Photon momentum transfer in inhomogeneous dielectric mixtures and induced tractor beams

Qiu, Cheng‐Wei; Ding, Weiqiang; Mahdy, M. R. C.; Gao, Dongliang; Zhang, Tianhang; Cheong, Fook Chiong; Dogariu, Aristide; Wang, Zheng; Lim, Chwee Teck

doi:10.1038/lsa.2015.51

Cited by 83 publications

(61 citation statements)

References 50 publications

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“…This idea has been widely exploited to reverse the force direction due to the environment. Examples include the interface between two media [9][10][11], plasmonic interfaces [12,13], and anisotropic materials [14][15][16]. The pulling force also depends on the material of the scattering object and can be accordingly observed for gain [17], chiral [18,19], and structured [20] particles.…”

Section: Matter-wave Tractor Beamsmentioning

confidence: 99%

Matter-Wave Tractor Beams

Gorlach

Lavrinenko

et al. 2017

Phys. Rev. Lett.

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Section: Matter-wave Tractor Beamsmentioning

confidence: 99%

Matter-Wave Tractor Beams

Gorlach

Lavrinenko

et al. 2017

Phys. Rev. Lett.

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“…In most works so far, optical pulling is based on the scattering force, and long distance pulling is difficult to achieve [32,33,[37][38][39]. In [41], a solenoidal beam was introduced for tractor beam application to move the particle in a helical path.…”

Section: Introductionmentioning

confidence: 99%

“…Previous works regarding optical pulling using tractor beams can be divided into well-defined procedures which mainly are based on: (a) the use of a single nonparaxial Bessel beam [32,33], (b) building a standing wave named the optical conveyor-belt [34,35], (c) employing gain background media [36], (d) generating a negative force by exciting multipoles inside a scatterer [37], (e) placing the particle between two different media to make linearly polarized light [38,39] to act as a tractor beam and (f) introducing the optical conveyor [40] as a travelling wave.…”

Section: Introductionmentioning

confidence: 99%

Tractor beam for fully immersed multiple objects: Long distance pulling, trapping, and rotation with a single optical set‐up

et al. 2015

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In this article, we have theoretically demonstrated the mechanism of an active tractor beam for multiple fully immersed objects with additional abilities to yielding stable long distance levitation, a controlled rotation and a desired 3D trapping. This is demonstrated with a single optical setup by using two coaxial, or even non-coaxial, superimposed higher order monochromatic Bessel beams of reverse helical nature and different frequencies. The superimposed beams can possess periodic intensity variations both along and around the beam-axis due to a difference in longitudinal wave-numbers and beam orders, respectively. The difference in frequencies of the two laser beams makes the intensity pattern to move along and around the beam-axis in a continuous way without manual ramping of phase, which allows for bidirectional movement of completely immersed multiple particles. The condition for increasing or decreasing the dimension of binding regions is also proposed here to manipulate multiple immersed objects of different sizes under dipole approximation.

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“…Optical pulling forces are also reported in optical waveguides, where they emerge owing to the backward 29 or evanescent modes, [30][31][32][33] as well as coupling of the waveguide and ring resonators. 34 The amplification of particle's forward momentum can be also achieved on a dielectric interface (such as airwater) 35,36 and a metallic surface supporting surface plasmon polariton 37 or with the assistance of photothermal effects. [38][39][40][41] In this letter, we propose a robust and distinct configuration to achieve the optical pulling force.…”

mentioning

confidence: 99%

“…According to Ref. 36, the Minkowski stress tensor should be used in the current situation, which is defined as…”

mentioning

confidence: 99%

Mode conversion enables optical pulling force in photonic crystal waveguides

Zhu

Novitsky

Cao

et al. 2017

Applied Physics Letters

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We propose a robust scheme to achieve optical pulling force using the guiding modes supported in a hollow core double-mode photonic crystal waveguide instead of the structured optical beams in free space investigated earlier. The waveguide under consideration supports both the 0th order mode with a larger forward momentum and the 1st order mode with a smaller forward momentum. When the 1st order mode is launched, the scattering by the object inside the waveguide results in the conversion from the 1st order mode to the 0th order mode, thus creating the optical pulling force according to the conservation of linear momentum. We present the quantitative agreement between the results derived from the mode conversion analysis and those from rigorous simulation using the finite-difference in the time-domain numerical method. Importantly, the optical pulling scheme presented here is robust and broadband with naturally occurred lateral equilibriums and has a long manipulation range. Flexibilities of the current configuration make it valuable for the optical force tailoring and optical manipulation operation, especially in microfluidic channel systems.

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Photon momentum transfer in inhomogeneous dielectric mixtures and induced tractor beams

Cited by 83 publications

References 50 publications

Matter-Wave Tractor Beams

Matter-Wave Tractor Beams

Tractor beam for fully immersed multiple objects: Long distance pulling, trapping, and rotation with a single optical set‐up

Mode conversion enables optical pulling force in photonic crystal waveguides

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