圓柱形孔道內球形帶電粒子在高分子溶液中之電泳與電滲透運動

Yu-fen Huang; 黃郁棻

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/2613

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	李克強(Eric Lee)
dc.contributor.author	Yu-fen Huang	en
dc.contributor.author	黃郁棻	zh_TW
dc.date.accessioned	2021-05-13T06:43:08Z	-
dc.date.available	2019-02-17
dc.date.available	2021-05-13T06:43:08Z	-
dc.date.copyright	2017-02-17
dc.date.issued	2017
dc.date.submitted	2017-02-10
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/2613	-
dc.description.abstract	在毛細管電泳及微米/奈米流體的系統中，所採用的介質除了眾所習知的凝膠與水溶液之外，高分子溶液也逐漸被廣泛應用，所採用的流體管道也愈來愈微小化。本研究探討帶電球形粒子於填充高分子溶液的圓柱形管道中之電泳與電滲透運動現象，並以Debye-Bueche-Brinkman (DBB)模型來描述高分子水溶液的流體性質。DBB模型針對線性高分子溶於均勻的溶劑系統，描述高分子溶液的流變學特性，為經過嚴謹推導的非牛頓流體模型。對應的電動力學主控方程式乃由Debye及Bueche以Chebyshev多項式為基礎，採用修正的假性光譜法來進行數值解。根據數值模擬結果，吾人發現粒子的泳動度因電雙層極化效應而在κa等於1附近有明顯的下降，特別是在窄管道中。此乃導因於管壁產生額外的侷限效應，而使帶電粒子附近電雙層當中的反離子移動到粒子運動方向之後方，誘發反向電場而阻滯粒子運動。在高分子溶液中，粒子的泳動度低於電解質水溶液，乃因高分子流體中黏滯力對粒子運動的阻礙效應更強。此外，管壁帶電條件下，管道中的電滲透流分布呈現特別的非牛頓特性。不同於牛頓流體中呈現平推流(plug flow)的分布，在高分子溶液中可明顯觀察到電滲透流的流速分布在管壁附近出現極大值，且為軸對稱分布。此種軸向變化的速度分布可能對於靠近管壁流動的小分子提供額外的沖提分離機制。本研究突破數學上複雜性的限制，數值模擬結果對於採用高分子溶液為介質的微奈米管道電泳與電滲透現象分析提供良好的理論研究基礎。	zh_TW
dc.description.abstract	Electrophoretic and electroosmotic motion of a charged spherical particle within a cylindrical pore filled with a Debye-Bueche-Brinkman (DBB) polymeric solution is investigated theoretically, which is of high relevance in capillary electrophoresis as well as micro- and nanofluidic applications involving polymeric solutions in a micro- or nanopore. The DBB model describes rheological response of a polymeric solution with linear polymer dissolved in a homogeneous solvent. It is a well-known non-Newtonian model in liquid physics based on rigorous theoretical derivations. By Debye and Bueche, corresponding governing fundamental electrokinetic equations are solved numerically with a patched pseudo-spectral method based on Chebyshev polynomials. We found that the double layer polarization effect reduces the particle mobility severely when the Debye parameter, κa, is around unity, especially in narrow pores. This is attributed to the extra confinement effect from the nearby wall which tends to sweep the predominant counterions within the double layer to the wake of the moving particle, resulting in a motion-deterring induced electric field. The electrophoretic mobility in a polymer solution is smaller than that in an aqueous electrolyte solution in general due to the much stronger viscous drag effect in a polymer solution. Moreover, electroosmotic flow (EOF) due to a charged pore wall is found to exhibit a highly non-Newtonian behavior. Unlike the corresponding plug-like flow for a Newtonian solution, an axisymmetric flow with a large local maximum in the velocity profile in the region near the pore wall is observed. This radial-varying velocity profile offers a potential extra separation mechanism which favors the elution of smaller particles in general. The results obtained here provide fundamental understandings and insights of the electrophoresis and electroosmosis phenomena in a cylindrical pore filled with polymeric solution.	en
dc.description.provenance	Made available in DSpace on 2021-05-13T06:43:08Z (GMT). No. of bitstreams: 1 ntu-106-D98524021-1.pdf: 4865418 bytes, checksum: a29fa03f5555016bf4bd7c34f6a59b32 (MD5) Previous issue date: 2017	en
dc.description.tableofcontents	誌謝中文摘要 I Abstract III 目錄 V 圖目錄 IX 表目錄 XIII 第一章緒論 1 1.1 膠體懸浮液系統 1 1.2 膠體電動力學現象及文獻回顧 5 1.2.1 電雙層理論及膠體電動力學應用 5 1.2.2 電泳現象應用及相關文獻 8 1.2.3 電滲透流現象及相關文獻 12 1.3 粒子於微流道中電動力學相關應用 16 1.3.1 毛細管電泳技術發展進程 16 1.3.2 毛細管電泳裝置及電動力學效應 18 1.3.3 微流道電泳之待測物分離模式及篩分介質 23 1.3.4 微流道電泳中不同介質之篩分機制 27 1.4 粒子在微流道電泳現象理論研究回顧 35 1.4.1 微流道中電泳遷移的作用力理論分析 35 1.4.2 粒子在微流道中電泳遷移現象相關研究文獻 36 第二章理論分析 41 2.1 系統描述 41 2.2 主控方程式 43 2.2.1 電位方程式 43 2.2.2 離子守恆式 43 2.2.3 流場方程式 44 2.3 平衡態與擾動態 47 2.3.1 平衡態 47 2.3.2 擾動態 48 2.4 無因次化分析 52 2.5 邊界條件 55 2.5.1 粒子邊界 55 2.5.2 流體通道邊界 56 2.5.3 其它邊界 58 2.6 粒子受力計算 58 2.7 泳動度計算 59 2.8 計算流程 61 第三章數值方法 63 3.1 正交配位法 64 3.2 空間映射 70 3.3 牛頓—拉福森疊代法 73 3.4 數值積分 76 第四章球形粒子於微流道中之電泳運動現象 79 4.1 硬球表面電位( ζa)的影響 82 4.2 摩擦阻力係數(λa)的影響 88 4.3 圓柱管道半徑( Rb* )的影響 90 4.4 電滲透流(EOF)的影響 97 4.5 電泳及電滲透流(EOF)的加成影響 104 4.6 結論 110 參考文獻 112 符號說明 130 附錄A 座標系統簡介 136 附錄B 主控方程式之詳細推導 142 附錄C 力積分之推導 146 附錄D 常見電解質水溶液參數值 152 附錄E 高分子溶液的特性黏度與遮蔽係數 154
dc.language.iso	zh-TW
dc.subject	電滲透	zh_TW
dc.subject	電泳	zh_TW
dc.subject	電雙層極化效應	zh_TW
dc.subject	電動力學	zh_TW
dc.subject	Debye-Bueche-Brinkman高分子溶液	zh_TW
dc.subject	electric double layer polarization	en
dc.subject	Debye-Bueche-Brinkman (DBB) polymer solution	en
dc.subject	electroosmosis	en
dc.subject	electrophoresis	en
dc.subject	electrokinetics	en
dc.title	圓柱形孔道內球形帶電粒子在高分子溶液中之電泳與電滲透運動	zh_TW
dc.title	Electrophoretic and Electroosmotic Motion of a Charged Spherical Particle within a Cylindrical Pore Filled with Polymeric Solution	en
dc.type	Thesis
dc.date.schoolyear	105-1
dc.description.degree	博士
dc.contributor.oralexamcommittee	周正堂(Cheng-Tung Chou),朱智瑋(Jhih-Wei Chu),趙玲(Ling Chao),游佳欣(Jiashing Yu)
dc.subject.keyword	電泳,電滲透,電動力學,Debye-Bueche-Brinkman高分子溶液,電雙層極化效應,	zh_TW
dc.subject.keyword	electrophoresis,electroosmosis,electrokinetics,electric double layer polarization,Debye-Bueche-Brinkman (DBB) polymer solution,	en
dc.relation.page	159
dc.identifier.doi	10.6342/NTU201700486
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2017-02-10
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	化學工程學研究所	zh_TW
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