Multimodal Manipulation of Particles Based on Optothermal Controlled Marangoni Convection in Dynamic Microfluidics

马朗戈尼效应 微流控 粒子(生态学) 光学力 流量(数学) 对流 纳米技术 光学镊子 领域(数学) 材料科学 粒子图像测速 光学 化学 流量控制(数据) 光散射 机械 调制(音乐) 航程(航空) 光流 流体力学 动态范围
作者
Fengya Lu,L. He,Tong Li,Xiao Xia,Yipeng Dou,Xianghao Tan,Jiankang Wang,Jinhua Zhou,Yuxin Mao
出处
期刊:Langmuir [American Chemical Society]
卷期号:41 (37): 25137-25145 被引量:3
标识
DOI:10.1021/acs.langmuir.5c01895
摘要

Optical manipulation techniques have been widely applied in the biomedical field. However, the key issues limiting the efficiency of optical manipulation techniques are the weak driving force of optical scattering and the small working range of optical gradient forces. The optothermal Marangoni convection enables effective control of flow fields through optical means, and particle manipulation based on this mechanism offers advantages such as a wide working range, strong driving force, and high flexibility. In recent years, it has been applied in fields such as biological cell manipulation and micro/nanomaterial assembly. However, current research predominantly focuses on particle manipulation in static environments, overlooking the potential applications of this method in dynamic and complex flow fields. In this study, we investigate particle manipulation methods based on optothermal Marangoni convection in dynamic flow fields. Through combined simulation and experiment, we systematically characterized flow field profile and particle trajectories under coupled "optothermal-flow" control, developed manipulation schemes with extended working range (>20 μm) and multiparticle capacity for trapping, assembly, and migration. Through laser spot positioning, we achieved real-time flow field modulation in microchannels, enabling versatile multimodal particle control. These findings demonstrate the substantial potential of optothermal Marangoni convection in microfluidic applications, offering a novel methodology for dynamic flow field regulation and high-efficiency on-chip particle manipulation.
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