Engineering Light‐Driven Rod‐Shaped Micromotors for Exhibiting Controlled and Tunable Multimode Swimming

Panda, Suvendu Kumar; Debata, Srikanta; Andia, Kanhu Charan; Das, Sayan; Singh, Dhruv Pratap

doi:10.1002/adom.202400590

Advanced Optical Materials

2024

DOI: 10.1002/adom.202400590

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Engineering Light‐Driven Rod‐Shaped Micromotors for Exhibiting Controlled and Tunable Multimode Swimming

Suvendu Kumar Panda,

Srikanta Debata,

Kanhu Charan Andia

et al.

Abstract: The recent era of research has been focused on attaining precise and adjustable propulsion modes in micromotors, with remarkable implications in microrobotics and active‐matter applications. This study introduces a novel design of rod‐shaped micromotors featuring light‐driven motion and wavelength‐dependent multimodal swimming behavior. The micromotors are fabricated through the Glancing Angle Deposition (GLAD) technique, which offers a flexible approach to engineering surfaces by incorporating photocatalytic … Show more

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Cited by 3 publications

References 46 publications

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Enzymatic bimetallic Cu-Ni micromotor sensor for xanthine detection

Muslu Yilmaz,

Dag,

Killioglu

et al. 2025

Journal of Food Engineering

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Enzymatic bimetallic Cu-Ni micromotor sensor for xanthine detection

Muslu Yilmaz,

Dag,

Killioglu

et al. 2025

Journal of Food Engineering

View full text Add to dashboard Cite

Engineering light-driven micromotors with fluorescent dye coatings for easy detection and tracking

Debata,

Panda,

Singh

2024

Nanoscale

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Orbital motion of gold heterodimer driven by optical force of circularly polarized light and reactive drag of medium

Ku,

Yang,

Kuo

et al. 2024

Journal of Mechanics

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This theoretical study explores the two-dimensional orbital motion of an optically bound heterodimer consisting of two gold nanoparticles (NPs) of different sizes, driven by circularly polarized (CP) light. Although a CP light possesses only spin angular momentum without orbital angular momentum, it can still induce orbital revolution in the plasmonic heterodimer. This phenomenon arises from the interaction between the optical force and torque generated by the CP light and the reactive drag force and torque from the surrounding medium. We calculate the optical forces acting on each NP by analyzing the Maxwell stress tensor at their surfaces, and we account for the reactive drag force using Stokes’ law. These forces are used to simulate the trajectories of the NPs through dynamic equations of motion. Our results demonstrate that, regardless of the initial conditions of the two NPs, they will become optically bound together, exhibiting rigid-body translation and rotation. Notably, the center of mass of the heterodimer undergoes an orbital revolution around a fixed point eventually. The CP light-manipulated heterodimer behaves like a boomerang, acting as a spinning rotor on a circular path. The heterodimer's orbital radius and direction of revolution are influenced by the size disparity between the two NPs. Additionally, each NP experiences spin motion, with the spin direction determined by the handedness of the CP light. The optically bound gold heterodimer functions as a light-driven microrotor, with potential applications in microfluidic channels. These findings offer valuable insights into the optomechanical manipulation of non-monodisperse NP clusters using CP light.

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Engineering Light‐Driven Rod‐Shaped Micromotors for Exhibiting Controlled and Tunable Multimode Swimming

Cited by 3 publications

References 46 publications

Enzymatic bimetallic Cu-Ni micromotor sensor for xanthine detection

Enzymatic bimetallic Cu-Ni micromotor sensor for xanthine detection

Engineering light-driven micromotors with fluorescent dye coatings for easy detection and tracking

Orbital motion of gold heterodimer driven by optical force of circularly polarized light and reactive drag of medium

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