Effects of excited-state absorption on self-pulsing in Tm3+-doped fiber lasers

Based on theoretical analysis and numerical simulation, the mechanism of self-pulsing operation of 2-mu m Tm3+-doped fiber lasers is explored. A simplified rate-equation model is proposed to analyze stable operation of Tm3+-doped fiber lasers. It is shown that the continuous-wave (CW) solution does not exist for certain pump intensities when excited-state absorption (ESA) is included. In numerical simulation, four energy-transfer processes are calculated to identify the origin of self-pulsing in Tm3+-doped fiber lasers. The phonon-assisted ESA process H-3(5)-> H-3(4) is identified as the key factor for self-pulsing in Tm3+-doped fiber lasers, which confirms the absence of a CW solution in the theoretical analysis. The numerical simulation gives out a regular pulse train, whose characteristics are in excellent agreement with the experimental results. The impacts of ESA cross section and pump intensity on the self-pulsing characteristics are also investigated. (C) 2010 Optical Society of America