Giant resonant light forces in microspherical photonics

Abstract: Resonant light pressure effects can open new degrees of freedom in optical manipulation with microparticles, but they have been traditionally considered as relatively subtle effects. Using a simplified two-dimensional model of surface electromagnetic waves evanescently coupled to whispering gallery modes (WGMs) in transparent circular cavities, we show that under resonant conditions the peaks of the optical forces can approach theoretical limits imposed by the momentum conservation law on totally absorbing par… Show more

“…2(a), and coupled the fiber output to a photodiode connected to an oscilloscope. In a weak coupling regime, which is usually the case for polystyrene spheres in water, 22,37 the minimal values of transmitted signal can be achieved under contact conditions between the sphere and taper. Under these conditions, the intensity measured by photodiode can be used as a qualitative measure of the gap separating the microsphere from the taper.…”

“…Under resonant conditions (Δλ =0), we observed that the spheres tend to be optically attracted to the fiber. However, at very short separations the sphere is likely to be electrostatically repulsed from the fiber, 22 thus forming a potential minimum at a certain nanometer-scale distance from the taper required for stable propulsion. Once radially trapped, the resonant …”

“…We observed that some of large spheres of 15-20 μm diameters can be optically propelled at an extraordinary high velocity. [21][22][23][24] Giant optical propulsion velocities of ~450 μm/s were recorded for some of 20 μm polystyrene a microspheres in water with guided powers of only 43 mW. 22 These velocities were more than an order of magnitude higher than that observed in previous studies.…”

“…[21][22][23][24] Giant optical propulsion velocities of ~450 μm/s were recorded for some of 20 μm polystyrene a microspheres in water with guided powers of only 43 mW. 22 These velocities were more than an order of magnitude higher than that observed in previous studies. [6][7][8][9][10][11][12] Theoretically, we showed that the peak force can approach the level that an absorbing particle would experience based on the total momentum transfer from light to microparticle.…”

“…[6][7][8][9][10][11][12] Theoretically, we showed that the peak force can approach the level that an absorbing particle would experience based on the total momentum transfer from light to microparticle. 22,25 These experiments were carried out with an assembly of microspheres interacting with the tapered fiber. In these experiments, the laser emission line has been fixed, and different spheres from the suspension have been trapped and propelled along the taper.…”

Spectral control and temporal properties of resonant optical propulsion of dielectric microspheres in evanescent fiber couplers

“…2(a), and coupled the fiber output to a photodiode connected to an oscilloscope. In a weak coupling regime, which is usually the case for polystyrene spheres in water, 22,37 the minimal values of transmitted signal can be achieved under contact conditions between the sphere and taper. Under these conditions, the intensity measured by photodiode can be used as a qualitative measure of the gap separating the microsphere from the taper.…”

“…Under resonant conditions (Δλ =0), we observed that the spheres tend to be optically attracted to the fiber. However, at very short separations the sphere is likely to be electrostatically repulsed from the fiber, 22 thus forming a potential minimum at a certain nanometer-scale distance from the taper required for stable propulsion. Once radially trapped, the resonant …”

“…We observed that some of large spheres of 15-20 μm diameters can be optically propelled at an extraordinary high velocity. [21][22][23][24] Giant optical propulsion velocities of ~450 μm/s were recorded for some of 20 μm polystyrene a microspheres in water with guided powers of only 43 mW. 22 These velocities were more than an order of magnitude higher than that observed in previous studies.…”

“…[21][22][23][24] Giant optical propulsion velocities of ~450 μm/s were recorded for some of 20 μm polystyrene a microspheres in water with guided powers of only 43 mW. 22 These velocities were more than an order of magnitude higher than that observed in previous studies. [6][7][8][9][10][11][12] Theoretically, we showed that the peak force can approach the level that an absorbing particle would experience based on the total momentum transfer from light to microparticle.…”

“…[6][7][8][9][10][11][12] Theoretically, we showed that the peak force can approach the level that an absorbing particle would experience based on the total momentum transfer from light to microparticle. 22,25 These experiments were carried out with an assembly of microspheres interacting with the tapered fiber. In these experiments, the laser emission line has been fixed, and different spheres from the suspension have been trapped and propelled along the taper.…”

Spectral control and temporal properties of resonant optical propulsion of dielectric microspheres in evanescent fiber couplers

Switching of Giant Lateral Force on Sub‐10 nm Particle Using Phase‐Change Nanoantenna

Binding of Resonant Dielectric Particles to Metal Surfaces Using Plasmons