Page 172 - Read Online

P. 172

Page 34 of 37 Shipitsyn et al. Energy Mater 2023;3:300038 https://dx.doi.org/10.20517/energymater.2023.22

46. Ponrouch A, Goñi AR, Palacín MR. High capacity hard carbon anodes for sodium ion batteries in additive free
electrolyte. Electrochem Commun 2013;27:85-8. DOI
47. Zhu YE, Gu H, Chen YN, Yang D, Wei J, Zhou Z. Hard carbon derived from corn straw piths as anode materials for sodium
ion batteries. Ionics 2018;24:1075-81. DOI
48. Jin J, Yu BJ, Shi ZQ, Wang CY, Chong CB. Lignin-based electrospun carbon nanofibrous webs as free-standing and binder-free
electrodes for sodium ion batteries. J Power Sources 2014;272:800-7. DOI
49. Yang T, Qian T, Wang M, et al. A sustainable route from biomass byproduct okara to high content nitrogen-doped carbon sheets for
efficient sodium ion batteries. Adv Mater 2016;28:539-45. DOI
50. Cao Y, Xiao L, Sushko ML, et al. Sodium ion insertion in hollow carbon nanowires for battery applications. Nano Lett 2012;12:3783-
7. DOI
51. Lotfabad EM, Ding J, Cui K, et al. High-density sodium and lithium ion battery anodes from banana peels. ACS Nano 2014;8:7115-
29. DOI
52. Jiang X, Liu X, Zeng Z, et al. A bifunctional fluorophosphate electrolyte for safer sodium-ion batteries. iScience 2018;10:114-22.
DOI PubMed PMC
53. Li Y, Xu S, Wu X, et al. Amorphous monodispersed hard carbon micro-spherules derived from biomass as a high performance
negative electrode material for sodium-ion batteries. J Mater Chem A 2015;3:71-7. DOI
54. Li W, Zeng L, Yang Z, et al. Free-standing and binder-free sodium-ion electrodes with ultralong cycle life and high rate performance
based on porous carbon nanofibers. Nanoscale 2014;6:693-8. DOI
55. Ding J, Wang H, Li Z, et al. Carbon nanosheet frameworks derived from peat moss as high performance sodium ion battery anodes.
ACS Nano 2013;7:11004-15. DOI
56. Liu X, Jiang X, Zeng Z, et al. High capacity and cycle-stable hard carbon anode for nonflammable sodium-ion batteries. ACS Appl
Mater Interfaces 2018;10:38141-50. DOI
57. Li Y, Hu YS, Titirici MM, Chen L, Huang X. Hard carbon microtubes made from renewable cotton as high-performance anode
material for sodium-ion batteries. Adv Energy Mater 2016;6:1600659. DOI
58. Li Y, Lu Y, Meng Q, et al. Regulating pore structure of hierarchical porous waste cork-derived hard carbon anode for enhanced Na
storage performance. Adv Energy Mater 2019;9:1902852. DOI
59. Zhang Q, Wang Z, Li X, et al. Comparative study of 1,3-propane sultone, prop-1-ene-1,3-sultone and ethylene sulfate as film-forming
additives for sodium ion batteries. J Power Sources 2022;541:231726. DOI
60. Shao Y, Xiao J, Wang W, et al. Surface-driven sodium ion energy storage in nanocellular carbon foams. Nano Lett 2013;13:3909-14.
DOI
61. Feng J, An Y, Ci L, Xiong S. Nonflammable electrolyte for safer non-aqueous sodium batteries. J Mater Chem A 2015;3:14539-44.
DOI
62. Luo W, Bommier C, Jian Z, et al. Low-surface-area hard carbon anode for Na-ion batteries via graphene oxide as a dehydration
agent. ACS Appl Mater Interfaces 2015;7:2626-31. DOI
63. Kim DH, Kang B, Lee H. Comparative study of fluoroethylene carbonate and succinic anhydride as electrolyte additive for hard
carbon anodes of Na-ion batteries. J Power Sources 2019;423:137-43. DOI
64. Bai P, Han X, He Y, et al. Solid electrolyte interphase manipulation towards highly stable hard carbon anodes for sodium ion
batteries. Energy Stor Mater 2020;25:324-33. DOI
65. Che H, Liu J, Wang H, et al. Rubidium and cesium ions as electrolyte additive for improving performance of hard carbon anode in
sodium-ion battery. Electrochem Commun 2017;83:20-3. DOI
66. Wang J, Yamada Y, Sodeyama K, et al. Fire-extinguishing organic electrolytes for safe batteries. Nat Energy 2018;3:22-9. DOI
67. Zhang J, Wang DW, Lv W, et al. Achieving superb sodium storage performance on carbon anodes through an ether-derived solid
electrolyte interphase. Energy Environ Sci 2017;10:370-6. DOI
68. Cometto C, Yan G, Mariyappan S, Tarascon JM. Means of using cyclic voltammetry to rapidly design a stable DMC-based
electrolyte for Na-ion batteries. J Electrochem Soc 2019;166:A3723-30. DOI
69. Yan G, Reeves K, Foix D, et al. A new electrolyte formulation for securing high temperature cycling and storage performances of
Na-ion batteries. Adv Energy Mater 2019;9:1901431. DOI
70. Che H, Yang X, Wang H, et al. Long cycle life of sodium-ion pouch cell achieved by using multiple electrolyte additives. J Power
Sources 2018;407:173-9. DOI
71. Dugas R, Ponrouch A, Gachot G, David R, Palacin MR, Tarascon JM. Na reactivity toward carbonate-based electrolytes: the effect of
FEC as additive. J Electrochem Soc 2016;163:A2333-9. DOI
72. Liu Q, Mu D, Wu B, Wang L, Gai L, Wu F. Density functional theory research into the reduction mechanism for the solvent/additive
in a sodium-ion battery. ChemSusChem 2017;10:786-96. DOI
73. Wang E, Niu Y, Yin YX, Guo YG. Manipulating electrode/electrolyte interphases of sodium-ion batteries: strategies and
perspectives. ACS Materials Lett 2021;3:18-41. DOI
74. Hu S, Zhao H, Qian Y, et al. Improved high-temperature performance of LiNi Co Mn O /artificial graphite lithium ion pouch
0.5 0.2 0.3 2
cells by difluoroethylene carbonate. J Energy Storage 2023;57:106266. DOI
75. Ma L, Glazier SL, Petibon R, et al. A guide to ethylene carbonate-free electrolyte making for Li-ion cells. J Electrochem Soc
2017;164:A5008-18. DOI

167 168 169 170 171 172 173 174 175 176 177