Noise-like pulse laser source with ultrabroadband tunability and coherence-limited sub-structure

TL;DR

This paper presents a tunable noise-like pulse laser source with ultrabroadband spectral width, low temporal coherence, and high brightness, suitable for high-contrast, speckle-free imaging applications.

Contribution

It demonstrates a novel approach using a Tm doped fiber laser operating in a noise-like pulse regime with simultaneous time and frequency diversity.

Findings

Spectral widths from 13.8 nm to 18.8 nm achieved.

Output power varies between 63.3 mW and 213 mW.

Coherence time of approximately 100 fs in high-gain regime.

Abstract

High brightness and low coherence laser sources with wideband tunability are essential for many full-field imaging applications aiming for high contrast and speckle free performance. However, this combination of parameters is challenging to achieve. The current solutions focus on decreasing spatial coherence or generation of time-varying speckle patterns, while suppression of temporal coherence typically compromises brightness. Here we demonstrate a wideband pulsed laser source with low temporal coherence and the absence of phase correlation between pulses as an alternative approach with simultaneous time and frequency diversity. The full gain spectrum of a Tm doped fiber laser (1650 nm 2000 nm) is operated in a tunable noise like pulse regime, which by nature is composed of countless structured elementary events with uncorrelated phases randomly varying from bunch to bunch. The measured spectral widths range from 13.8 nm to 18.8 nm, while the average output power varies between 63.3 mW and 213 mW. Numerical simulations reveal that temporal coherence decreases significantly with increasing optical gain, dropping from near unity at low gain to approximately 0.2 at high gain. The startup dynamics of the noise like pulse laser are experimentally studied using the dispersive Fourier transformation (DFT) method. Based on single shot spectra and frequency resolved optical gating traces, the coherence properties of the laser are further analyzed by calculating the mutual coherence function and cross-spectral density. The noise like pulse laser exhibits a coherence time of approximately 100 fs and an average pulse burst duration of about 40 ps in the high-gain regime.