Measurement of particle motion in optical tweezers embedded in a Sagnac interferometer
Journal article, 2015

We have constructed a counterpropagating optical tweezers setup embedded in a Sagnac interferometer in order to increase the sensitivity of position tracking for particles in the geometrical optics regime. Enhanced position determination using a Sagnac interferometer has previously been described theoretically by Taylor et al. [Journal of Optics 13, 044014 (2011)] for Rayleigh-regime particles trapped in an antinode of a standing wave. We have extended their theory to a case of arbitrarily-sized particles trapped with orthogonally-polarized counter-propagating beams. The working distance of the setup was sufficiently long to optically induce particle oscillations orthogonally to the axis of the tweezers with an auxiliary laser beam. Using these oscillations as a reference, we have experimentally shown that Sagnac-enhanced back focal plane interferometry is capable of providing an improvement of more than 5 times in the signal-to-background ratio, corresponding to a more than 30-fold improvement of the signal-to-noise ratio. The experimental results obtained are consistent with our theoretical predictions. In the experimental setup, we used a method of optical levitator-assisted liquid droplet delivery in air based on commercial inkjet technology, with a novel method to precisely control the size of droplets.

Author

Ivan Galinskiy

University of Gothenburg

Oscar Isaksson

Chalmers, Applied Physics

University of Gothenburg

Israel Rebolledo Salgado

University of Gothenburg

Mathieu Hautefeuille

Universidad Nacional Autónoma de México

Bernhard Mehlig

University of Gothenburg

Dag Hanstorp

University of Gothenburg

Optics Express

1094-4087 (ISSN) 10944087 (eISSN)

Vol. 23 21 27071-27084

Subject Categories

Physical Sciences

DOI

10.1364/OE.23.027071

More information

Latest update

2/1/2023 1