A research group led by Prof. Yao Baoli and Dr. Xu Xiaohao from Xi’an Institute of Optics and Precision Mechanics (XIOPM) of the Chinese Academy of Sciences have revealed a full-gray optical trap in structured light, which is able to capture nanoparticles but appears at the region where the intensity is neither maximized nor minimized. The study is published in Physical Review A.
The optical trap is one of the greatest findings in optics and photonics. Since the pioneering work by Arthur Ashkin in the 1970s, the optical trap has been employed in a broad range of applications in life sciences, physics, and engineering. Akin to its thermal and acoustic counterparts, this trap is typically either bright or dark, located at the field intensity maxima or minima.
In this study, researchers developed a high-order multipole model for gradient forces based on multipole expansion theory. Through immersing the Si particles in the structured light with a petal-shaped field, they found that the high-order multipole gradient forces can trap Si particles at the optical intensity, which is neither maximized nor minimized.
Therefore, researchers demonstrated that there may exist an intermediate trapping state, which is referred to as the full-gray optical trapping. The origin of this novel trap can be traced back to the nonlocal pondermotive effect of the optical intensity gradient, which is achieved through the excitation of higher-order multipole Mie resonances in nanoparticles.
The full-gray trap underscores the impact of Mie responses on optomechanics, and will facilitate the development of nanoparticle cooling, patterning and ultra-sensitive sorting in the future.
More information:
Yanan Zhang et al, Full-gray optical trapping by high-order multipole-resonant gradient forces in structured light, Physical Review A (2024). DOI: 10.1103/PhysRevA.110.063517
Provided by
Chinese Academy of Sciences
Citation:
Researchers reveal full-gray optical trap in structured light (2024, December 24)
