报道了一种基于MgO:APLN实现1.57μm和3.84μm跨周期参量光连续输出的内腔抽运多光参量振荡器.采用1064nm谐振腔与多光参量振荡腔折叠型复合结构,综合考虑高功率抽运下谐振腔的热稳定性及多光参量振荡过程的光斑模式匹配,通过对两个子腔谐振结构的数值模拟分析,确定了最佳腔型参数.在此基础上,进一步研究了谐振参量光透过率对振荡阈值、抽运光下转换效率、输出功率稳定性的影响,最终实现了3.13W的1.57μm和0.85W的3.84μm参量光输出,对应斜效率为6.8%和1.9%,输出功率稳定性分别达到了1.8%和3%.
Continuous-wave (CW) coherent sources emitting two wavelengths of 1.57 μm and 3.84μm have aroused much interest of scientists due to their many applications such as military multiband composite guidance, remote monitoring of the special environment, etc. Quasi-phase matching (QPM) optical parametric oscillator (OPO) device with periodically inverted structure of nonlinear coefficient can implement an efficient and wavelength conversion at arbitrary wavelength in the transparent range of the QPM material Nowadays, using MgO:PPLN for QPM, various MgO:PPLN-OPOs pumped by conventional 1.06 μm laser source can produce 1.57μm and 3.84 μm laser and also achieve good results. But as a result of the limitation of momentum conservation condition and periodically poled structure, 1.57 μm and 3.84 μm laser can only meet a single band. To obtain the two-wavelength laser output at the same time, the MgO:PPLN-OPO could not be applied. In this paper, a CW 1.57 μm and 3.84 μm intra-cavity multiple optical parametric oscillator based on MgO:APLN is reported. The cross period parameter light is obtained by using a folded type doubly cavity which consists of 1064 nm resonator and multiple optical parametric oscillator. Considering both its thermal stability under high power pump and the light spot mode matching of multiple optical parametric oscillation process, through numerical simulation and theoretical analysis of two sub cavities, the optimum parameters of the cavity structure are determined. On this basis, the influences of output coupler transmittance on oscillation threshold, the down-conversion efficiency, output power stability are investigated in experiment. With T = 10% at 1.47 μm and 3.3 μm output coupler used, the maximum output powers of 3.13 W at 1.57 μm and 0.85 W at 3.84 μm are obtained, corresponding to slope efficiencies of 6.8% and 1.9%, respectively. The power stabilities are better than 1.8% and 3% at the maximum output power in half an hour. The experimental results show that