M. M. van Leest, F. Bernal Arango, J. Caro
We propose a novel design of the dual-waveguide trap for trapping and Raman identification of microscopic particles and biological objects in a fluid. The device is based on two embedded Si3N4 waveguides launching counterpropagating beams into the fluidic channel of a lab-on-chip. For waveguides with a square cross-section of 1 μm2, a 5 μm gap between them and a 785 nm operation wavelength, we perform finite-difference time-domain simulations of the beam profiles and the trapping forces acting on polystyrene beads (diameter 0.2-1.4 μm). The forces reach values up to 16 pN/W for a bead diameter of 1.4 μm, indicating that the trap is very suitable for trapping of particles in a fluidic environment. This is confirmed by the trapping potentials deduced from the force curves. The design of waveguides and chip is completely compatible with glass-based microfluidic technology, thus enabling mass production and widespead application, contrary to previous approaches.
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