單分子於奈米碳管生物感測器之研究

Ming-Chih Kuo; 郭明誌

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/32332

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	黃榮山(Long-Sun Huang)
dc.contributor.author	Ming-Chih Kuo	en
dc.contributor.author	郭明誌	zh_TW
dc.date.accessioned	2021-06-13T03:43:16Z	-
dc.date.available	2008-07-30
dc.date.copyright	2006-07-30
dc.date.issued	2006
dc.date.submitted	2006-07-26
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/32332	-
dc.description.abstract	本論文嘗試利用奈米碳管電晶體做為生物反應平台，並結合全反射螢光顯微術進行蛋白質分子的即時量測與觀察。以對奈米碳管與生物分子之間的鍵結提供一個眼見為憑的驗證。並且從中找出單分子與奈米碳管電晶體電訊號的相互關係以及單分子造成訊號改變的可能原因。此外，本研究除了成功的嘗試利用一種具有磁性的新觸媒金屬--四氧化三鐵（Fe3O4）奈米顆粒成長奈米碳管。在製作奈米碳管電晶體方面，由於以往製作奈米碳管電晶體的觸媒金屬島只能使用成本昂貴且產量少的電子束曝光系統。但本論文突破其限制，成功的利用一般黃光製程所定義出觸媒金屬島，製作出可量產的奈米碳管電晶體。由於全反射螢光顯微術的主要原理是利用全反射所產生的漸逝波來激發表面的螢光分子，再藉由CCD擷取到所需要的螢光。因此光所通過的材料都必須具有高透明度、低厚度的基材，所以原先製作出矽底材的奈米碳管電晶體就無法達到需求。為此目的，本研究利用聚亞醯胺這種材料，在經過旋塗和蝕刻製程後，成功地將奈米碳管電晶體轉置到厚度僅有7 μm的透明聚亞醯胺基材上。並且利用4 ~ 5 %wt的草酸蝕刻氧化銦錫(ITO)玻璃，定義出可撓式奈米碳管電晶體所需的透明背電極以達到可同時觀測與量測的功能。最後，我們再利用微機電技術所製作出的PDMS微流道，利用氧化電漿(Oxide plasma) 整合到氧化銦錫(ITO)玻璃上成為一個完整的生物晶片，並且藉由幫浦(switch pump)控制生物分子流入流道的時間。在成功製作出奈米碳管電晶體後，經過量測奈米碳管電晶體電訊號後，發現本研究的奈米碳管具有p-type電晶體的特性，該訊號的開關比（ON/OFF ratio）高達103。另外，在經過轉置後的可撓式奈米碳管電晶體，量測後也發現雖然所需的閘極電壓較大，但仍具有電晶體的特性表現。在觀測蛋白質分子與奈米碳管鍵結的影像捕捉方面，本研究也成功的利用cytoviva TM 150觀察到奈米碳管的外型，並且再流入與量子點鍵結的鏈黴卵白素(strepavidin)後，成功地利用全反射螢光顯微鏡觀測到蛋白質分子與奈米碳管的影像。	zh_TW
dc.description.provenance	Made available in DSpace on 2021-06-13T03:43:16Z (GMT). No. of bitstreams: 1 ntu-95-R93543058-1.pdf: 5738994 bytes, checksum: b3526a752ad38c68a1c3aae8886a532d (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	口試委員會審定書 i 誌謝 iii 中文摘要 iii Abstract v 目錄 vii 圖目錄 xi 表目錄 xv 第 1 章緒論 1 1-1 前言 1 1-1-1 奈米碳管生物感測器 1 1-1-2 奈米碳管場效電晶體與可撓式電子元件 2 1-1-3 全反射螢光顯微術與Cytoviva TM 150 3 1-2 研究動機與目的 4 1-3 文獻回顧 5 1-3-1 奈米碳管生物感測原理 5 1-3-2 奈米碳管場效電晶體與可撓式電子元件 11 1-3-3 全反射螢光顯微術 21 1-4 研究方法 23 1-5 論文架構 24 第 2 章奈米碳管理論基礎 26 2-1 奈米碳管的發展歷史 26 2-2 奈米碳管的構造 29 2-2-1 單壁奈米碳管 29 2-2-2 多壁奈米碳管 33 2-3 奈米碳管的成長機制 36 2-4 奈米碳管生物感測器 37 2-4-1 奈米碳管表面功能化修飾 38 2-4-2 奈米碳管場效電晶體 41 2-4-3 單分子生物感測器 45 第 3 章即時觀測系統之原理與架設 50 3-1 全反射螢光顯微鏡原理與架設 50 3-1-1 全反射螢光顯微鏡之基本原理 51 3-1-2 全反射螢光顯微鏡之光學架設 53 第 4 章奈米碳管生物感測器之設計 56 4-1 奈米碳管製備 57 4-1-1 觸媒金屬材料及顆粒大小之選擇 57 4-1-2 氣體及溫度的選擇 59 4-2 奈米碳管電晶體生物感測器之設計 60 4-2-1 電極材料及功能之設計 60 4-2-2 絕緣層材料的選擇 63 4-2-3 觸媒金屬島定位址之設計 63 4-2-4 奈米碳管生物感測器電極設計 65 4-2-5 可撓式奈米碳管電晶體之設計 67 4-2-6 奈米碳管生物感測器基板之設計 69 4-2-7 奈米碳管生物感測器微流道之設計 70 4-3 生物分子之選用 72 第 5 章奈米碳管生物感測器之製作 73 5-1 觸媒金屬島定義之製作 73 5-2 奈米碳管電晶體之製作 74 5-3 可撓式奈米碳管電晶體之製作 78 5-4 奈米碳管生物感測器基板之製作 79 5-5 奈米碳管生物感測器微流道之製作 81 5-6 奈米碳管生物感測器之整合 83 第 6 章實驗結果與討論 84 6-1 觸媒金屬島定義 85 6-1-1 利用黃光微影製程定義觸媒金屬島的實驗結果 85 6-1-2 利用觸媒金屬島成長奈米碳管的實驗結果 86 6-2 奈米碳管外觀量測 90 6-2-1 奈米碳管外觀量測—掃描式電子顯微鏡 90 6-3 電晶體電訊號量測 91 6-3-1 電晶體外觀量測 91 6-3-2 電晶體電訊號量測架構 92 6-3-3 p型奈米碳管電晶體電訊號 93 6-4 可撓式奈米碳管電晶體電訊號 94 6-4-1 可撓式電晶體製作結果 94 6-4-2 可撓式電晶體電訊號量測 97 6-5 奈米碳管生物感測器之鍵結觀測 98 6-5-1 Cytoviva TM 150觀測奈米碳管之影像 98 6-5-2 全反射螢光顯微鏡觀測奈米碳管與蛋白質結果 101 6-6 奈米碳管生物感測器電訊號量測 103 6-7 奈米碳管生物感測器整合之結果 105 6-7-1 奈米碳管生物感測器之基板製作結果 105 6-7-2 奈米碳管生物感測器之整合結果 106 第 7 章結論與未來展望 107 7-1 結論 107 7-2 未來展望 109 參考文獻 110
dc.language.iso	zh-TW
dc.subject	奈米碳管生物感測器	zh_TW
dc.subject	奈米碳管	zh_TW
dc.subject	單分子	zh_TW
dc.subject	奈米碳管電晶體	zh_TW
dc.subject	全反射螢光顯微術	zh_TW
dc.subject	carbon nanotube biosensor	en
dc.subject	TIRFM	en
dc.subject	carbon nanotube field effect transistor (CNTFET)	en
dc.subject	carbon nanotube(CNT)	en
dc.subject	single molecule	en
dc.title	單分子於奈米碳管生物感測器之研究	zh_TW
dc.title	A Study of Single Molecule with the Carbon Nanotube Biosensor	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	楊燿州(Yao-Joe Joseph Yang),施文彬(Wen-Pin Shih),吳志偉(Chih-Wei Wu)
dc.subject.keyword	單分子,奈米碳管,奈米碳管電晶體,奈米碳管生物感測器,全反射螢光顯微術,	zh_TW
dc.subject.keyword	single molecule,carbon nanotube(CNT),carbon nanotube field effect transistor (CNTFET),carbon nanotube biosensor,TIRFM,	en
dc.relation.page	116
dc.rights.note	有償授權
dc.date.accepted	2006-07-26
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	應用力學研究所	zh_TW
顯示於系所單位：	應用力學研究所

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