Quasi Monolithic Fiber Collimators

TL;DR

This paper introduces a simplified quasi-monolithic fiber collimator design that reduces complexity and improves stability for space interferometry applications, matching or exceeding commercial standards.

Contribution

The authors present a novel, easier-to-fabricate fiber collimator that combines alignment and active mode control, enhancing stability and performance in thermal-sensitive environments.

Findings

Achieved well-collimated Gaussian beam output.

Demonstrated beam-pointing stability suitable for space applications.

Matched or exceeded performance of commercial fiber collimators.

Abstract

Interferometric displacement measurements, especially in space interferometry applications, face challenges from thermal expansion. Bonded assemblies of ultra-low thermal expansion glass-ceramics offer a solution; however, transitioning from light transport in fibers to free beam propagation presents a notable challenge. These experiments often need an interface to convert between laser beams propagating through fiber optics into a well-defined free beam and vice versa. These interfaces must also be made of rigid glass pieces that can be bonded to a glass base plate. Current designs for these fiber collimators, often called fiber injector optical sub-assemblies, require multiple glass parts fabricated to very tight tolerances and assembled with special alignment tools. We present a simplified quasi-monolithic fiber collimator that can generate a well-collimated laser beam. The complexity and tolerances of bonding are reduced by combining the alignment of the fiber mode to the imaging lens in one step with active mode control: the welding of the fiber to the glass body. We produce several of these designs and test that the desired light field is achieved, its profile is described as a Gaussian beam, and the beam-pointing stability is acceptable for such a piece. In each case, they perform at least as well as a standard commercial fiber collimator. These Quasi Monolithic Fiber Collimators offer a promising and easy-to-implement solution to convert between free beam and fiber-coupled lasers in experiments sensitive to long term thermal drifts.