Litcius/Paper detail

High-power low-noise 2-GHz femtosecond laser oscillator at 2.4 µm

Ajanta Barh, B. Özgür Alaydin, Jonas Heidrich, Marco Gaulke, Matthias Golling, Christopher R. Phillips, Ursula Keller

2022Optics Express30 citationsDOIOpen Access PDF

Abstract

Femtosecond lasers with high repetition rates are attractive for spectroscopic applications with high sampling rates, high power per comb line, and resolvable lines. However, at long wavelengths beyond 2 µm, current laser sources are either limited to low output power or repetition rates below 1 GHz. Here we present an ultrafast laser oscillator operating with high output power at multi-GHz repetition rate. The laser produces transform-limited 155-fs pulses at a repetition rate of 2 GHz, and an average power of 0.8 W, reaching up to 0.7 mW per comb line at the center wavelength of 2.38 µm. We have achieved this milestone via a Cr 2+ -doped ZnS solid-state laser modelocked with an InGaSb/GaSb SESAM. The laser is stable over several hours of operation. The integrated relative intensity noise is 0.15% rms for [10 Hz, 100 MHz], and the laser becomes shot noise limited (-160 dBc/Hz) at frequencies above 10 MHz. Our timing jitter measurements reveal contributions from pump laser noise and relaxation oscillations, with a timing jitter of 100 fs integrated over [3 kHz, 100 MHz]. These results open up a path towards fast and sensitive spectroscopy directly above 2 µm.

Topics & Concepts

LaserOpticsFemtosecondLaser linewidthMaterials scienceJitterRelative intensity noiseUltrashort pulseLaser power scalingInjection seederPhase noiseFrequency combFiber laserWavelengthMode-lockingLaser pumpingOptoelectronicsOptical parametric oscillatorFar-infrared laserNoise (video)Power (physics)PhysicsUltrafast laser spectroscopyDistributed feedback laserTemporal resolutionSpectroscopySemiconductor laser theoryAdvanced Fiber Laser TechnologiesSolid State Laser TechnologiesPhotorefractive and Nonlinear Optics