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系統識別號 U0026-2907202015375200
論文名稱(中文) 碳化矽與導電碳包覆之奈米矽片及其於鋰離子電池陽極之應用
論文名稱(英文) Silicon Carbide and Conductive Carbon Coated Silicon Flake for Application to Anode of Lithium Ion Battery
校院名稱 成功大學
系所名稱(中) 微電子工程研究所
系所名稱(英) Institute of Microelectronics
學年度 108
學期 2
出版年 109
研究生(中文) 何佳霖
研究生(英文) Jia-Lin Her
學號 Q16071194
學位類別 碩士
語文別 中文
論文頁數 73頁
口試委員 指導教授-曾永華
口試委員-洪茂峰
口試委員-許渭州
口試委員-盧達生
中文關鍵字 鋰離子電池    間苯二酚-甲醛樹酯  碳化矽  陽極材料 
英文關鍵字 Lithium ion battery  Silicon  Resorcinol–formaldehyde (RF) resins  Silicon Carbide  Anode 
學科別分類
中文摘要 科技的進步帶給人們便利生活的同時,能源的需求與儲存議題也逐漸受到重視,不能否認,能源是帶動科技進步的重要推手,然而隨著地球的資源日漸短缺,能源不足的問題日趨嚴峻,加上近年來環保意識抬頭更注重於綠色能源,發展儲電系統便是構建分散能源並提昇離峰時段用電效率的最佳方法,對於間歇性電力來源而言,電池或許是理想的儲存媒介,因為電池充電速度快,能立即開啟或關閉,而且容易擴充,而其中鋰離子電池為現今最有效儲存能源的方式之一,與其他電池相比,鋰電池具有電容量大、安全性高、工作電壓適中、低環境汙染、高能量密度、可快速充放電且循環壽命長等優點,被認為是目前最有效率的能源儲存方式。

本研究主要專注於鋰離子電池陽極(負極)材料的開發,其中石墨陽極在應用上具有充放電周期長的優勢,且在長時間充放電時不會有枝晶鋰產生,是市面上最常使用的鋰電池陽極,然而其理論電容只有372〖 mAh g〗^(-1),所以尋找替代的材料是重之重。其中矽是下一代鋰離子電池(LIB)最有希望的陽極材料,因為它具有4200〖 mAh g〗^(-1)的高理論電容值,然而在充放電期間的大體積變化造成粉末碎裂和低固有電導率妨礙了其電化學性能。因此本研究主要在矽材料上加以改善,使用熱化學氣相沉積法(Thermal Chemical Vapor Deposition, Thermal CVD)在奈米矽片上成長碳化矽及沉積導電碳當作緩衝層,再加上塗佈間苯二酚-甲醛樹酯當作最外層的保護層,以上述所說的兩道製程包覆之矽所製成的陽極,在全充全放下80次循環後,還有1099〖 mAh g〗^(-1)的電容量,而未處理的奈米矽片陽極只剩下50〖 mAh g〗^(-1)的電容量,證明此包覆方法可以幫助矽基陽極材料延長其壽命。
英文摘要 A thermal chemical vapor deposition (CVD) method is used to grow silicon carbide and deposit conductive carbon as a buffer layer on surfaces of the silicon flake, and coating resorcinol–formaldehyde (RF) resins is used as the outermost protective layer. By taking advantage of the high strength and toughness of silicon carbide (SiC), a SiC layer is introduced between the inner silicon and outer carbon layers to inhibit the formation of Li2SiF6. The Si-carbon composite as an anode exhibited the reversible capacity of 1099〖 mAh g〗^(-1) at 500〖 mA g〗^(-1) after 80 cycles.
論文目次 摘要 I
Abstract II
致謝 VIII
圖目錄 XII
表目錄 XVIII
第一章 緒論 1
第二章 文獻回顧 3
2.1 鋰離子電池工作原理 3
2.2 鋰離子電池陽極材料介紹 4
2.3 矽作為鋰離子電池陽極之優勢與面對的挑戰 5
2.4 改善矽應用在鋰離子電池陽極之方法 – 矽奈米結構 7
2.4.1 零維矽奈米結構 8
2.4.2 一維矽奈米結構 10
2.4.3 二維矽奈米結構 12
2.4.4 三維矽奈米結構 13
2.5 改善矽應用在鋰離子電池陽極之方法 – 矽碳複合材料 15
2.5.1 石墨烯 (graphene) 與矽的複合材料應用於鋰電池陽極 15
2.5.2 奈米碳管 (carbon nanotube,CNT) 與矽的複合材料應用於鋰電池陽極 17
2.5.3 間苯二酚/甲醛(Resorinol / Formaldehyde, RF) 20
2.5.4 碳化矽(silicon carbide, SiC) 21
第三章 實驗方法與步驟 22
3.1 實驗流程 22
3.2 矽包覆間苯二酚/甲醛(Resorcinol / Formaldehyde, RF)之製備 23
3.3 矽包覆碳化矽(Silicon carbide, SiC):碳之製備 24
3.4 粉末特性量測機台介紹 26
3.4.1 拉曼光譜分析儀(Raman Spectrum System) 26
3.4.2 掃描式電子顯微鏡 (Scanning Electron Microscope, SEM) 28
3.4.3 高溫二維X-ray廣角繞射儀(2D X-ray Diffractometer, XRD) 29
3.4.4 傅立葉轉換紅外光光譜儀(Fourier-transform infrared spectroscopy, FTIR) 30
3.4.5 高解析穿透電子顯微鏡(Transmission Electron Microscope, HR-TEM) 31
3.5 鋰離子二次半電池組裝 32
3.5.1 攪漿料及陽極極片製作流程 32
3.5.2 半電池封裝流程 34
3.6 充放電量測系統與分析 36
第四章 實驗結果與討論 38
4.1 矽碳複合材料 38
4.1.1 矽碳複合材料製備及電子顯微鏡分析 38
4.1.2 粉末簡易導電度量測 45
4.1.3 拉曼光譜儀分析 46
4.1.4 傅立葉轉換紅外光光譜儀(FTIR)分析 48
4.1.5 X-ray廣角繞射儀(XRD)分析 52
4.1.6 高解析穿透電子顯微鏡(HR-TEM)分析 56
4.2 半電池之電化學性質分析 57
4.2.1 原始矽粉以及包覆RF碳層與成長碳化矽:碳之電池性能 57
4.2.2 奈米矽片結合RF碳層與成長碳化矽:碳之電池性能 61
第五章 結論與未來展望 67
第六章 參考文獻 69

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