Page 174 - Read Online

P. 174

Page 36 of 37 Shipitsyn et al. Energy Mater 2023;3:300038 https://dx.doi.org/10.20517/energymater.2023.22

alloy anode for sodium ion batteries. Nano Energy 2018;54:349-59. DOI
106. Kim IT, Kim SO, Manthiram A. Effect of TiC addition on SnSb-C composite anodes for sodium-ion batteries. J Power
Sources 2014;269:848-54. DOI
107. Kim IT, Allcorn E, Manthiram A. High-performance FeSb-TiC-C nanocomposite anodes for sodium-ion batteries. Phys Chem Chem
Phys 2014;16:12884-9. DOI PubMed
108. Kim IT, Allcorn E, Manthiram A. Cu6Sn5-TiC-C nanocomposite anodes for high-performance sodium-ion batteries. J Power
Sources 2015;281:11-7. DOI
109. Sadan MK, Choi SH, Kim HH, et al. Effect of sodium salts on the cycling performance of tin anode in sodium ion batteries.
Ionics 2018;24:753-61. DOI
110. Qian J, Chen Y, Wu L, Cao Y, Ai X, Yang H. High capacity Na-storage and superior cyclability of nanocomposite Sb/C anode for
Na-ion batteries. Chem Commun 2012;48:7070-2. DOI
111. Ji L, Gu M, Shao Y, et al. Controlling SEI formation on SnSb-porous carbon nanofibers for improved Na ion storage. Adv Mater
2014;26:2901-8. DOI
112. Zhang J, Zhang K, Yang J, et al. Engineering solid electrolyte interphase on red phosphorus for long-term and high-capacity sodium
storage. Chem Mater 2020;32:448-58. DOI
113. Yabuuchi N, Matsuura Y, Ishikawa T, et al. Phosphorus electrodes in sodium cells: small volume expansion by sodiation and the
surface-stabilization mechanism in aprotic solvent. ChemElectroChem 2014;1:580-9. DOI
114. Dahbi M, Yabuuchi N, Fukunishi M, et al. Black phosphorus as a high-capacity, high-capability negative electrode for sodium-ion
batteries: investigation of the electrode/electrolyte interface. Chem Mater 2016;28:1625-35. DOI
115. Li M, Muralidharan N, Moyer K, Pint CL. Solvent mediated hybrid 2D materials: black phosphorus - graphene heterostructured
building blocks assembled for sodium ion batteries. Nanoscale 2018;10:10443-9. DOI PubMed
116. Song J, Wu M, Fang K, Tian T, Wang R, Tang H. NaF-rich interphase and high initial coulombic efficiency of red phosphorus anode
for sodium-ion batteries by chemical presodiation. J Colloid Interface Sci 2023;630:443-52. DOI
117. Capone I, Hurlbutt K, Naylor AJ, Xiao AW, Pasta M. Effect of the particle-size distribution on the electrochemical performance of a
red phosphorus-carbon composite anode for sodium-ion batteries. Energy Fuels 2019;33:4651-8. DOI PubMed PMC
118. Jian Z, Zhao B, Liu P, et al. Fe O nanocrystals anchored onto graphene nanosheets as the anode material for low-cost sodium-ion
2 3
batteries. Chem Commun 2014;50:1215-7. DOI PubMed
119. Hu Z, Wang L, Zhang K, et al. MoS nanoflowers with expanded interlayers as high-performance anodes for sodium-ion batteries.
2
Angew Chem Int Ed Engl 2014;53:12794-8. DOI PubMed
120. Xiong H, Slater MD, Balasubramanian M, Johnson CS, Rajh T. Amorphous TiO nanotube anode for rechargeable sodium ion
2
batteries. J Phys Chem Lett 2011;2:2560-5. DOI
121. Dynarowska M, Kotwiński J, Leszczynska M, Marzantowicz M, Krok F. Ionic conductivity and structural properties of Na Ti O
2 3 7
anode material. Solid State Ionics 2017;301:35-42. DOI
122. Zhao L, Zhao J, Hu YS, et al. Disodium Terephthalate (Na C H O ) as high performance anode material for low-cost
2 8 4 4
room-temperature sodium-ion battery. Adv Energy Mater 2012;2:962-5. DOI
123. Armand M, Endres F, MacFarlane DR, Ohno H, Scrosati B. Ionic-liquid materials for the electrochemical challenges of the future.
Nat Mater 2009;8:621-9. DOI PubMed
124. López-herraiz M, Castillo-martínez E, Carretero-gonzález J, Carrasco J, Rojo T, Armand M. Oligomeric-schiff bases as negative
electrodes for sodium ion batteries: unveiling the nature of their active redox centers. Energy Environ Sci 2015;8:3233-41. DOI
125. Castillo-Martínez E, Carretero-González J, Armand M. Polymeric schiff bases as low-voltage redox centers for sodium-ion batteries.
Angew Chem Int Ed Engl 2014;53:5341-5. DOI PubMed
126. Huang Y, Zhao L, Li L, Xie M, Wu F, Chen R. Electrolytes and electrolyte/electrode interfaces in sodium-ion batteries: from
scientific research to practical application. Adv Mater 2019;31:e1808393. DOI PubMed
127. Kucinskis G, Nesterova I, Sarakovskis A, Bikse L, Hodakovska J, Bajars G. Electrochemical performance of Na FeP O /C cathode
7
2
2
for sodium-ion batteries in electrolyte with fluoroethylene carbonate additive. J Alloys Compd 2022;895:162656. DOI
128. Lee Y, Lee J, Kim H, Kang K, Choi NS. Highly stable linear carbonate-containing electrolytes with fluoroethylene carbonate for
high-performance cathodes in sodium-ion batteries. J Power Sources 2016;320:49-58. DOI
129. Cheng Z, Mao Y, Dong Q, et al. Fluoroethylene carbonate as an additive for sodium-ion batteries: effect on the sodium cathode. Acta
Phys-Chim Sin 2019;35:868-75. DOI
130. Wu S, Su B, Kun N, et al. Fluorinated carbonate electrolyte with superior oxidative stability enables long-term cycle stability of Na
2/3
Ni Mn O cathodes in sodium-ion batteries. Adv Energy Mater 2020;11:2002737. DOI
2
1/3
2/3
131. Shi J, Ding L, Wan Y, et al. Achieving long-cycling sodium-ion full cells in ether-based electrolyte with vinylene carbonate additive.
J Energy Chem 2021;57:650-5. DOI
132. Yang Z, He J, Lai WH, et al. Fire-retardant, stable-cycling and high-safety sodium ion battery. Angew Chem 2021;133:27292-
300. DOI
133. Law M, Ramar V, Balaya P. Na MnSiO as an attractive high capacity cathode material for sodium-ion battery. J Power Sources
2 4
2017;359:277-84. DOI
134. Farhat D, Maibach J, Eriksson H, Edström K, Lemordant D, Ghamouss F. Towards high-voltage Li-ion batteries: reversible cycling
of graphite anodes and Li-ion batteries in adiponitrile-based electrolytes. Electrochimica Acta 2018;281:299-311. DOI

169 170 171 172 173 174 175 176 177 178 179