménétrier M, Croguennec L, Suard E, Delmas C. On the structure of Li Ti (PO ) . J Mater Chem 2002;12:2971-8. DOI
2
3
4 3
104. Ma C, Cheng Y, Yin K, et al. Interfacial stability of Li metal-solid electrolyte elucidated via in situ electron microscopy. Nano Lett
2016;16:7030-6. DOI
105. Zhu Y, Connell JG, Tepavcevic S, et al. Dopant-dependent stability of garnet solid electrolyte interfaces with lithium metal. Adv
Energy Mater 2019;9:1803440. DOI
106. Hartmann P, Leichtweiss T, Busche MR, et al. Degradation of NASICON-type materials in contact with lithium metal: formation of
mixed conducting interphases (MCI) on solid electrolytes. J Phys Chem C 2013;117:21064-74. DOI
107. Tolganbek N, Serikkazyyeva A, Kalybekkyzy S, et al. Interface modification of NASICON-type Li-ion conducting ceramic
electrolytes: a critical evaluation. Mater Adv 2022;3:3055-69. DOI
108. Schwöbel A, Hausbrand R, Jaegermann W. Interface reactions between LiPON and lithium studied by in-situ X-ray photoemission.
