Influence of Gain Saturation Effect on Transverse Mode Instability Considering Four-Wave Mixing

Abstract: Transverse mode instability (TMI) has been recognized as onse of the primary limiting factors for the average power scaling of high-brightness fiber lasers. In this work, a static model of the TMI effect based on stimulated thermal Rayleigh scattering (STRS) is established while considering the four-wave mixing (FWM) effect. The focus of the model is to theoretically investigate the TMI phenomenon and threshold power dominated by FWM. The gain saturation effect and fiber laser system parameters, such as seed p… Show more

“…( ) (0, ) exp( ( )) where C 21 is the nonlinear coupling coefficient [44], T k ,  , 0 C , and  are the thermal-optical coefficient, density silica, specific heat capacity, and thermal conductivity of silica, respectively. 0 g is the small-signal gain, 1(2) ( , ) r  is the normalized electric field distribution of LP 01 (11) mode.…”

Transverse mode instability mitigation in a high-power confined-doped fiber amplifier with good beam quality through seed laser control

“…( ) (0, ) exp( ( )) where C 21 is the nonlinear coupling coefficient [44], T k ,  , 0 C , and  are the thermal-optical coefficient, density silica, specific heat capacity, and thermal conductivity of silica, respectively. 0 g is the small-signal gain, 1(2) ( , ) r  is the normalized electric field distribution of LP 01 (11) mode.…”

Transverse mode instability mitigation in a high-power confined-doped fiber amplifier with good beam quality through seed laser control

Mitigation of TMI in an 8 kW tandem pumped fiber amplifier enabled by inter-mode gain competition mechanism through bending control