Photonic tractor beams: a review

Ding, Wei; Zhu, Tongtong; Zhou, Lei‐Ming; Qiu, Cheng‐Wei

doi:10.1117/1.ap.1.2.024001

Cited by 66 publications

(46 citation statements)

References 122 publications

(247 reference statements)

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“…In recent years, laser [187][188][189][190][191] and plasmonic 64,66,192 traps have demonstrated unexpected phenomena that have drawn considerable interest. These unique properties are interesting and important for developments in assembly, crystallization and organization of micro-and nanostructures.…”

Section: Unique Phenomena In Plasmonic Tweezersmentioning

confidence: 99%

“…The pulling force acts in the direction opposite to the optical wave propagation 191 by either structuring the incident field [193][194][195] or modifying the surroundings of the manipulated object 196,197 . For specific plasmonic cases, Shalin et al verified that directional excitation of SPPs can enhance the linear momentum of scattered light and induce a considerable negative force on a particle, as shown in Fig.…”

Section: Pulling Phenomenamentioning

confidence: 99%

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Plasmonic tweezers: for nanoscale optical trapping and beyond

et al. 2021

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Optical tweezers and associated manipulation tools in the far field have had a major impact on scientific and engineering research by offering precise manipulation of small objects. More recently, the possibility of performing manipulation with surface plasmons has opened opportunities not feasible with conventional far-field optical methods. The use of surface plasmon techniques enables excitation of hotspots much smaller than the free-space wavelength; with this confinement, the plasmonic field facilitates trapping of various nanostructures and materials with higher precision. The successful manipulation of small particles has fostered numerous and expanding applications. In this paper, we review the principles of and developments in plasmonic tweezers techniques, including both nanostructure-assisted platforms and structureless systems. Construction methods and evaluation criteria of the techniques are presented, aiming to provide a guide for the design and optimization of the systems. The most common novel applications of plasmonic tweezers, namely, sorting and transport, sensing and imaging, and especially those in a biological context, are critically discussed. Finally, we consider the future of the development and new potential applications of this technique and discuss prospects for its impact on science.

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Section: Unique Phenomena In Plasmonic Tweezersmentioning

confidence: 99%

Section: Pulling Phenomenamentioning

confidence: 99%

Plasmonic tweezers: for nanoscale optical trapping and beyond

et al. 2021

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“…In contrast to the above discussed optical tweezers, where the optical force exerted on the micro-and nanoparticles produces an acceleration along the same direction of the photon flow in an optical tractor beam, the optical forces drag small microparticles against this flow, i.e., toward the photons source. 28,[176][177][178][179][180] In contrast to a conveyor belt that requires gradient forces to pull microparticles toward the source of the photons, 118 the pulling forces of a tractor beam originate from a momentum conservation law. In essence, when the forward scattered light is more collimated than the incident light, and if the backward scattering is weak enough, the momentum conservation law predicts the existence of a pulling force.…”

Section: Optical Trapping With Tractor Beamsmentioning

confidence: 99%

Optical trapping with structured light: a review

et al. 2021

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Optical trapping describes the interaction between light and matter to manipulate micro-objects through momentum transfer. In the case of 3D trapping with a single beam, this is termed optical tweezers. Optical tweezers are a powerful and noninvasive tool for manipulating small objects, and have become indispensable in many fields, including physics, biology, soft condensed matter, among others. In the early days, optical trapping was typically accomplished with a single Gaussian beam. In recent years, we have witnessed rapid progress in the use of structured light beams with customized phase, amplitude, and polarization in optical trapping. Unusual beam properties, such as phase singularities on-axis and propagation invariant nature, have opened up novel capabilities to the study of micromanipulation in liquid, air, and vacuum. We summarize the recent advances in the field of optical trapping using structured light beams.

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“…The counterintuitive optical pulling force draws increasing attention because of its attractive physical mechanism and potential applications. [ 74 ] In 2011, Chen et al theoretically demonstrated that microparticles can be accelerated against the photon flow and named this phenomenon as “optical pulling.” [ 29 ] To verify the optical pulling concept experimentally, Brzobohaty et al designed an optical setup using two Gaussian laser beams focused through objective lenses or using a single beam that was retro‐reflected from a mirror ( Figure a‐I). [ 28 ] Because of the action‐and‐reaction mechanism, the light‐matter momentum transfer leads to backward motion of the objects when the photons mainly propagate against the direction of wave vector k = k 1 + k 2 (Figure 3a‐II).…”

Section: Physical Models Of Optical Forcesmentioning

confidence: 99%

Optical Forces: From Fundamental to Biological Applications

et al. 2020

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Optical forces, generally arising from changes of field gradients or linear momentum carried by photons, form the basis for optical trapping and manipulation. Advances in optical forces help to reveal the nature of light–matter interactions, giving answers to a wide range of questions and solving problems across various disciplines, and are still yielding new insights in many exciting sciences, particularly in the fields of biological technology, material applications, and quantum sciences. This review focuses on recent advances in optical forces, ranging from fundamentals to applications for biological exploration. First, the basics of different types of optical forces with new light–matter interaction mechanisms and near‐field techniques for optical force generation beyond the diffraction limit with nanometer accuracy are described. Optical forces for biological applications from in vitro to in vivo are then reviewed. Applications from individual manipulation to multiple assembly into functional biophotonic probes and soft‐matter superstructures are discussed. At the end future directions for application of optical forces for biological exploration are provided.

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Photonic tractor beams: a review

Cited by 66 publications

References 122 publications

Plasmonic tweezers: for nanoscale optical trapping and beyond

Plasmonic tweezers: for nanoscale optical trapping and beyond

Optical trapping with structured light: a review

Optical Forces: From Fundamental to Biological Applications

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