激光二极管泵浦Nd∶YAG 946nm激光器及倍频研究(英文)

提出如何克服准三能级再吸收损耗和抑制寄生振荡实现 LD泵浦的 Nd∶YAG946nm激光器 .在室温下 946nm连续输出大于 1 2 0 m W,斜率效率接近 1 0 %,同时采用 KNb O3 晶体实现了腔内倍频的蓝色激光输出 .

用于准相位匹配的LD泵浦Nd∶YAG 946nm连续激光光源

本文为泵浦质子交换准相位匹配波导器 Li Nb O3 提供了激光光源 ,用 80 8nm半导体激光器泵浦 Nd∶ YAG晶体 ,在室温下获得 946 nm激光连续输出大于 1 2 0 m W,斜率效率9.8% ,并且在国内首次实现了 LD泵浦 Nd∶YAG/ KNb O3 4 73 nm蓝色激光器的连续运转 ,报道了初步的实验结果并对此进行了详细的分析 ,提出了改进方案 .

LD泵浦Nd∶YAG946nmCW激光器研究

文章简述了 Nd∶ YAG 946nm激光器特别是 LD泵浦的 Nd∶ YAG 946nm激光器的发展 ,在国内首次实现了 LD泵浦 Nd∶YAG946nm激光器的连续运转 ,报道了初步的实验结果并对此进行了详细的分析 。

二极管端面泵浦Nd:YAG 946nm连续激光器研究

二极管端面泵浦Nd:YAG晶体946nm连续激光器实验装置,采用紧凑的平-平腔型,当泵浦功率为19.5W时,得到最大输出功率为1.2W,光-光转换效率为6.14%,平均斜效率为10.1%,输出功率与泵浦功率呈线性关系。

LD端面泵浦946nm/473nm连续Nd:YAG/LBO激光器

对Nd:YAG 946 nm和473 nm激光器特性进行了实验研究。采用二极管端面泵浦平-平腔实验结构,使用键合Nd:YAG晶体作为激光增益介质,在入射泵浦功率31.8 W时,得到最高11 W的连续波946 nm激光输出,光-光转换效率34.6%,斜率效率35.4%,光束质量M2达到7.53,半小时内功率不稳定度小于0.4%。采用I类临界相位匹配LBO晶体对946nm激光进行内腔倍频,获得了0.887 W的连续波473 nm蓝光输出,光-光换转效率5.87%。实验结果表明:所设计的端面泵浦连续激光器具有很强的实用价值。

角抽运Nd:YAG复合板条946nm连续运转激光器

报道了一种适合中小功率输出的全固态激光器的角抽运方法,抽运光从板条激光器中板条晶体的角部入射,可获得较高的抽运效率和较好的抽运均匀性.采用单角抽运方式,首次进行了角抽运Nd:YAG复合板条946nm连续运转激光器的实验研究.激光腔采用紧凑型平凹直腔结构,腔长仅为20mm.当注入抽运功率为50W时,946nm激光连续输出功率最高达5.29W,光光转换效率为10.6%,斜效率为12%.整台激光器结构紧凑,调谐简单,成本低,具有广阔的应用前景.

LD泵浦Nd:YAG晶体准三能级热效应理论与实验(英文)

对LD端面泵浦圆柱形Nd:YAG晶体产生946 nm激光的晶体热效应进行了分析。考虑晶体的准三能级结构和腔内传播功率的分布,对热转换系数进行了修改,得到了更符合实际情况的晶体内部温度场分布。当泵浦功率为15W时,晶体端面中心温度由未修改参数前的242.73℃升高到了387.43℃,提高了144.70℃。分别对修改参数前后的热透镜焦距进行了理论计算,并进行了实验测量。实验测量结果和修改参数后的理论计算值相符合。此理论将为激光谐振腔的优化设计、准三能级和三能级的热效应研究提供参考。

二极管泵浦Nd:YAG PPLT腔外倍频473nm激光特性

对Nd:YAG946nm和473nm激光器特性进行了研究。采用二极管端面泵浦平-平腔的实验结构,当腔长为4cm时,获得946nm连续激光的最大输出功率为1.2W,光-光转换效率为6.14%,平均斜效率为10.1%。同时采用声光调Q设备,获得脉宽80ns,重复频率20kHz的946nm脉冲激光。随后利用周期性极化LiTaO3(PPLT)晶体腔外倍频得到473nm激光的最大输出功率为66mW。946～473nm的光-光转换效率为14.2%。实验结果表明:所设计的全固态蓝光激光器具有很强的实用价值。

Passively Q-Switched Nd,Cr:YAG Laser Simultaneous Dual-Wavelength Operation at 946 nm and 1.3μm

A diode-end-pumped Q-switched high-efficiency Nd, Cr：YAG laser with simultaneous dual-wavelength emission at 946nm and 1.3μm is demonstrated. The maximum output power of 1.93 W with simultaneous dual-wavelength operation is achieved at an absorbed pump power of 13.32 W and an absorbed slope efficiency of 15.15%. The maximum optical-optical efficiency is 14.49% with pulse widths of 16.38ns at 946nm and 26.65ns at 1.3μm. A maximum total repetition rate of 43.25 kHz is obtained.

Linear polarization output performance of Nd:YAG laser at 946 nm considering the energy-transfer upconversion

A theoretical model of quasi-three-level laser system is developed, in which both the thermally induced depolarization loss and the effect of energy-transfer upconversion are taken into account. Based on the theoretical investigation of the influences of output transmission and incident pump power on thermally induced depolarization loss, the output performance of 946 nm linearly polarized Nd：YAG laser is experimentally studied. By optimizing the transmission of output coupler, a 946 nm linearly polarized continuous-wave single-transverse-mode laser with an output power of 4.2 W and an optical-optical conversion efficiency of 16.8% is obtained, and the measured beam quality factors are M2 = 1.13 and My2 = 1.21. The theoretical prediction is in good agreement with the experimental result.

885 nm直接抽运946 nm Nd∶YAG低温激光特性研究

对低温下885nm抽运Nd∶YAG晶体946nm准三能级激光性能进行了研究。将激光上、下能级的玻尔兹曼分布分数f_1、f_2作为温度的函数引入到激光速率方程中,定性分析了低温下小信号增益和激光阈值的变化规律。利用搭建的低温冷却系统研究了不同晶体温度下946nm激光的输出性能,在210K时获得了最大165 mW的激光输出,斜效率为36%,相比于常温下斜效率提高了71%。观察并分析了低温下1061nm增益增强的现象,当温度低于190K时,1061nm激光增益显著提高,与946nm激光形成竞争,导致946nm激光输出降低。

Double Q-switched 946 nm laser with MgO：LN electro-optic crystal and MoSe2 saturable absorber

We report a double Q-switched 946 nm laser with a magnesium-oxide-doped LiNbO3 （MgO：LN） electro-optic （EO） crystal and a monolayer molybdenum diselenide （MoSe2） saturable absorber （SA）. A pulsed laser diode side-pumped long neodymium-doped yttrium aluminum garnet rod （φ3×65 mm） is used as the gain medium. Large pulse energy up to 3.15 mJ and peak power up to 346 kW are generated at the repetition rate of 550 Hz, corresponding to the beam quality factors of Mx^2=3.849, My^2=3.868. Monolayer MoSe2 nanosheets applied in the experiment would be a promising SA for a passive Q-switching operation.