參考文獻 |
1. May, G.J., A. Davidson, and B. Monahov, Lead batteries for utility energy storage: A review. Journal of Energy Storage, 2018. 15: p. 145-157.
2. Kebede, A.A., et al., A comprehensive review of stationary energy storage devices for large scale renewable energy sources grid integration. Renewable and Sustainable Energy Reviews, 2022. 159.
3. Li, S., et al., Fast Charging Anode Materials for Lithium‐Ion Batteries: Current Status and Perspectives. Advanced Functional Materials, 2022. 32(23).
4. Cho, J., S. Jeong, and Y. Kim, Commercial and research battery technologies for electrical energy storage applications. Progress in Energy and Combustion Science, 2015. 48: p. 84-101.
5. Fan, X. and C. Wang, High-voltage liquid electrolytes for Li batteries: progress and perspectives. Chem Soc Rev, 2021. 50(18): p. 10486-10566.
6. Kabir, M.M. and D.E. Demirocak, Degradation mechanisms in Li-ion batteries: a state-of-the-art review. International Journal of Energy Research, 2017. 41(14): p. 1963-1986.
7. Li, W., B. Song, and A. Manthiram, High-voltage positive electrode materials for lithium-ion batteries. Chem Soc Rev, 2017. 46(10): p. 3006-3059.
8. Manthiram, A., A reflection on lithium-ion battery cathode chemistry. Nat Commun, 2020. 11(1): p. 1550.
9. Goodenough, J.B., Metallic oxides. Progress in Solid State Chemistry, 1971. 5: p. 145-399.
10. Ma, Q., et al., Viscoelastic and Nonflammable Interface Design–Enabled Dendrite‐Free and Safe Solid Lithium Metal Batteries. Advanced Energy Materials, 2019. 9(13).
11. Gong, J.Q., Q.S. Wang, and J.H. Sun, Thermal analysis of nickel cobalt lithium manganese with varying nickel content used for lithium ion batteries. Thermochimica Acta, 2017. 655: p. 176-180.
12. Yi, T.-F., S.-Y. Yang, and Y. Xie, Recent advances of Li4Ti5O12 as a promising next generation anode material for high power lithium-ion batteries. Journal of Materials Chemistry A, 2015. 3(11): p. 5750-5777.
13. Gong, Z. and Y. Yang, Recent advances in the research of polyanion-type cathode materials for Li-ion batteries. Energy & Environmental Science, 2011. 4(9).
14. Liang, G., et al., Developing high-voltage spinel LiNi0.5Mn1.5O4 cathodes for high-energy-density lithium-ion batteries: current achievements and future prospects. Journal of Materials Chemistry A, 2020. 8(31): p. 15373-15398.
15. Li, W., E.M. Erickson, and A. Manthiram, High-nickel layered oxide cathodes for lithium-based automotive batteries. Nature Energy, 2020. 5(1): p. 26-34.
16. Zubi, G., et al., The lithium-ion battery: State of the art and future perspectives. Renewable and Sustainable Energy Reviews, 2018. 89: p. 292-308.
17. Yang, K., et al., The simulation on thermal stability of LiNi0.5Mn1.5O4/C electrochemical systems. Journal of Power Sources, 2016. 302: p. 1-6.
18. Jena, K.K., A. AlFantazi, and A.T. Mayyas, Comprehensive Review on Concept and Recycling Evolution of Lithium-Ion Batteries (LIBs). Energy & Fuels, 2021. 35(22): p. 18257-18284.
19. Chen, L., et al., High-Energy Li Metal Battery with Lithiated Host. Joule, 2019. 3(3): p. 732-744.
20. Zhao, L.F., et al., Hard Carbon Anodes: Fundamental Understanding and Commercial Perspectives for Na‐Ion Batteries beyond Li‐Ion and K‐Ion Counterparts. Advanced Energy Materials, 2020. 11(1).
21. Chen, K.H., et al., Enabling 6C Fast Charging of Li‐Ion Batteries with Graphite/Hard Carbon Hybrid Anodes. Advanced Energy Materials, 2020. 11(5).
22. Dedryvère, R., et al., Electrode/Electrolyte Interface Reactivity in High-Voltage Spinel LiMn1.6Ni0.4O4/Li4Ti5O12 Lithium-Ion Battery. The Journal of Physical Chemistry C, 2010. 114(24): p. 10999-11008.
23. Qi, Y., et al., Recent progress of structural designs of silicon for performance-enhanced lithium-ion batteries. Chemical Engineering Journal, 2020. 397.
24. Julien, C., et al., Lithium Batteries, in Lithium Batteries. 2016. p. 29-68.
25. Xu, K., Nonaqueous liquid electrolytes for lithium-based rechargeable batteries. Chem Rev, 2004. 104(10): p. 4303-417.
26. Jung, R., et al., Chemical versus Electrochemical Electrolyte Oxidation on NMC111, NMC622, NMC811, LNMO, and Conductive Carbon. J Phys Chem Lett, 2017. 8(19): p. 4820-4825.
27. Qi, X., et al., Influence of Thermal Treated Carbon Black Conductive Additive on the Performance of High Voltage Spinel Cr-Doped LiNi0.5Mn1.5O4Composite Cathode Electrode. Journal of The Electrochemical Society, 2014. 162(3): p. A339-A343.
28. Kawamura, T., et al., Thermal stability of alkyl carbonate mixed-solvent electrolytes for lithium ion cells. Journal of Power Sources, 2002. 104(2): p. 260-264.
29. Wang, C.-C., et al., Advanced Carbon Cloth as Current Collector for Enhanced Electrochemical Performance of Lithium-Rich Layered Oxide Cathodes. ChemistrySelect, 2017. 2(16): p. 4419-4427.
30. Yamada, M., et al., Review of the Design of Current Collectors for Improving the Battery Performance in Lithium-Ion and Post-Lithium-Ion Batteries. Electrochem, 2020. 1(2): p. 124-159.
31. Zhu, P., et al., A review of current collectors for lithium-ion batteries. Journal of Power Sources, 2021. 485.
32. Zhu, X., T. Schulli, and L. Wang, Stabilizing High-voltage Cathode Materials for Next-generation Li-ion Batteries. Chemical Research in Chinese Universities, 2020. 36(1): p. 24-32.
33. Yoon, T., et al., Failure mechanisms of LiNi0.5Mn1.5O4 electrode at elevated temperature. Journal of Power Sources, 2012. 215: p. 312-316.
34. Pieczonka, N.P.W., et al., Lithium Polyacrylate (LiPAA) as an Advanced Binder and a Passivating Agent for High-Voltage Li-Ion Batteries. Advanced Energy Materials, 2015. 5(23).
35. Wang, Z., et al., CMC as a binder in LiNi0.4Mn1.6O4 5V cathodes and their electrochemical performance for Li-ion batteries. Electrochimica Acta, 2012. 62: p. 77-83.
36. Zhang, S.S., A review on the separators of liquid electrolyte Li-ion batteries. Journal of Power Sources, 2007. 164(1): p. 351-364.
37. Zou, Z., et al., Electrolyte Therapy for Improving the Performance of LiNi0.5Mn1.5O4 Cathodes Assembled Lithium-Ion Batteries. ACS Appl Mater Interfaces, 2020. 12(19): p. 21368-21385.
38. Wang, H., LiNi0.5Mn1.5O4 Cathodes for Lithium Ion Batteries: A Review. J Nanosci Nanotechnol, 2015. 15(9): p. 6883-90.
39. Campion, C.L., W. Li, and B.L. Lucht, Thermal Decomposition of LiPF[sub 6]-Based Electrolytes for Lithium-Ion Batteries. Journal of The Electrochemical Society, 2005. 152(12).
40. Yi, T.-F., J. Mei, and Y.-R. Zhu, Key strategies for enhancing the cycling stability and rate capacity of LiNi0.5Mn1.5O4 as high-voltage cathode materials for high power lithium-ion batteries. Journal of Power Sources, 2016. 316: p. 85-105.
41. Pieczonka, N.P.W., et al., Understanding Transition-Metal Dissolution Behavior in LiNi0.5Mn1.5O4High-Voltage Spinel for Lithium Ion Batteries. The Journal of Physical Chemistry C, 2013. 117(31): p. 15947-15957.
42. Hwang, T., et al., Surface-modified carbon nanotube coating on high-voltage LiNi0.5Mn1.5O4 cathodes for lithium ion batteries. Journal of Power Sources, 2016. 322: p. 40-48.
43. Gao, X.-W., et al., Improving the electrochemical performance of the LiNi0.5Mn1.5O4spinel by polypyrrole coating as a cathode material for the lithium-ion battery. Journal of Materials Chemistry A, 2015. 3(1): p. 404-411.
44. Liu, M., et al., Hydrolysis of LiPF6-Containing Electrolyte at High Voltage. ACS Energy Letters, 2021. 6(6): p. 2096-2102.
45. Xu, K., Electrolytes and interphases in Li-ion batteries and beyond. Chem Rev, 2014. 114(23): p. 11503-618.
46. Schultz, C., et al., Quantitative investigation of the decomposition of organic lithium ion battery electrolytes with LC-MS/MS. RSC Advances, 2017. 7(45): p. 27853-27862.
47. Lee, K., et al., Composite coating of Li2O–2B2O3 and carbon as multi-conductive electron/Li-ion channel on the surface of LiNi0.5Mn1.5O4 cathode. Journal of Power Sources, 2017. 365: p. 249-256.
48. Myung, S.-T., et al., Electrochemical behavior of current collectors for lithium batteries in non-aqueous alkyl carbonate solution and surface analysis by ToF-SIMS. Electrochimica Acta, 2009. 55(1): p. 288-297.
49. Kanamura, K., et al. , Electrochemical oxidation of propylene carbonate (containing various salts) on aluminium electrodes. Journal of power sources, 1995. 57.1-2: p. 119-123.
50. Streipert, B., et al., Influence of LiPF6on the Aluminum Current Collector Dissolution in High Voltage Lithium Ion Batteries after Long-Term Charge/Discharge Experiments. Journal of The Electrochemical Society, 2017. 164(7): p. A1474-A1479.
51. Guo, J., A. Sun, and C. Wang, A porous silicon–carbon anode with high overall capacity on carbon fiber current collector. Electrochemistry Communications, 2010. 12(7): p. 981-984.
52. Chen, P.-C., et al., Hybrid silicon-carbon nanostructured composites as superior anodes for lithium ion batteries. Nano Research, 2010. 4(3): p. 290-296.
53. Li, Z.H., et al., A new battery process technology inspired by partially carbonized polymer binders. Nano Energy, 2020. 67.
54. Chen, L., et al., PVP-Assisted Synthesis of Uniform Carbon Coated Li2S/CB for High-Performance Lithium-Sulfur Batteries. ACS Appl Mater Interfaces, 2015. 7(46): p. 25748-56.
55. Ding, X., et al., An Ultra-Long-Life Lithium-Rich Li1.2 Mn0.6 Ni0.2 O2 Cathode by Three-in-One Surface Modification for Lithium-Ion Batteries. Angew Chem Int Ed Engl, 2020. 59(20): p. 7778-7782.
56. Bosch-Navarro, C., et al., Influence of the pH on the synthesis of reduced graphene oxide under hydrothermal conditions. Nanoscale, 2012. 4(13): p. 3977-82.
57. Miao, Q., et al., Effect of defects controlled by preparation condition and heat treatment on the ferromagnetic properties of few-layer graphene. Sci Rep, 2017. 7(1): p. 5877.
58. Jo, N.-B., J.-S. Baek, and E.-S. Kim, The Effect of PVA Binder Solvent Composition on the Microstructure and Electrical Properties of 0.98BaTiO3-0.02(Ba0.5Ca0.5)SiO3 Doped with Dy2O3. Processes, 2021. 9(11).
59. Bockholt, H., W. Haselrieder, and A. Kwade, Intensive powder mixing for dry dispersing of carbon black and its relevance for lithium-ion battery cathodes. Powder Technology, 2016. 297: p. 266-274.
60. Cinquino, M., et al., Effect of surface tension and drying time on inkjet-printed PEDOT:PSS for ITO-free OLED devices. Journal of Science: Advanced Materials and Devices, 2022. 7(1).
61. Xu, J., W. Wang, and A. Wang, Dispersion of palygorskite in ethanol–water mixtures via high-pressure homogenization: Microstructure and colloidal properties. Powder Technology, 2014. 261: p. 98-104.
62. Sung, S.H., et al., Role of PVDF in Rheology and Microstructure of NCM Cathode Slurries for Lithium-Ion Battery. Materials (Basel), 2020. 13(20).
63. Park, K.-J., et al., Improved Cycling Stability of Li[Ni0.90Co0.05Mn0.05]O2 Through Microstructure Modification by Boron Doping for Li-Ion Batteries. Advanced Energy Materials, 2018. 8(25).
64. Zheng, J., et al., Surface and structural stabilities of carbon additives in high voltage lithium ion batteries. Journal of Power Sources, 2013. 227: p. 211-217.
65. Chung, D.-W., et al., Particle Size Polydispersity in Li-Ion Batteries. Journal of The Electrochemical Society, 2014. 161(3): p. A422-A430.
66. Hasanpoor, M., et al., Morphological Evolution and Solid-Electrolyte Interphase Formation on LiNi0.6Mn0.2Co0.2O2 Cathodes Using Highly Concentrated Ionic Liquid Electrolytes. ACS Appl Mater Interfaces, 2022. 14(11): p. 13196-13205.
67. J. Z. Li Wang, X.H., Jian Gao, Jianjun Li, Chunrong Wan, Changyin Jiang, Electrochemical Impedance Spectroscopy (EIS) Study of LiNi1/3Co1/3Mn1/3O2 for Li-ion Batteries. Int. J. Electrochem. Sci., 2012: p. 345-353.
68. Salleh, W.N.W. and A.F. Ismail, Effects of carbonization heating rate on CO2 separation of derived carbon membranes. Separation and Purification Technology, 2012. 88: p. 174-183.
69. Wu, J., et al., Mechanistic insights into formation of SnO(2) nanotubes: asynchronous decomposition of poly(vinylpyrrolidone) in electrospun fibers during calcining process. Langmuir, 2014. 30(37): p. 11183-9.
70. Pindar, S. and N. Dhawan, Evaluation of carbothermic processing for mixed discarded lithium-ion batteries. Metallurgical Research & Technology, 2020. 117(3).
71. El-Batal, A.I., et al., Antibiofilm and Antimicrobial Activities of Silver Boron Nanoparticles Synthesized by PVP Polymer and Gamma Rays Against Urinary Tract Pathogens. Journal of Cluster Science, 2019. 30(4): p. 947-964.
72. Rahma, A., et al., Intermolecular Interactions and the Release Pattern of Electrospun Curcumin-Polyvinyl(pyrrolidone) Fiber. Biological and Pharmaceutical Bulletin, 2016. 39(2): p. 163-173.
73. Marshall, S.J., et al., A review of adhesion science. Dent Mater, 2010. 26(2): p. e11-6.
74. Choi, Y.C., et al., Poly(azomethine ether)‐derived carbon nanofibers for self‐standing and binder‐free supercapacitor electrode material applications. Polymers for Advanced Technologies, 2020. 31(11): p. 2874-2883.
75. Zhao, J., et al., Nitrogen-doped carbon with a high degree of graphitization derived from biomass as high-performance electrocatalyst for oxygen reduction reaction. Applied Surface Science, 2017. 396: p. 986-993.
76. Liu, Y.-H., et al., Elucidating the function of modified carbon blacks in high-voltage lithium-ion batteries: impact on electrolyte decomposition. Materials Today Chemistry, 2022. 25. |