Author Affiliations
Abstract
1 College of Advanced Interdisciplinary Studies, National University of Defense Technology, Changsha 410073, China
2 School of Information and Communications, National University of Defense Technology, Wuhan 430035, China
3 Nanhu Laser Laboratory, National University of Defense Technology, Changsha 410073, China
4 Hunan Provincial Key Laboratory of High Energy Laser Technology, National University of Defense Technology, Changsha 410073, China
High-power ultrafast laser amplification based on a non-polarization maintaining fiber chirped pulse amplifier is demonstrated. The active polarization control technology based on the root-mean-square propagation (RMS-prop) algorithm is employed to guarantee a linearly polarized output from the system. A maximum output power of 402.3 W at a repetition rate of 80 MHz is realized with a polarization extinction ratio (PER) of > 11.4 dB. In addition, the reliable operation of the system is verified by examining the stability and noise properties of the amplified laser. The M2 factor of the laser beam at the highest output power is measured to be less than 1.15, indicating a diffraction-limited beam quality. Finally, the amplified laser pulse is temporally compressed to 755 fs with a highest average power of 273.8 W. This is the first time, to the best of our knowledge, that the active polarization control technology was introduced into the high-power ultrafast fiber amplifier.
active polarization control root-mean-square propagation algorithm linearly polarized laser chirped pulse amplification femtosecond laser fiber laser Chinese Optics Letters
2024, 22(4): 041403
运用经典系综方法研究了线偏振激光场和双色反旋圆偏振激光场中CO2分子非序列双电离的产量。结果表明:在激光强度较高的区域,双色反旋圆偏振激光场下CO2分子非序列双电离的产量高于线偏振激光场;在激光强度较低的区域,结果则刚好相反。这是因为当激光强度较低时,CO2非序列双电离产量的主要影响因素是抑制势垒,当激光强度较高时,由于抑制势垒发生扭曲,其产量主要受激光场结构的影响。
原子与分子物理学 非序列双电离 双色反旋圆偏振激光场 线偏振激光场 分子 产量 光学学报
2023, 43(20): 2002001
1 南京邮电大学 贝尔英才学院, 南京 210023
2 南京邮电大学 通信与信息工程学院, 南京 210023
3 南京邮电大学 理学院, 南京 210023
为了探究高能电子辐射与其初始位置间的关系, 依据拉格朗日方程构建了单个高能电子与高斯激光脉冲相互作用发生散射的模型, 并采用数值模拟的方法通过MATLAB获得了电子运动轨迹及散射光的空间辐射特性, 具体分析讨论了电子初始位置对空间能量辐射的影响。结果表明, 初始状态静止的高能电子经与线偏振紧聚焦强激光相互作用, 其在平面内沿+z方向先做振荡运动, 然后沿直线行进; 最大辐射能量及其辐射方向均受到电子初始位置的较大影响, 前者随电子初始位置朝z轴正向移动出现极大值, 而后者在方位角恒定的同时极角逐渐减小并最终稳定; 全空间最大辐射能量在电子初始位置位于(0,0,-7λ0)(λ0为激光波长)、极角和方位角分别为23.5°和180°时取得。此结果说明通过合理设置电子的初始位置可以获得强度尽可能大的辐射。
激光光学 空间辐射分布 数值模拟 线偏振激光 非线性汤姆逊散射 laser optics spatial radiation distribution numerical simulation linearly polarized laser nonlinear Thomson scattering
Author Affiliations
Abstract
College of Optoelectronic Science and Engineering, National University of Defense Technology, Changsha 410073, China
In this paper, we experimentally investigated the extreme frequency shift in high-power Raman fiber laser (RFL). The RFL was developed by using a pair of fiber Bragg gratings with fixed and matched central wavelength (1120 nm) combined with a piece of 31-m-long polarization maintaining (PM) passive fiber adopted as Raman gain medium. The pump source was a homemade high-power, linearly polarized (LP) wavelength-tunable master oscillator power amplifier (MOPA) source with ${\sim}25~\text{nm}$ tunable working range (1055–1080 nm). High-power and high-efficiency RFL with extreme frequency shift between the pump and Stokes light was explored. It is found that frequency shift located within 10.6 THz and 15.2 THz can ensure efficient Raman lasing, where the conversion efficiency is more than 95% of the maximal value, 71.3%. In addition, a maximum output power of 147.1 W was obtained with an optical efficiency of 71.3%, which is the highest power ever reported in LP RFLs to the best of our knowledge.
linearly polarized laser Raman fiber laser Raman gain spectrum. High Power Laser Science and Engineering
2018, 6(2): 02000e28
1 井冈山大学 数理学院, 江西 吉安 343009
2 井冈山大学 图书馆, 江西 吉安 343009
基于超强线极化激光在正负电子对(e-p)等离子体中的传播方程,讨论了相互作用过程中的成丝不稳定性。得到了电磁波的非线性色散关系和不稳定性增长率,并讨论了传播过程中激光强度和等离子体温度对成丝不稳定性的影响。结果表明,成丝不稳定性的强弱主要由相互作用的非线性效应与受有质动力作用后等离子体密度的减小之间的竞争所决定。
e-p等离子体 线极化激光 波动方程 色散关系 成丝不稳定性 electron-positron plasmas linearly polarized laser wave equation dispersion relation filamentation instability 强激光与粒子束
2014, 26(1): 012005
1 云南大学物理科学技术学院物理系, 云南 昆明 650091
2 中国科学院上海光学精密机械研究所上海市全固态激光器与应用技术重点实验室, 上海 201800
报道了一种全光纤结构的线偏振掺镱光纤激光器,采用快慢轴交叉对准的光纤光栅为腔镜,实现了线偏振激光的振荡输出。以975 nm的半导体激光器为抽运源,在抽运功率为50 W时,获得了30.2 W线偏振激光输出,光光转换效率60%,偏振消光比(PER)优于22 dB。研究了输出激光的光谱控制特性,通过对光纤光栅的温度控制,实现了输出激光中心波长和半峰全宽(FWHM)的精确调节。
激光器 光纤布拉格光栅 线偏振激光 全光纤结构 中国激光
2013, 40(s1): s102006
1 井冈山大学 数理学院, 江西 吉安 343009
2 井冈山大学 图书馆, 江西 吉安 343009
基于包含辐射阻尼效应的电子运动方程,通过坐标变换,分析了圆极化和线极化超强激光在等离子体中传播时,辐射阻尼效应对电子运动的影响。结果表明:两种极化情况下,辐射阻尼效应都随等离子体密度的增大而增强;在圆极化激光中,激光强度在1023~1026 W/cm2范围(对应于不同的等离子体密度)时,辐射阻尼效应将对电子的运动产生显著的反作用,而对于线极化激光,只有当激光强度远大于极限光强时,辐射阻尼效应才对电子的运动有明显的作用。
辐射阻尼效应 超强激光 等离子体 洛伦兹变换 线极化激光 圆极化激光 radiation damping effects ultra-intense laser plasmas Lorentz transformation linearly polarized laser circularly polarization laser
哈尔滨工业大学光电子技术研究所可调谐激光技术国家级重点实验室,哈尔滨,150001
以类硼氮系统为例,对基于光场感生电离线偏振激励低密度等离子体的电离参数进行了研究,由此确定了对于适合复合机制的类硼氮45.21 nm的产生,其最佳激励激光强度为5×1015 W/cm2,并对计算结果进行了分析.
线偏振光场 电离参数 类硼氮系统
哈尔滨工业大学可调谐激光技术国家级重点实验室,哈尔滨 150001
在准静态隧道电离理论模型和准经典阈上电离理论模型的基础上,建立了一个描述线偏振光场电离电子能量分布的简单模型,推导出了既易于理解又相对简单适用的描述线偏振光场的电子能量分布函数解析表达式.数值计算了类硼氮系统的电子能量分布曲线,并对计算结果进行了分析.最后与现有实验结果进行比较,给出其适用范围.
线偏振光场 电子能量 类硼氮系统
