側鍊烷基化之PEO聚輪烷：
合成與其在鋰離子固態電解質之應用

Ssu-Ting Liao; 廖思婷

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/77207

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	趙基揚(Chi-Yang Chao)
dc.contributor.author	Ssu-Ting Liao	en
dc.contributor.author	廖思婷	zh_TW
dc.date.accessioned	2021-07-10T21:50:54Z	-
dc.date.available	2021-07-10T21:50:54Z	-
dc.date.copyright	2021-03-04
dc.date.issued	2020
dc.date.submitted	2021-02-18
dc.identifier.citation	1. Tarascon, J.-M.; Armand, M. (2001). Issues and challenges facing rechargeable lithium batteries. Nature, 414(6861), 359–367. 2. Ngai, K. S.; Ramesh, S.; Ramesh, K.; Juan, J. C. (2016). A review of polymer electrolytes: Fundamental, approaches and applications. Ionics, 22(8), 1259-1279. 3. Fenton, D.; Parker, J.; Wright, P. (1973). Complexes of alkali metal ions with poly(ethylene oxide). Polymer, 14(11), 589. 4. Wright, P. V. (1975). Electrical conductivity in Ionic complexes of poly(ethylene oxide). British Polymer Journal, 7(5), 319-327. 5. Armand, M. B.; Chabagao, J. M.; Duclot, M. (1978). ‘Second Intern Meeting on Solid Electrolytes’, St. Andrews, Scotland, pp. 2022. 6. M. Armand; J.M. Chabagno; M. Duclot; P. Vashishta; J.N. Mundy; G.K. Shenoy (1979) (Eds.), Fast Ion Transport in Solids, North Holland, Amsterdam, p. 131 7. Quartarone, E. (1998). PEO-based composite polymer electrolytes. Solid State Ionics, 110(1-2), 1-14. 8. Ramesh, S.; Liew, C.; Morris, E.; Durairaj, R. (2010). Effect of PVC on Ionic conductivity, crystallographic structural, morphological and thermal characterizations in PMMA–PVC blend-based polymer electrolytes. Thermochimica Acta, 511(1-2), 140-146. 9. Feuillade, G.; Perche, P. (1975). Ion-conductive macromolecular gels and membranes for solid lithium cells. Journal of Applied Electrochemistry, 5(1), 63-69. 10. Manuel Stephan, A. (2006). Review on gel polymer electrolytes for lithium batteries. European Polymer Journal, 42(1), 21-42. 11. Liew, C.; Durairaj, R.; Ramesh, S. (2014). Rheological studies of PMMA–PVC based polymer blend electrolytes with LiTFSI as doping salt. PLoS ONE, 9(7), e102815. 12. Liew, C.; Ramesh, S.; Durairaj, R. (2012). Impact of low viscosity Ionic liquid on PMMA–PVC–LiTFSI polymer electrolytes based on AC -impedance, dielectric behavior, and HATR–FTIR characteristics. Journal of Materials Research, 27(23), 2996-3004. 13. Itoh, T. (2003). Composite polymer electrolytes based on poly(ethylene oxide), hyperbranched polymer, BaTiO3 and LiN(CF3SO2)2. Solid State Ionics, 156(3-4), 393-399. 14. Hu, J.; Luo, J.; Wagner, P.; Conrad, O.; Agert, C. (2009). Anhydrous proton conducting membranes based on electron-deficient nanoparticles/PBI-OO/PFSA composites for high-temperature PEMFC. Electrochemistry Communications, 11(12), 2324-2327. 15. Wen, Z. (2003). Thermal, electrical, and mechanical properties of composite polymer electrolytes based on cross-linked poly(ethylene oxide-Co-propylene oxide) and ceramic filler. Solid State Ionics, 160(1-2), 141-148. 16. Hao, J.; Li, X.; Yu, S.; Jiang, Y.; Luo, J.; Shao, Z.; Yi, B. (2015). Development of proton-conducting membrane based on incorporating a proton conductor 1,2,4-triazolium methanesulfonate into the Nafion membrane. Journal of Energy Chemistry, 24(2), 199-206. 17. Katsaros, G.; Stergiopoulos, T.; Arabatzis, I.; Papadokostaki, K.; Falaras, P. (2002). A solvent-free composite polymer/inorganic oxide electrolyte for high efficiency solid-state dye-sensitized solar cells. Journal of Photochemistry and Photobiology A: Chemistry, 149(1-3), 191-198. 18. Agrawal, R. C.; Pandey, G. P. (2008). Solid polymer electrolytes: Materials designing and all-solid-state battery applications: an overview. Journal of Physics D: Applied Physics, 41(22), 223001. 19. Gray, F. M. (1991). Solid polymer electrolytes: Fundamentals and technological applications. Wiley-VCH 20. Pearson, R. G.(1963). Hard and Soft Acids and Bases. Journal of the American Chemical Society 85 (22), 3533-3539 21. Armand, M.; Gorecki, W.; Andreani, R. (1990). in “2nd International Symposium on Polymer Electrolytes”, Ed. By Scrosati, B., Elsevier Applied Science 22. Xue, Z.; He, D.; Xie, X. (2015). Poly(ethylene oxide)-based electrolytes for lithium-ion batteries. Journal of Materials Chemistry A, 3(38), 19218-19253. 23. Harada, A.; Li, J.; Kamachi, M. (1994). Preparation and characterization of a Polyrotaxane consisting of Monodisperse Poly(ethylene glycol) and .alpha.-cyclodextrins. Journal of the American Chemical Society, 116(8), 3192-3196. 24. Lin, Y.; Ito, K.; Yokoyama, H. (2018). Solid polymer electrolyte based on crosslinked polyrotaxane. Polymer, 136, 121-127. 25. Okumura, Y.; Ito, K. (2001). The Polyrotaxane gel: A topological gel by figure-of-Eight cross-links. Advanced Materials, 13(7), 485-487. 26. Imholt, L.; Dong, D.; Bedrov, D.; Cekic-Laskovic, I.; Winter, M.; Brunklaus, G. (2018). Supramolecular self-assembly of methylated Rotaxanes for solid polymer electrolyte application. ACS Macro Letters, 7(7), 881-885. 27. Imholt, L.; Dörr, T. S.; Zhang, P.; Ibing, L.; Cekic-Laskovic, I.; Winter, M.; Brunklaus, G. (2019). Grafted polyrotaxanes as highly conductive electrolytes for lithium metal batteries. Journal of Power Sources, 409, 148-158. 28. Moriyasu, T.; Sakamoto, T.; Sugihara, N.; Sasa, Y.; Ota, Y.; Shimomura, T.; Sakai, Y.; Ito, K. (2013). Ionic conduction of slide-ring gel swollen with Ionic liquids. Polymer, 54(5), 1490-1496. 29. Sugihara, N.; Tominaga, Y.; Shimomura, T.; Ito, K. (2015). Ionic conductivity and mechanical properties of slide-ring gel swollen with electrolyte solution including lithium ions. Electrochimica Acta, 169, 433-439. 30. Choi, W.; Shin, H.; Kim, J.; Choi. J.; Yoon, W. (2020). Modeling and Applications of Electrochemical Impedance Spectroscopy (EIS) for Lithium-ion Batteries. Journal of Electrochemical Science and Technology, 11(1), 1–13. 31. Angelova, S.; Nikolova, V.; Pereva, S.; Spassov, T.; Dudev, T. (2017). α-cyclodextrin: How effectively can its hydrophobic cavity be hydrated? The Journal of Physical Chemistry B, 121(39), 9260-9267.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/77207	-
dc.description.abstract	本實驗的主要目的是以官能基化的聚輪烷（polyrotaxane, PR）為基材製備固態電解質獨立膜。PR為一主鏈為poly(ethylene oxide) （PEO），並將CD環（α -cyclodextrin）以PEO主鏈串起之特殊高分子，具有特殊的滑環特性而展現出高度的延展性及良好的分子運動性，當應用固態電解質時可以克服PEO在室溫下的結晶性而提升離子傳導度。由於其可透過CD環間的氫鍵作用力進行物理交聯，因此可以在不犧牲機械強度的情形下製備成實現PEO良好的鏈段遷移特性。然而影響其離子傳導性質與機械性質的因素有很多：包括PEO的分子量，CD與EO之間的比例，添加的鋰鹽種類與添加量，以及CD環上所修飾的官能基種類及數目等。為了優化固態電解質的電性，以上影響因素需要仔細的平衡。在此研究中，我們以PR為基材，將四種不同的烷基對CD環進行修飾，並改變修飾的密度，以調控分子間的作用力，並改變鋰鹽的混摻量，嘗試最佳化固態高分子電解質的成膜性、機械性質與離子傳導度。由NMR光譜結果印證，由於線型烷基有較小的立體障礙，其修飾率皆高於分支型烷基。通過溶劑揮發法，可製成約50至100微米厚的獨立膜，並用於其鋰離子傳導度的量測及研究鋰離子的遷移行為。結果顯示，分支型烷基側鏈修飾之PR可以有效改善固態電解質薄膜的柔韌性，並由較低的活化能得到較高的離子傳導度特性。	zh_TW
dc.description.abstract	In this work, we perform alkylation of polyrotaxane (PR) and develop the corresponding solid polymer electrolytes (SPEs) for lithium batteries. Polyrotaxane (PR) is composed of a linear PEO chain threading through multiple cyclic α-cyclodextrin (CD) molecules, which is expected to improve the conductivity at room temperature while retain mechanical strengths due to the unique “mobile crosslinking” of PR, allowing good chain mobility of PEO without sacrificing mechanical strength since CDs contain abundant hydroxyl groups to form strong inter- and intramolecular hydrogen bonds to serve as physical crosslinks. To optimize the performance of SPE, carefully balance the chain mobility and the strengths of hydrogen-bondings is critical to obtain good conductivity and good mechanical strength simultaneously. Hereby, modification of CDs with different alkyl groups in various degree of functionalization is systematically performed, and the resulting alkylated PRs (A-PR) are blended with various concentrations of LiClO4 to fabricate the SPE membranes with thickness of 50-100 μm via solvent casting method. It is found that the degree of CD functionalization of linear alkyl chain is higher than that of branched alkyl group due to less steric hindrance. PR containing alkylated CD with branched ethyl hexyl group and low degree of functionalization of hexyl group would effectively improve the flexibility of the SPE and enhance the ionic conductivity with lowered activation energy for lithium ion transportation.	en
dc.description.provenance	Made available in DSpace on 2021-07-10T21:50:54Z (GMT). No. of bitstreams: 1 U0001-0902202107231000.pdf: 11640887 bytes, checksum: de99ee86bc33ade19d9a608c899cb0c8 (MD5) Previous issue date: 2020	en
dc.description.tableofcontents	中文摘要 I ABSTRACT II 目錄 III 圖目錄 V 表目錄 VI 第一章緒論 1 1.1 研究背景 1 1.2 研究動機與架構 2 第二章文獻回顧 5 2.1 高分子電解質 5 2.2 高分子電解質的種類 5 2.3 高分子電解質中的鹽溶作用(SALT SOLVATION) 6 2.4 高分子電解質中的離子傳導機制 7 2.5 聚輪烷(POLYROTAXANE)於固態高分子電解質的應用 9 第三章實驗步驟與原理 15 3.1 實驗藥品 15 3.2 實驗儀器 16 3.3 材料製備 17 3.3.1 CD 環(α-Cyclodextrin)之烷基化側鏈修飾 17 3.3.2 A-PR 固態電解質薄膜製備 19 3.4 材料分析 19 3.4.1 合成鑑定 19 3.4.2 熱分析 20 3.4.3 薄膜機械強度分析 20 3.4.4 薄膜表面接觸角分析 21 3.4.5 交流阻抗分析 21 3.4.6 變溫離子傳導度量測 22 第四章實驗結果與討論 23 4.1 CD 環之烷基化側鏈修飾與鑑定 23 4.2 A-PR 之熱穩定性分析 31 4.3 SPE 薄膜的機械性質 33 4.4 A-PR 薄膜的表面性質 36 4.5 SPE 薄膜的鋰離子傳導度 37 第五章結論 41 第六章未來展望 42 參考文獻 43
dc.language.iso	zh-TW
dc.subject	滑環材料	zh_TW
dc.subject	固態高分子電解質	zh_TW
dc.subject	聚乙二醇	zh_TW
dc.subject	Slide-ring Material	en
dc.subject	PEO	en
dc.subject	Solid Polymer Electrolyte	en
dc.title	側鍊烷基化之PEO聚輪烷：合成與其在鋰離子固態電解質之應用	zh_TW
dc.title	Alkylated PEO-based Polyrotaxane: Syntheses and Applications in Lithium-ion Conducting Solid Polymer Electrolyte	en
dc.type	Thesis
dc.date.schoolyear	109-1
dc.description.degree	碩士
dc.contributor.oralexamcommittee	吳乃立(Nae-Lih Wu),戴子安(Chi-An Dai),胡芝瑋(Chih-Wei Hu)
dc.subject.keyword	固態高分子電解質,聚乙二醇,滑環材料,	zh_TW
dc.subject.keyword	Solid Polymer Electrolyte,PEO,Slide-ring Material,	en
dc.relation.page	46
dc.identifier.doi	10.6342/NTU202100687
dc.rights.note	未授權
dc.date.accepted	2021-02-18
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	材料科學與工程學研究所	zh_TW
顯示於系所單位：	材料科學與工程學系

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