Programmable thermocapillary shaping of thin liquid films

IF 2.8 Q2 MECHANICS

Flow (Cambridge, England) Pub Date : 2021-09-01 DOI:10.1017/flo.2022.17

R. Eshel, V. Frumkin, Matan Nice, Omer Luria, Boris Ferdman, Nadav Opatovski, K. Gommed, M. Shusteff, Y. Shechtman, M. Bercovici

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引用次数: 2

Abstract

Abstract We present a method that leverages projected light patterns as a mechanism for freeform deformation of a thin liquid film via the thermocapillary effect. We developed a closed-form solution for the inverse problem of the thin-film evolution equation, allowing us to obtain the projection pattern required in order to achieve a desired topography. We experimentally implement the method using a computer controlled light projector, which illuminates any desired pattern onto the bottom of a fluidic chamber patterned with heat–absorbing metal pads. The resulting heat map induces surface tension gradients in the liquid–air interface, giving rise to thermocapillary flow that deforms the liquid surface. If a polymer is used for the liquid film, it can then be photocured to yield a solid device. Based on the inverse-problem solutions and using this system, we demonstrate the fabrication of several diffractive optical elements, including phase masks for extended depth of field imaging, and for three-dimensional localization microscopy. The entire process, from projection to solidification, is completed in less than five minutes, and yields a sub-nanometric surface quality without any post-processing.

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薄液膜的可编程热毛细管成形

摘要我们提出了一种利用投影光图案作为通过热毛细效应实现薄液膜自由变形的机制的方法。我们为薄膜演化方程的反问题开发了一个闭合形式的解决方案，使我们能够获得所需的投影模式，以实现所需的形貌。我们使用计算机控制的投光器实验性地实现了该方法，该投光器将任何想要的图案照射到带有吸热金属垫图案的流体室的底部。由此产生的热图在液体-空气界面中引发表面张力梯度，产生使液体表面变形的热毛细管流。如果将聚合物用于液膜，则可以对其进行光固化以产生固体器件。基于反问题解并使用该系统，我们演示了几种衍射光学元件的制造，包括用于扩展景深成像和三维定位显微镜的相位掩模。从投影到固化的整个过程在不到五分钟的时间内完成，无需任何后处理即可获得亚纳米的表面质量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Flow (Cambridge, England)

CiteScore

2.40

自引率

0.00%

发文量