Technique for rapid mass determination of airborne micro-particles based on release and recapture from an optical dipole force trap

TL;DR

This paper introduces a rapid, non-invasive optical method to determine the mass of airborne micro-particles by analyzing their trajectories during release and recapture in an optical trap, achieving high accuracy without vacuum conditions.

Contribution

The paper presents a novel technique combining high-speed imaging and autocorrelation analysis for quick mass measurement of airborne particles in open air.

Findings

Mass measurement uncertainty less than 2%

Applicable to particles around 5×10⁻¹⁴ kg

Measurement time approximately 90 seconds

Abstract

We describe a new method for the rapid determination of the mass of particles confined in a free-space optical dipole-force trap. The technique relies on direct imaging of drop-and-restore experiments without the need for a vacuum environment. In these experiments, the trapping light is rapidly shuttered with an acousto-optic modulator causing the particle to be released from and subsequently recaptured by the trapping force. The trajectories of both the falls and restorations, imaged using a high-speed CMOS sensor, are combined to determine the particle mass. We corroborate these measurements using an analysis of position autocorrelation functions of the trapped particles. We report a statistical uncertainty of less than 2% for masses on the order of $5\times10^{-14}$ kg using a data acquisition time of approximately 90 seconds.