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研究生: 吳昱辰
Wu, Yu-Chen
論文名稱: 開發應用於高分子自組裝反應原位穿透式電子顯微鏡流體及加熱載台
Development of Fluid/Heating Holder for In-situ Fluid TEM Observation of Polymer Self-assembly
指導教授: 陳福榮
Chen, Fu-Rong
口試委員: 曾繁根
Tseng, Fan-Gang
吳文偉
Wu, Wen-Wei
學位類別: 碩士
Master
系所名稱: 原子科學院 - 工程與系統科學系
Department of Engineering and System Science
論文出版年: 2018
畢業學年度: 106
語文別: 中文
論文頁數: 113
中文關鍵詞: 電子顯微鏡流體臨場觀測加熱臨場觀測半導體製程
外文關鍵詞: MEMS process
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    • 電子顯微鏡中臨場觀測技術近年來逐漸被廣泛討論,此技術開創了以往電子顯微鏡中觀測樣片之諸多限制,並開創了新穎與獨特的領域,本研究針對穿透式電子顯微鏡中臨場觀測之需求,開發穿透式電子顯微鏡之流體系統載具,利用微機電製程配合機構零件設計以及真空迫緊技術,製造出可與外界流通且仍然維持腔體內部高真空之流體載具,此新式設計使用200nm厚之鉻spacer定義出流體之微流道,改善了先前舊有流體載具中液體在觀測視窗中間之流速問題,使得在穿透式電子顯微鏡臨場觀測下可規範液體的流動方向,並觀測嵌段共聚高分子於甲苯溶劑特定流速潤濕下發生自組裝反應,由原本無序雜亂之結構逐漸開始排列,選用兩成分原子序差異較大之嵌段共聚高分子,在穿透式電子顯微鏡下明顯具有不同序號強度,以判斷開始發生自組裝反應而驗證此流體系統之可行性。此外利用微機電製程設計出加熱晶片,相較於傳統熱爐式加熱樣品桿,更能表現出微區加熱之快速升降溫高性能,且利用四點探針即時回饋得到精準的控溫,將新設計之加熱晶片結合上述之新式流體系統載具,開發出在穿透式電子顯微鏡中具有雙刺激元之流體加熱臨場觀測系統載具,以達到可同時與外界流通且精準控制反應環境溫度之目的,將臨場觀測技術與現今各式奈米材料反應過程連結,並對科學研究上做出貢獻。

    The in-situ observation in electron microscope has been widely discussed in recent years. This technology overcomes many limitation of sample and creates innovation of observation in electron microscope. The research depends on the demands of in-situ observation in transmission electron microscopy, so develop the fluid holder, by MEMS processes, design of mechanism and o-rings to encapsulate the fluid. It allows to inject different kinds of fluid or gas, and will not affect the vacuum value from outside. The new MEMS processes use Cr spacer which thickness is 200 nm to define the direction of flow to improve the velocity in the fluid holder before. Availability of self-designed fluid holder is proven by phase transitions of polystyrene‐b‐poly(dimethylsiloxane) with tuning toluene with certain velocity. A variety of phases, such as the sphere, cylinder, gyroid, lamellar phases and even inverted phases, can be acquired by simply tuning the selectivity of solvent. Additionally, we design the heating chip by MEMS processes. Compared to traditional resistance wires, the heating chip has high performance in heating rapidly and cooling, and use four point resistance feedback to precisely control the temperature. Combine the new-designed heating chip and the new fluid holder to develop dual stimulus source for heating and fluid holder in transmission electron microscope. It can define the temperature of reaction surrounding while injecting fluid from outside. Let the technology of in-situ observation link with many kinds of reaction in nanometer scale, and contribute to the technology research.

    摘要 i Abstract ii 致謝 iii 目錄 v 圖目錄 viii 表目錄 xv 第一章 緒論 1 1-1穿透式電子顯微鏡臨場觀測 1 1-1-1穿透式電子顯微鏡 1 1-1-2臨場觀測樣品桿 2 1-2研究動機與目的 4 第二章 文獻回顧 6 2-1流體臨場觀測系統 6 2-1-1初期環境式電子顯微鏡系統 6 2-1-2微型封閉式環境腔體元件 9 2-1-3流通式臨場觀測電子顯微鏡系統 14 2-2加熱臨場觀測系統 18 2-2-1初期環境式電子顯微鏡系統 18 2-2-2電子顯微鏡加熱載具 20 2-2-3微機電製程之微型加熱器 23 2-3流體加熱臨場觀測系統 26 2-4共聚嵌段高分子自組裝反應 28 第三章 實驗方法 30 3-1 實驗儀器 30 3-1-1 分析儀器 30 3-1-2 晶片製程儀器 34 3-2 流體系統晶片製程設計 36 3-2-1 流體系統晶片設計 36 3-2-2 光罩設計繪製 39 3-2-3 黃光微影 40 3-2-4 流體系統晶片製程流程 43 3-3 流體系統載具設計 48 3-3-1 自製攝影式tip 48 3-3-2 自製攝影式tip拍攝結果 49 3-3-3 流體tip之設計 50 3-4 流體加熱系統晶片製程設計 54 3-4-1 流體加熱系統晶片設計 54 3-4-2 光罩設計繪製 58 3-4-3 黃光微影 60 3-4-4 流體加熱系統晶片製程流程 62 3-5 流體加熱系統載具設計 70 3-6 加熱晶片溫度校正 72 3-7 流體臨場觀測實驗架設 74 3-7-1 高分子樣品製備 74 3-7-2 流體系統架設 75 3-8 流體加熱系統測試 76 第四章 結果與討論 77 4-1 流體系統晶片 77 4-2 流體系統載具 78 4-2-1 流速模擬分析 78 4-2-2 電子束對焦面測試 80 4-2-3 流體測試 81 4-3 流體臨場觀測結果 82 4-3-1 高分子樣品 82 4-3-2 輻射損傷 83 4-3-3 高分子自組裝反應 86 4-4 流體加熱系統晶片 90 4-4-1 水刀切割 90 4-4-2 濕蝕刻保護 92 4-4-3 上下晶片觀測視窗對準機制 96 4-4-4 加熱晶片溫度校正測試 97 4-5 流體加熱系統載具 102 第五章 結論 110 第六章 參考文獻 111

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