Development Of Thulium Fiber Lasers For High Average Power And High Peak Power Operation

Sims, Robert

01 January 2013

High power thulium fiber lasers are useful for a number of applications in both continuous-wave and pulsed operating regimes. The use of thulium as a dopant has recently gained interest due to its large bandwidth, possibility of high efficiency, possibility of high power and long wavelength ~1.8 – 2.1 μm. The longer emission wavelength of Tm-doped fiber lasers compared to Yb- and/or Er-doped fiber lasers creates the possibility for higher peak power operation due to the larger nonlinear thresholds and reduced nonlinear phase accumulation. One primary interest in Tm-doped fiber lasers has been to scale to high average powers; however, the thermal and mechanical constraints of the fiber limit the average power out of a single-fiber aperture. One method to overcome the constraints of a single laser aperture is to spectrally combine the output from multiple lasers operating with different wavelengths into a single beam. In this thesis, results will be presented on the development of three polarized 100 W level laser systems that were wavelength stabilized for SBC. In addition to the development of the laser channels, the beams were combined using bandpass filters to achieve a single near diffraction-limited output. Concurrently, with the development of high average power systems there is an increasing interest in femotosecond pulse generation and amplification using Tm- doped fiber lasers. High peak power sources operating near 2 µm have the potential to be efficient pump sources to generate mid-infrared light through supercontinuum generation or optical parametric oscillators. This thesis focuses on the development of a laser system utilizing chirped pulse amplification (CPA) to achieve record level energies and peak powers for ultrashort pulses in Tm-doped fiber. iv A mode-locked oscillator was built to generate femtosecond pulses operating with pJ energy. Pulses generated in the mode-locked oscillator were limited to low energies and contained spectral modulation due to the mode-locking mechanism, therefore, a Raman-soliton self-frequency shift (Raman-SSFS) amplifier was built to amplify pulses, decrease the pulse duration, and spectrally clean pulses. These pulses were amplified using chirped pulse amplification (CPA) in which, limiting factors for amplification were examined and a high peak power system was built. The primary limiting factors of CPA in fibers include the nonlinear phase accumulation, primarily through self-phase modulation (SPM), and gain narrowing. Gain narrowing was examined by temporally stretching pulses in a highly nonlinear fiber that both stretched the pulse duration and broadened the spectrum. A high peak power CPA system amplified pulses to 1 µJ energy with 300 fs compressed pulses, corresponding to a peak power >3 MW. High peak power pulses were coupled into highly nonlinear fibers to generate supercontinuum

Thulium fiber laser

chirped pulse amplification

spectral beam combining

Electromagnetics and Photonics

Optics

Dense spectral beam combining with volume bragg gratings in photo-thermo-refractive glass

Andrusyak, Oleksiy G.

11 March 2009

En utilisant la combinaison spectrale de faisceaux, des faisceaux provenant de plusieurs lasers opérant à des longueurs d'onde différentes sont combinés en un seul faisceau avec une divergence proche de la limite de diffraction. Cette thèse présente des résultats expérimentaux de combinaison spectrale de faisceaux avec une grande densité spectrale dans deux régions spectrales d'intérêt (1064 et 1550 nm). Un système laser avec une puissance de sortie de l'ordre du kW et une divergence du faisceau combiné proche de la limite de diffraction est démontré. Le système combine cinq fibres lasers dopées Ytterbium polarisées de façon aléatoire avec une séparation spectrale de 0.5 nm en utilisant des réseaux de Bragg volumiques réfléchissants présentant une largeur spectrale étroite et une efficacité de combinaison absolue supérieure à 90%. La projection d'un tel système pour des puissances de sortie de l'ordre de 100 kW est discutée. / Using spectral beam combining (SBC), beams from an array of lasers with each element operated at a different wavelength are combined into a single near-diffraction-limited beam with the same aperture using dispersive optical elements. In this thesis, experimental results of SBC with high spectral density of combined channels in two spectral regions of interest (1064 and 1550 nm) are reported. A laser system with kW-level output power and near-diffraction-limited divergence of spectrally-combined output beam is demonstrated. The system combines five randomly-polarized Yb-doped fiber lasers with 0.5 nm spectral separation in central wavelengths with absolute efficiency of combining > 90% using narrow-band reflecting volume Bragg gratings recorded in photo-thermo-refractive glass. Scaling of such systems to 100 kW power level is discussed.

Combinaison spectrale

Réseaux de Bragg volumiques

Verre photo-thermo-réfractif

Fibres lasers

Spectral beam combining

Volume Bragg gratings

Photo-thermo-refractive glass