利用界面活性劑於介電濕潤驅動液滴間形成虛擬微流道

Hsin-Yi Lu; 盧欣宜

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/51723

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	范士岡(Shih-Kang Fan)
dc.contributor.author	Hsin-Yi Lu	en
dc.contributor.author	盧欣宜	zh_TW
dc.date.accessioned	2021-06-15T13:46:23Z	-
dc.date.available	2019-02-15
dc.date.copyright	2016-02-15
dc.date.issued	2015
dc.date.submitted	2015-11-25
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/51723	-
dc.description.abstract	近年來，微觀尺度下建立微流道的技術已相當成熟，為了改善微流道由於物理邊界而導致操作上尺寸及設計靈活性的減少，本論文利用介電濕潤（Electrowetting-on-dielectric）作為驅動液體的機制，於數位微流體操控平台上，提出一種無固體邊界且具有重現性的虛擬微流道（Virtual microchannel）。在去離子水中加入臨界微胞濃度（Critical micelle concentration, CMC）之Pluronic F127、Pluronic F68、TWEEN 20以及Triton X-100等界面活性劑，液體及虛擬微流道皆在兩平行ITO玻璃基材結構間移動和形成，利用界面活性劑會降低液體表面張力的特性，在兩顆液滴之間可輕易地形成一可任意改變型態和寬度的虛擬微流道。藉由不同設計之電極，可建立不同型態、長度（1000 um至5000 um）、高度（20 um至180 um）的虛擬微流道陣列，並利用共軛焦顯微鏡觀察，在高度為100 um下，該虛擬微流道可達1.74 um的寬度，使其深寬比達60。再者，於虛擬微流道的兩端施予不同電壓值，使液體由於兩端的壓力差形成一幫浦，並加入1 um的粒子，其憑藉著液體的流動，於流道口一次一顆噴濺而出，目前得到液體流經虛擬微流道的流量約為0.0088 nL/s至0.0382 nL/s，進一步將該技術用於DNA拉伸。本論文提出一種簡單的無固體邊界之虛擬微流道建立方法，不僅具有可重複性，且可整合其他微流體應用於單一晶片，並利用液體幫浦移動溶液中的粒子或DNA。	zh_TW
dc.description.abstract	In recent years, constructing flow channels on a micro scale has been intensively investigated. In order to improve the flexibility of the microchannels by removing their physical sidewalls, we demonstrate reprogrammable virtual microchannels on a digital microfluidic platform using electrowetting-on-dielectric (EWOD). We added different kinds of surfactants, Pluronic F127, Pluronic F68, TWEEN 20, and Triton X-100 to distilled deionized (DD) water at their critical micelle concentration (CMC). The virtual microchannels were established between two parallel Indium Tin Oxide (ITO) coated glass plates. A reprogrammable virtual microchannel without physical sidewalls between two droplets was achieved and stabilized simply due to the surfactant molecules. By using different patterns of the electrodes, we created virtual microchannels in various forms, lengths (from 1000 um to 5000 um), and heights (from 20 um to 180 um). We obtained high aspect ratios as 60 when the virtual microchannel was 100 um high and 1.74 um wide. We applied different voltages on the two sides of the microchannel to generate uneven pressure and to pump the liquid. Furthermore, we put 1 um particles into the liquid for visualizing the flow. Individual particles passing through the microchannel at a time were observed. The pumping rate was about 0.0088 nL/s to 0.0382 nL/s. Moreover, DNA molecules were stretched with the flow in the virtual microchannels.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T13:46:23Z (GMT). No. of bitstreams: 1 ntu-104-R02522111-1.pdf: 7975602 bytes, checksum: 1630684f8b7d9296b0611e740384b2fd (MD5) Previous issue date: 2015	en
dc.description.tableofcontents	誌謝................................i 中文摘要.............................ii 英文摘要.............................iii 目錄.................................v 圖目錄...............................viii 表目錄...............................xiii 第一章緒論.........................1 1-1 前言.............................1 1-2 微流體系統........................2 1-2.1 數位微流體晶片.................2 1-2.2 微流道........................5 1-2.3 虛擬微流道....................7 1-3 界面活性劑........................10 1-4 研究動機..........................12 1-5 論文組織架構.......................13 第二章理論介紹......................14 2-1 介電濕潤..........................14 2-1.1 介電濕潤原理...................14 2-1.2 介電濕潤應用...................16 2-2 界面活性劑.........................17 2-2.1 臨界微胞濃度...................17 2-2.2 表面張力......................18 2-2.3 實驗用界面活性劑...............20 2-3 微流體幫浦.........................23 第三章介電濕潤晶片實驗平台與實驗設計...25 3-1 晶片設計與製程參數..................25 3-1.1 介電濕潤晶片設計................25 3-1.2 介電濕潤晶片製程................28 3-2 實驗平台與儀器簡介..................33 3-2.1 實驗平台操作系統................33 3-2.2 電路設計.......................34 3-2.3 儀器簡介.......................36 3-2.4 微流體幫浦流速分析方法...........45 3-3 實驗操作流程........................47 3-3.1 實驗試劑配置....................47 3-3.2 實驗流程.......................47 第四章結果與討論.....................48 4-1 表面張力量測.......................48 4-2 虛擬微流道的形成....................51 4-2.1 不同操作條件下之虛擬微流道.......53 4-2.2 不同型態的虛擬微流道.............57 4-2.3 虛擬微流道之三維結構.............60 4-3 虛擬微流道幫浦......................61 4-3.1 形成虛擬微流道幫浦 ..............61 4-3.2 虛擬微流道幫浦之流動速度.........64 4-4 虛擬微流道應用......................73 4-4.1 離子型粒子於微流體幫浦...........73 4-4.2 DNA拉伸........................74 第五章結語與未來展望..................76 5-1 結語...............................76 5-2 未來展望...........................76 參考文獻...............................78
dc.language.iso	zh-TW
dc.subject	DNA拉伸	zh_TW
dc.subject	虛擬微流道	zh_TW
dc.subject	介電濕潤	zh_TW
dc.subject	幫浦	zh_TW
dc.subject	界面活性劑	zh_TW
dc.subject	DNA stretching	en
dc.subject	Virtual microchannel	en
dc.subject	surfactant	en
dc.subject	pumping	en
dc.subject	electrowetting	en
dc.title	利用界面活性劑於介電濕潤驅動液滴間形成虛擬微流道	zh_TW
dc.title	Surfactant-Stabilized Virtual Microchannels between Electrowetting-Driven Droplets	en
dc.type	Thesis
dc.date.schoolyear	104-1
dc.description.degree	碩士
dc.contributor.oralexamcommittee	曹嘉文(Chia-Wen Tsao),趙玲(Ling Chao)
dc.subject.keyword	虛擬微流道,介電濕潤,幫浦,界面活性劑,DNA拉伸,	zh_TW
dc.subject.keyword	Virtual microchannel,electrowetting,pumping,surfactant,DNA stretching,	en
dc.relation.page	80
dc.rights.note	有償授權
dc.date.accepted	2015-11-26
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	機械工程學研究所	zh_TW
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