Optimizing light pattern curvature to improve the performance of optoelectronic tweezers in micromanipulation

Bingrui Xu; Gong Li; Lixiang Zheng; Wenbo Dong; Pengfei Song; Zongliang Guo; Zonghao Li; Haobing Liu; Ziang Ma; Hainan Xie; Wei Xie; Hang Li; Rongxin Fu; Yao Lu; Na Liu; Huikai Xie; Shuailong Zhang

doi:10.1364/OE.543990

Optimizing light pattern curvature to improve the performance of optoelectronic tweezers in micromanipulation

Bingrui Xu, Gong Li, Lixiang Zheng, Wenbo Dong, Pengfei Song, Zongliang Guo, Zonghao Li, Haobing Liu, Ziang Ma, Hainan Xie, Wei Xie, Hang Li, Rongxin Fu, Yao Lu, Na Liu, Huikai Xie, Shuailong Zhang

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

Optoelectronic tweezers (OET) offer a versatile, programmable, and contactless method for manipulating microscale objects. While factors like AC voltage and light intensity have been extensively studied, the role of light pattern curvature in the performance of OET manipulation remains underexplored. This study investigates how the curvature of light patterns affects the movement of polystyrene microparticles under negative dielectrophoretic (DEP) forces in an OET system. Experimental results show that as the curvature decreases, the maximum velocity of microparticles first increases to a peak and then gradually decreases. Numerical simulations reveal that light pattern curvature significantly influences the horizontal and vertical DEP forces, altering equilibrium positions and maximum velocities. By defining the optimal curvature (χ, the ratio of microparticle diameter to the inner diameter of the light pattern), we found that microparticles achieve maximum velocity and stability at this optimal ratio regardless of the sizes. These findings offer key insights into optimizing OET for improved manipulation performance, facilitating more precise and efficient applications in micromanipulation, micro-assembly, microfabrication, and beyond.

源语言	英语
页（从-至）	2968-2979
页数	12
期刊	Optics Express
卷	33
期	2
DOI	https://doi.org/10.1364/OE.543990
出版状态	已出版 - 27 1月 2025

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Xu, B., Li, G., Zheng, L., Dong, W., Song, P., Guo, Z., Li, Z., Liu, H., Ma, Z., Xie, H., Xie, W., Li, H., Fu, R., Lu, Y., Liu, N., Xie, H., & Zhang, S. (2025). Optimizing light pattern curvature to improve the performance of optoelectronic tweezers in micromanipulation. Optics Express, 33(2), 2968-2979. https://doi.org/10.1364/OE.543990

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title = "Optimizing light pattern curvature to improve the performance of optoelectronic tweezers in micromanipulation",

abstract = "Optoelectronic tweezers (OET) offer a versatile, programmable, and contactless method for manipulating microscale objects. While factors like AC voltage and light intensity have been extensively studied, the role of light pattern curvature in the performance of OET manipulation remains underexplored. This study investigates how the curvature of light patterns affects the movement of polystyrene microparticles under negative dielectrophoretic (DEP) forces in an OET system. Experimental results show that as the curvature decreases, the maximum velocity of microparticles first increases to a peak and then gradually decreases. Numerical simulations reveal that light pattern curvature significantly influences the horizontal and vertical DEP forces, altering equilibrium positions and maximum velocities. By defining the optimal curvature (χ, the ratio of microparticle diameter to the inner diameter of the light pattern), we found that microparticles achieve maximum velocity and stability at this optimal ratio regardless of the sizes. These findings offer key insights into optimizing OET for improved manipulation performance, facilitating more precise and efficient applications in micromanipulation, micro-assembly, microfabrication, and beyond.",

author = "Bingrui Xu and Gong Li and Lixiang Zheng and Wenbo Dong and Pengfei Song and Zongliang Guo and Zonghao Li and Haobing Liu and Ziang Ma and Hainan Xie and Wei Xie and Hang Li and Rongxin Fu and Yao Lu and Na Liu and Huikai Xie and Shuailong Zhang",

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doi = "10.1364/OE.543990",

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T1 - Optimizing light pattern curvature to improve the performance of optoelectronic tweezers in micromanipulation

AU - Xu, Bingrui

AU - Li, Gong

AU - Zheng, Lixiang

AU - Dong, Wenbo

AU - Song, Pengfei

AU - Guo, Zongliang

AU - Li, Zonghao

AU - Liu, Haobing

AU - Ma, Ziang

AU - Xie, Hainan

AU - Xie, Wei

AU - Li, Hang

AU - Fu, Rongxin

AU - Lu, Yao

AU - Liu, Na

AU - Xie, Huikai

AU - Zhang, Shuailong

PY - 2025/1/27

Y1 - 2025/1/27

N2 - Optoelectronic tweezers (OET) offer a versatile, programmable, and contactless method for manipulating microscale objects. While factors like AC voltage and light intensity have been extensively studied, the role of light pattern curvature in the performance of OET manipulation remains underexplored. This study investigates how the curvature of light patterns affects the movement of polystyrene microparticles under negative dielectrophoretic (DEP) forces in an OET system. Experimental results show that as the curvature decreases, the maximum velocity of microparticles first increases to a peak and then gradually decreases. Numerical simulations reveal that light pattern curvature significantly influences the horizontal and vertical DEP forces, altering equilibrium positions and maximum velocities. By defining the optimal curvature (χ, the ratio of microparticle diameter to the inner diameter of the light pattern), we found that microparticles achieve maximum velocity and stability at this optimal ratio regardless of the sizes. These findings offer key insights into optimizing OET for improved manipulation performance, facilitating more precise and efficient applications in micromanipulation, micro-assembly, microfabrication, and beyond.

AB - Optoelectronic tweezers (OET) offer a versatile, programmable, and contactless method for manipulating microscale objects. While factors like AC voltage and light intensity have been extensively studied, the role of light pattern curvature in the performance of OET manipulation remains underexplored. This study investigates how the curvature of light patterns affects the movement of polystyrene microparticles under negative dielectrophoretic (DEP) forces in an OET system. Experimental results show that as the curvature decreases, the maximum velocity of microparticles first increases to a peak and then gradually decreases. Numerical simulations reveal that light pattern curvature significantly influences the horizontal and vertical DEP forces, altering equilibrium positions and maximum velocities. By defining the optimal curvature (χ, the ratio of microparticle diameter to the inner diameter of the light pattern), we found that microparticles achieve maximum velocity and stability at this optimal ratio regardless of the sizes. These findings offer key insights into optimizing OET for improved manipulation performance, facilitating more precise and efficient applications in micromanipulation, micro-assembly, microfabrication, and beyond.

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JO - Optics Express

JF - Optics Express

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Optimizing light pattern curvature to improve the performance of optoelectronic tweezers in micromanipulation

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