Beam pointing stabilization of an acousto-optic modulator with thermal control

TL;DR

This paper introduces a thermal management method to stabilize beam pointing in acousto-optic modulators, significantly reducing angular drift and noise without complex servo systems, enhancing stability for optical experiments.

Contribution

The authors demonstrate a thermal control approach using water-cooling to suppress beam drift in AOMs, achieving over 100-fold reduction in angular drift and noise, applicable to various optical setups.

Findings

Angular drift reduced over 100 times with thermal management.

Angular noise suppressed to one-third of non-cooled case.

Refractive index thermal coefficient measured as 16×10⁻⁶ K⁻¹.

Abstract

Diffraction beams generated by an acousto-optic modulator (AOM) are widely used in various optical experiments, some of which require high angular stability with the temporal modulation of optical power. Usually, it is difficult to realize both angular stability and high-power modulation in a passive setup without a servo system of radio-frequency compensation. Here, we present a method to suppress the angular drift and pointing noise only with the thermal management of the AOM crystal. We analyze the dependence of the angular drift on the refractive index variation, and find that the angular drift is very sensitivity to the temperature gradient which could induce the refractive index gradient inside the AOM crystal. It reminds us such angular drift could be significantly suppressed by carefully overlapping the zero temperature gradient area with the position of the acousto-optic interaction zone. We implement a water-cooling setup, and find that the angular drift of an AOM is reduced over 100 times during the thermal transient, and the angular noise is also suppressed to 1/3 of the non-cooled case. It should be emphasized that this thermal control method is a general to suppress the beam drift in both the diffraction and the perpendicular-to-diffraction directions. The refractive index thermal coefficient of tellurium dioxide crystal at 1064 nm determined by this angular drift-temperature model is 16$\times$10$^{-6}$ K$^{-1}$ consistent with previous studies. This thermal control technique provides potential applications for optical trapping and remote sensoring that demand for intensity ramps.