Attonewton force detection using microspheres in a dual-beam optical trap in high vacuum

TL;DR

This paper demonstrates the use of laser-cooled silica microspheres in a dual-beam optical trap for attonewton force detection in high vacuum, enabling precise measurements for fundamental physics experiments.

Contribution

It introduces a novel setup with long trap lifetimes and tunable parameters, establishing a new platform for high-precision force sensing in vacuum environments.

Findings

Trap lifetimes exceeding several days

Attonewton force detection capability

Calibration with charged and neutral beads

Abstract

We describe the implementation of laser-cooled silica microspheres as force sensors in a dual-beam optical dipole trap in high vacuum. Using this system we have demonstrated trap lifetimes exceeding several days, attonewton force detection capability, and wide tunability in trapping and cooling parameters. Measurements have been performed with charged and neutral beads to calibrate the sensitivity of the detector. This work establishes the suitability of dual beam optical dipole traps for precision force measurement in high vacuum with long averaging times, and enables future applications including the study of gravitational inverse square law violations at short range, Casimir forces, acceleration sensing, and quantum opto-mechanics.