Optothermal generation, steady-state trapping, and 3D manipulation of bubbles: an experimental and theoretical analysis of the Marangoni effect

IF 2 4区 物理与天体物理 Q3 OPTICS Journal of Optics Pub Date : 2024-07-10 DOI:10.1088/2040-8986/ad5d02
Julio Aurelio Sarabia-Alonso and Rubén Ramos-García
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Abstract

Since Nobel Laureate Arthur Ashkin first introduced the trapping and manipulation of microparticles using light, numerous studies have explored this technique not only for dielectric/metallic particles but also for organic matter. This advancement has significantly expanded the landscape of non-contact and non-invasive micromanipulation at the nanometric scale. However, micromanipulation of particles with a refractive index smaller than the host medium, np< nm, proves challenging with Gaussian beams. To overcome this obstacle, a force known as thermocapillary, or the Marangoni force, has emerged as a straightforward trapping mechanism for bubbles in liquids. The Marangoni force results from the surface tension of bubbles, induced either thermally or chemically—by creating a temperature gradient or adding surfactants, respectively. The surface tension gradient on the liquid host induces tangential stress on the bubble wall, causing the bubble to move toward the region of lower surface tension, where it faces less opposing force. When the Marangoni force is generated by a laser beam’s temperature gradient, it becomes an exceptionally effective mechanism for the steady-state trapping and three-dimensional manipulation of bubbles, even with low optical power lasers. This force produces both longitudinal and transversal forces, resembling optical forces, creating a three-dimensional potential well capable of handling bubbles with radii of tens to hundreds of microns. This work provides guidance and demonstrates, both experimentally and theoretically, the step-by-step process of quasi-steady-state trapping and three-dimensional manipulation of bubbles through optothermal effects. The bubbles in question are tens of microns in size, significantly larger than those that optical tweezers can trap/manipulate. Furthermore, the study emphasizes the crucial role of the Marangoni force in this process, outlining its various advantages.
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气泡的光热生成、稳态捕获和三维操控:马兰戈尼效应的实验和理论分析
自诺贝尔奖获得者阿瑟-阿什金首次提出用光捕获和操纵微颗粒以来,许多研究不仅对电介质/金属颗粒,而且对有机物都进行了这种技术的探索。这一进步极大地扩展了纳米尺度非接触和非侵入式微操纵的范围。然而,对于折射率小于主介质(np< nm)的粒子,使用高斯光束进行微操作具有挑战性。为了克服这一障碍,一种被称为热毛细管力或马兰戈尼力的力应运而生,成为液体中气泡的直接捕获机制。马兰戈尼力是由气泡的表面张力产生的,这种表面张力是通过热或化学方法诱发的,分别是制造温度梯度或添加表面活性剂。液体主机上的表面张力梯度会在气泡壁上产生切向应力,导致气泡向表面张力较低的区域移动,在那里它所面临的反作用力较小。当激光束的温度梯度产生马兰戈尼力时,它就会成为稳态捕获和三维操控气泡的一种异常有效的机制,即使使用的是低光学功率激光器。这种力会产生纵向和横向力,类似于光学力,从而产生一种三维势能,能够很好地处理半径为几十到几百微米的气泡。这项工作提供了指导,并从实验和理论两方面展示了通过光热效应对气泡进行准稳态捕获和三维操控的逐步过程。有关气泡的大小为几十微米,比光镊所能捕获/操纵的气泡大得多。此外,研究还强调了马兰戈尼力在这一过程中的关键作用,并概述了它的各种优势。
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来源期刊
CiteScore
4.50
自引率
4.80%
发文量
237
审稿时长
1.9 months
期刊介绍: Journal of Optics publishes new experimental and theoretical research across all areas of pure and applied optics, both modern and classical. Research areas are categorised as: Nanophotonics and plasmonics Metamaterials and structured photonic materials Quantum photonics Biophotonics Light-matter interactions Nonlinear and ultrafast optics Propagation, diffraction and scattering Optical communication Integrated optics Photovoltaics and energy harvesting We discourage incremental advances, purely numerical simulations without any validation, or research without a strong optics advance, e.g. computer algorithms applied to optical and imaging processes, equipment designs or material fabrication.
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