參考文獻 |
1. Harry, K.J., et al., Detection of subsurface structures underneath dendrites formed on cycled lithium metal electrodes. Nature materials, 2014. 13(1): p. 69.
2. Homewood, P., Fossil Fuels and Emissions Forecast To Continue To Rise – BP Energy Outlook. https://notalotofpeopleknowthat.wordpress.com/2018/02/22/fossil-fuels-and-emissions-forecast-to-continue-to-rise-bp-energy-outlook/, 2018.2.22.
3. Yang, M. and J. Hou, Membranes in lithium ion batteries. Membranes, 2012. 2(3): p. 367-383.
4. Hausbrand, R., et al., Fundamental degradation mechanisms of layered oxide Li-ion battery cathode materials: Methodology, insights and novel approaches. Materials Science and Engineering: B, 2015. 192: p. 3-25.
5. Wang, Q., et al., Thermal runaway caused fire and explosion of lithium ion battery. Journal of power sources, 2012. 208: p. 210-224.
6. Odziemkowski, M. and D. Irish, An Electrochemical Study of the Reactivity at the Lithium Electrolyte/Bare Lithium Metal Interface I. Purified Electrolytes. Journal of The Electrochemical Society, 1992. 139(11): p. 3063-3074.
7. Tarascon, J.-M., et al., Performance of Bellcore′s plastic rechargeable Li-ion batteries. Solid State Ionics, 1996. 86: p. 49-54.
8. Galiński, M., A. Lewandowski, and I. Stępniak, Ionic liquids as electrolytes. Electrochimica acta, 2006. 51(26): p. 5567-5580.
9. Rajendran, S., O. Mahendran, and T. Mahalingam, Thermal and ionic conductivity studies of plasticized PMMA/PVdF blend polymer electrolytes. European polymer journal, 2002. 38(1): p. 49-55.
10. Long, L., et al., Polymer electrolytes for lithium polymer batteries. Journal of Materials Chemistry A, 2016. 4(26): p. 10038-10069.
11. Song, J., Y. Wang, and C.C. Wan, Review of gel-type polymer electrolytes for lithium-ion batteries. Journal of Power Sources, 1999. 77(2): p. 183-197.
12. Dias, F.B., L. Plomp, and J.B. Veldhuis, Trends in polymer electrolytes for secondary lithium batteries. Journal of Power Sources, 2000. 88(2): p. 169-191.
13. Gadjourova, Z., et al., Ionic conductivity in crystalline polymer electrolytes. Nature, 2001. 412(6846): p. 520.
14. Stephan, A.M., et al., Poly (vinylidene fluoride-hexafluoropropylene)(PVdF-HFP) based composite electrolytes for lithium batteries. European Polymer Journal, 2006. 42(8): p. 1728-1734.
15. Rani, M.U., R. Babu, and S. Rajendran, Conductivity study on PVDF-HFP/PMMA electrolytes for lithium battery applications. International Journal of ChemTech Research, 2013. 5(4): p. 1724-1732.
16. FENTON, D., Complexes of Alkali Metal Ions with Poly (etylene oxide). Polymer, 1973. 14: p. 589.
17. Xu, X., et al., High lithium ion conductivity glass-ceramics in Li2O–Al2O3–TiO2–P2O5 from nanoscaled glassy powders by mechanical milling. Solid State Ionics, 2006. 177(26-32): p. 2611-2615.
18. Yao, X., et al., All-solid-state lithium batteries with inorganic solid electrolytes: Review of fundamental science. Chinese Physics B, 2015. 25(1): p. 018802.
19. Fergus, J.W., Ceramic and polymeric solid electrolytes for lithium-ion batteries. Journal of Power Sources, 2010. 195(15): p. 4554-4569.
20. Fu, X., et al., Inorganic and organic hybrid solid electrolytes for lithium-ion batteries. CrystEngComm, 2016. 18(23): p. 4236-4258.
21. Knauth, P., Inorganic solid Li ion conductors: An overview. Solid State Ionics, 2009. 180(14-16): p. 911-916.
22. Meyer, W.H., Polymer electrolytes for lithium‐ion batteries. Advanced materials, 1998. 10(6): p. 439-448.
23. Bachman, J.C., et al., Inorganic solid-state electrolytes for lithium batteries: mechanisms and properties governing ion conduction. Chemical reviews, 2015. 116(1): p. 140-162.
24. Ramesh, S., A. Yahaya, and A. Arof, Miscibility studies of PVC blends (PVC/PMMA and PVC/PEO) based polymer electrolytes. Solid State Ionics, 2002. 148(3-4): p. 483-486.
25. Subramania, A., N.K. Sundaram, and G.V. Kumar, Structural and electrochemical properties of micro-porous polymer blend electrolytes based on PVdF-co-HFP-PAN for Li-ion battery applications. Journal of power sources, 2006. 153(1): p. 177-182.
26. Ding, Y., et al., The ionic conductivity and mechanical property of electrospun P (VdF-HFP)/PMMA membranes for lithium ion batteries. Journal of membrane science, 2009. 329(1-2): p. 56-59.
27. Nunes-Pereira, J., C. Costa, and S. Lanceros-Méndez, Polymer composites and blends for battery separators: state of the art, challenges and future trends. Journal of Power Sources, 2015. 281: p. 378-398.
28. Xie, H., et al., PVDF-HFP composite polymer electrolyte with excellent electrochemical properties for Li-ion batteries. Journal of Solid State Electrochemistry, 2008. 12(11): p. 1497-1502.
29. Tiwari, V. and G. Srivastava, Effect of thermal processing conditions on the structure and dielectric properties of PVDF films. Journal of Polymer Research, 2014. 21(11): p. 587.
30. Martins, P., A. Lopes, and S. Lanceros-Mendez, Electroactive phases of poly (vinylidene fluoride): determination, processing and applications. Progress in polymer science, 2014. 39(4): p. 683-706.
31. Rajendran, S., O. Mahendran, and R. Kannan, Lithium ion conduction in plasticized PMMA–PVdF polymer blend electrolytes. Materials chemistry and physics, 2002. 74(1): p. 52-57.
32. Brown, H., et al., Effects of a diblock copolymer on adhesion between immiscible polymers. 1. Polystyrene (PS)-PMMA copolymer between PS and PMMA. Macromolecules, 1993. 26(16): p. 4155-4163.
33. Lin, D.-J., C.-L. Lin, and S.-Y. Guo, Network Nano-Porous Poly (vinylidene fluoride-co-hexafluoropropene) Membranes by Nano-Gelation Assisted phase Separation of Poly (vinylidene fluoride-co-hexafluoropropene)/Poly (methyl methacrylate) Blend Precursor in Toluene. Macromolecules, 2012. 45(21): p. 8824-8832.
34. Seki, S., et al., Highly reversible lithium metal secondary battery using a room temperature ionic liquid/lithium salt mixture and a surface-coated cathode active material. Chemical Communications, 2006(5): p. 544-545.
35. Balducci, A., et al., High temperature carbon–carbon supercapacitor using ionic liquid as electrolyte. Journal of Power Sources, 2007. 165(2): p. 922-927.
36. De Souza, R.F., et al., Room temperature dialkylimidazolium ionic liquid-based fuel cells. Electrochemistry Communications, 2003. 5(8): p. 728-731.
37. Wang, P., et al., Gelation of ionic liquid-based electrolytes with silica nanoparticles for quasi-solid-state dye-sensitized solar cells. Journal of the American Chemical Society, 2003. 125(5): p. 1166-1167.
38. Li, C., et al., Comparison of dilute acid and ionic liquid pretreatment of switchgrass: biomass recalcitrance, delignification and enzymatic saccharification. Bioresource technology, 2010. 101(13): p. 4900-4906.
39. Yang, P., et al., Characterization and properties of ternary P (VdF-HFP)-LiTFSI-EMITFSI ionic liquid polymer electrolytes. Solid State Sciences, 2012. 14(5): p. 598-606.
40. MacFarlane, D.R., et al., Energy applications of ionic liquids. Energy & Environmental Science, 2014. 7(1): p. 232-250.
41. Huddleston, J.G., et al., Characterization and comparison of hydrophilic and hydrophobic room temperature ionic liquids incorporating the imidazolium cation. Green chemistry, 2001. 3(4): p. 156-164.
42. Chaurasia, S., R. Singh, and S. Chandra, Thermal stability, complexing behavior, and ionic transport of polymeric gel membranes based on polymer PVdF-HFP and ionic liquid,[BMIM][BF4]. The Journal of Physical Chemistry B, 2013. 117(3): p. 897-906.
43. Ye, Y.-S., J. Rick, and B.-J. Hwang, Ionic liquid polymer electrolytes. Journal of Materials Chemistry A, 2013. 1(8): p. 2719-2743.
44. Wu, C., et al., Synthesis of hematite (α-Fe2O3) nanorods: diameter-size and shape effects on their applications in magnetism, lithium ion battery, and gas sensors. The Journal of Physical Chemistry B, 2006. 110(36): p. 17806-17812.
45. Ray, P.C., Size and shape dependent second order nonlinear optical properties of nanomaterials and their application in biological and chemical sensing. Chemical reviews, 2010. 110(9): p. 5332-5365.
46. Zhou, Z.-Y., et al., Nanomaterials of high surface energy with exceptional properties in catalysis and energy storage. Chemical Society Reviews, 2011. 40(7): p. 4167-4185.
47. Walkey, C.D., et al., Nanoparticle size and surface chemistry determine serum protein adsorption and macrophage uptake. Journal of the American Chemical Society, 2012. 134(4): p. 2139-2147.
48. Weston, J. and B. Steele, Effects of inert fillers on the mechanical and electrochemical properties of lithium salt-poly (ethylene oxide) polymer electrolytes. Solid State Ionics, 1982. 7(1): p. 75-79.
49. Ohta, N., et al., Enhancement of the High‐Rate Capability of Solid‐State Lithium Batteries by Nanoscale Interfacial Modification. Advanced Materials, 2006. 18(17): p. 2226-2229.
50. Chiang, C.-Y., M.J. Reddy, and P.P. Chu, Nano-tube TiO2 composite PVdF/LiPF6 solid membranes. Solid State Ionics, 2004. 175(1-4): p. 631-635.
51. Cao, J., et al., In situ prepared nano-crystalline TiO 2–poly (methyl methacrylate) hybrid enhanced composite polymer electrolyte for Li-ion batteries. Journal of Materials Chemistry A, 2013. 1(19): p. 5955-5961.
52. Palmero, P., Structural ceramic nanocomposites: a review of properties and powders’ synthesis methods. Nanomaterials, 2015. 5(2): p. 656-696.
53. Srivastava, S., et al., 25th anniversary article: polymer–particle composites: phase stability and applications in electrochemical energy storage. Advanced Materials, 2014. 26(2): p. 201-234.
54. Capiglia, C., et al., Effects of nanoscale SiO2 on the thermal and transport properties of solvent-free, poly (ethylene oxide)(PEO)-based polymer electrolytes. Solid State Ionics, 1999. 118(1-2): p. 73-79.
55. Forsyth, M., et al., The effect of nano-particle TiO2 fillers on structure and transport in polymer electrolytes. Solid State Ionics, 2002. 147(3-4): p. 203-211.
56. Pitawala, H., M. Dissanayake, and V. Seneviratne, Combined effect of Al2O3 nano-fillers and EC plasticizer on ionic conductivity enhancement in the solid polymer electrolyte (PEO) 9LiTf. Solid State Ionics, 2007. 178(13-14): p. 885-888.
57. Croce, F., L. Settimi, and B. Scrosati, Superacid ZrO2-added, composite polymer electrolytes with improved transport properties. Electrochemistry communications, 2006. 8(2): p. 364-368.
58. Cong, H., et al., Carbon nanotube composite membranes of brominated poly (2, 6-diphenyl-1, 4-phenylene oxide) for gas separation. Journal of Membrane Science, 2007. 294(1-2): p. 178-185.
59. Sun, J., et al., Cytotoxicity, permeability, and inflammation of metal oxide nanoparticles in human cardiac microvascular endothelial cells. Cell biology and toxicology, 2011. 27(5): p. 333-342.
60. Badwal, S., Zirconia-based solid electrolytes: microstructure, stability and ionic conductivity. Solid State Ionics, 1992. 52(1-3): p. 23-32.
61. Wegener, M., et al., Ferroelectric polarization in stretched piezo-and pyroelectric poly (vinylidene fluoride-hexafluoropropylene) copolymer films. Journal of applied physics, 2002. 92(12): p. 7442-7447.
62. Choi, J.-H., et al., Network structure and strong microphase separation for high ion conductivity in polymerized ionic liquid block copolymers. Macromolecules, 2013. 46(13): p. 5290-5300.
63. Liu, W., et al., Enhancing ionic conductivity in composite polymer electrolytes with well-aligned ceramic nanowires. Nature energy, 2017. 2(5): p. 17035.
64. Wegener, M., Electrical Poling of Polymers. https://www.uni-potsdam.de/u/physik/fprakti/ANLEIF10.pdf, 2002. |