Susan E. Skelton scite author profile

We present the result of an investigation into the optical trapping of spherical microparticles using laser beams with a spatially inhomogeneous polarization direction [cylindrical vector beams (CVBs)]. We perform three-dimensional tracking of the Brownian fluctuations in the position of a trapped particle and extract the trap spring constants. We characterize the trap geometry by the aspect ratio of spring constants in the directions transverse and parallel to the beam propagation direction and evaluate this figure of merit as a function of polarization angle. We show that the additional degree of freedom present in CVBs allows us to control the optical trap strength and geometry by adjusting only the polarization of the trapping beam. Experimental results are compared with a theoretical model of optical trapping using CVBs derived from electromagnetic scattering theory in the T-matrix framework.

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The dark spots of Arago

Fischer¹,

Skelton²,

Leburn³

et al. 2007

Opt. Express

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We explore the diffraction and propagation of Laguerre- Gaussian beams of varying azimuthal index past a circular obstacle both experimentally and numerically. When the beam and obstacle centers are aligned the famous spot of Arago, which arises for zero azimuthal index, is replaced for non-zero azimuthal indices by a dark spot of Arago, a simple consequence of the conserved phase singularity at the beam center. We explore how the dark spot of Arago behaves as the beam and obstacle centers are progressively misaligned, and find that the central dark spot may break into several dark spots of Arago for higher incident azimuthal index beams.

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Trapping and deformation of microbubbles in a dual-beam fibre-optic trap

Skelton¹,

Σεργίδης²,

Memoli³

et al. 2012

J. Opt.

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We present results of numerical calculations to evaluate the performance of a dual-beam fibre-optic trap for low refractive index particles such as ultrasound contrast agent microbubbles. Using a geometrical optics approach, we determine the range of parameters of microbubble size and beam dimensions over which the optical trap is stable and evaluate the trapping forces and spring constants. Additionally, we calculate the optically induced stress profile over the surface of the microbubble and evaluate the resulting deformation of the microbubble using elastic membrane theory. Our results suggest that such an experiment could be a useful tool for quantifying the mechanical properties (elastic modulus) of the shell material of an ultrasound contrast agent microbubble.

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Propagation and diffraction of optical vortices

Fischer

Skelton

Leburn

et al. 2008

Physica C: Superconductivity and its Applications

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Susan E. Skelton

Evanescent wave optical trapping and transport of micro- and nanoparticles on tapered optical fibers

Trapping volume control in optical tweezers using cylindrical vector beams

The dark spots of Arago

Trapping and deformation of microbubbles in a dual-beam fibre-optic trap

Propagation and diffraction of optical vortices

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