Lateral flow through a parallel gap driven by surface hydrophilicity and liquid edge pinning for creating microlens array

Chengbao Jiang; Xiangming Li; Hongmiao Tian; Chunhui Wang; Jinyou Shao; Yucheng Ding; Li Wang

doi:10.1021/am506067v

Lateral flow through a parallel gap driven by surface hydrophilicity and liquid edge pinning for creating microlens array

Chengbao Jiang
, Xiangming Li
, Hongmiao Tian
, Chunhui Wang
, Jinyou Shao
, Yucheng Ding
, Li Wang

School of Mechanical Engineering

Xi'an Jiaotong University

Research output: Contribution to journal › Article › peer-review

38 Scopus citations

Abstract

This letter proposes a surface-energy driven process for economically creating polymer microlens array (MLA) with well controllable curvatures. When a UV-curable prepolymer flows into a cell constructed by multiple holes on a top template and a flat substrate, since the edge pinning of the contact line, an array of curved air/prepolymer interface forms around each microhole of the template. Then a UV-radiation of the bulk prepolymer leads to a solid microlens array. The curvature of the air/prepolymer interface can be controlled by choosing materials with different interface free energy or varying the gap height mechanically.

Original language	English
Pages (from-to)	18450-18456
Number of pages	7
Journal	ACS Applied Materials and Interfaces
Volume	6
Issue number	21
DOIs	https://doi.org/10.1021/am506067v
State	Published - 12 Nov 2014

Keywords

hydrophilicity
liquid pinning
microlens array
micromolding
surface energy

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10.1021/am506067v

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title = "Lateral flow through a parallel gap driven by surface hydrophilicity and liquid edge pinning for creating microlens array",

abstract = "This letter proposes a surface-energy driven process for economically creating polymer microlens array (MLA) with well controllable curvatures. When a UV-curable prepolymer flows into a cell constructed by multiple holes on a top template and a flat substrate, since the edge pinning of the contact line, an array of curved air/prepolymer interface forms around each microhole of the template. Then a UV-radiation of the bulk prepolymer leads to a solid microlens array. The curvature of the air/prepolymer interface can be controlled by choosing materials with different interface free energy or varying the gap height mechanically.",

keywords = "hydrophilicity, liquid pinning, microlens array, micromolding, surface energy",

author = "Chengbao Jiang and Xiangming Li and Hongmiao Tian and Chunhui Wang and Jinyou Shao and Yucheng Ding and Li Wang",

note = "Publisher Copyright: {\textcopyright} 2014 American Chemical Society.",

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doi = "10.1021/am506067v",

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T1 - Lateral flow through a parallel gap driven by surface hydrophilicity and liquid edge pinning for creating microlens array

AU - Jiang, Chengbao

AU - Li, Xiangming

AU - Tian, Hongmiao

AU - Wang, Chunhui

AU - Shao, Jinyou

AU - Ding, Yucheng

AU - Wang, Li

PY - 2014/11/12

Y1 - 2014/11/12

N2 - This letter proposes a surface-energy driven process for economically creating polymer microlens array (MLA) with well controllable curvatures. When a UV-curable prepolymer flows into a cell constructed by multiple holes on a top template and a flat substrate, since the edge pinning of the contact line, an array of curved air/prepolymer interface forms around each microhole of the template. Then a UV-radiation of the bulk prepolymer leads to a solid microlens array. The curvature of the air/prepolymer interface can be controlled by choosing materials with different interface free energy or varying the gap height mechanically.

AB - This letter proposes a surface-energy driven process for economically creating polymer microlens array (MLA) with well controllable curvatures. When a UV-curable prepolymer flows into a cell constructed by multiple holes on a top template and a flat substrate, since the edge pinning of the contact line, an array of curved air/prepolymer interface forms around each microhole of the template. Then a UV-radiation of the bulk prepolymer leads to a solid microlens array. The curvature of the air/prepolymer interface can be controlled by choosing materials with different interface free energy or varying the gap height mechanically.

KW - hydrophilicity

KW - liquid pinning

KW - microlens array

KW - micromolding

KW - surface energy

UR - https://www.scopus.com/pages/publications/84910125076

U2 - 10.1021/am506067v

DO - 10.1021/am506067v

M3 - 文章

AN - SCOPUS:84910125076

SN - 1944-8244

VL - 6

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EP - 18456

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 21

ER -

Lateral flow through a parallel gap driven by surface hydrophilicity and liquid edge pinning for creating microlens array

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Keywords

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