分类
镊子
光学镊子
光电子学
材料科学
液晶
光学
物理
计算机科学
程序设计语言
作者
Y. S. Tsai,Ju-Nan Kuo,Shie‐Chang Jeng
标识
DOI:10.1088/1361-6439/ae00d0
摘要
Abstract This study presents an advanced approach for the precise manipulation and automated sorting of liquid crystal (LC) droplets using an optoelectronic tweezers (OETs) system. By employing a dynamically rotating radial light pattern to create virtual electrodes, we successfully achieved the controlled trapping, collection, and size-based sorting of LC droplets. A comprehensive analysis of the droplet-light interaction reveals a unique ‘hopping’ mechanism, which is governed by the disparity between the terminal angular frequency of the LC droplets and the angular frequency of the rotating light pattern. This phenomenon facilitates the selective detachment of droplets from OET traps, enabling efficient sorting. Numerical simulations validate that the strongest electric field gradient occurs at the edges of the virtual electrodes, where the dielectrophoretic (DEP) force is maximized, ensuring efficient droplet manipulation. To optimize the sorting process, we systematically investigate the effects of various parameters, including driving voltage, operating frequency, and light pattern width, on the dynamic response of LC droplets. Our experimental results demonstrate that at a driving voltage of 20 V pp and frequency of 100 kHz, LC droplets within the size range of 7–15 μ m can be successfully sorted into four distinct regions. The sorting resolution reaches 2 μ m, enabling precise classification of droplets based on their sizes. Furthermore, we observed that when the light pattern rotates at 90 deg s −1 , LC droplets of 28 μ m exhibit the hopping mechanism, transitioning into the next sorting region. The critical angular frequency required to induce the hopping mechanism increases with droplet size, reaching 200 deg s −1 for droplets exceeding 54 μ m when using a 24 μ m-wide light pattern.
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