LD抽运Yb:GSO实现1090 nm低阈值激光运转

用Yb:Gd₂SiO₅(Yb:GSO)晶体实现激光运转.利用940 nm的二极管激光器作为抽运源，得到Yb:GSO激光器的激光中心波长为1090 nm，抽运阈值功率密度仅为1.27 kW/cm²，小于Yb:YAG的理论阈值1.53 kW/cm².利用2%的输出镜得到最大输出功率为360 mW，相应的斜效率为19%. 关键词： Yb:GSO晶体 激光二极管抽运 阈值     

掺Yb光纤激光器抽运阈值研究

根据粒子数速率方程,石英中Yb^3 的能级和光谱特性及MucCumber关系式推导了描述掺Yb光纤激光器抽运阈值的表达式,对影响抽运 值的各因素进行了分析,并进行了相应的实验研究,理论值与实验结果符合。     

基于钠硼铝硅酸盐玻璃的PbSe量子点红外单模光纤激光

根据实验制备的钠硼铝硅酸盐PbSe量子点玻璃及其透射电子显微镜(TEM)图、吸收谱和发射谱,计算机数值模拟了以PbSe量子点作为激活增益介质的红外单模光纤激光。应用遗传算法,通过数值求解粒子数速率方程和激光谐振腔振荡方程,优化计算了量子点光纤激光器(QDFL)的最佳抽运波长、光纤长度、掺杂浓度及出射镜反射率。结果表明:饱和抽运功率为2 W,在1676nm激光波长处,QDFL最大输出功率可达1.36 W,抽运效率达68%。与通常的掺稀土离子(Yb3+、Er3+)的光纤激光器相比,QDFL具有抽运效率高、激励阈值低、掺杂密度可调、光纤饱和长度短等特点。由于量子点辐射波长的尺寸依赖特性,容易形成多波长激射或波长可调的新型激光器。     

室温下零声子线抽运Yb…YAG板条放大器的理论研究

对室温下零声子线(抽运波长为969 nm)抽运Yb…YAG激光器进行了理论研究,建立了969 nm抽运Yb…YAG的速率方程。在相同热负载状态下,通过数值模拟分别得到969 nm和941 nm抽运时Yb…YAG板条放大器的光-光转换效率和输出激光强度。模拟结果表明:941 nm和969 nm抽运的光-光转换效率基本相同;抽运波长为969 nm的抽运强度比941 nm提高了20%以上。     

Yb∶Y_2O_3陶瓷薄片激光器获得10.5 W连续激光输出

室温下采用中心波长约970 nm准直输出的大功率激光二极管模块作为抽运源,端面抽运双程吸收的腔型结构,抽运原子数分数为8%的Yb:Y2O3多晶透明陶瓷片获得连续激光输出。抽运阈值功率为7 W,当抽运功率达到35 W时,获得优化连续激光输出功率为10.5 W,光光转换效率为30%,斜率效率为37.5%。激光输出功率随抽运功率基本呈线性增长。采用更高功率抽运源、优化谐振腔结构和减小热效应的影响,Yb∶Y2O3陶瓷激光器的输出功率和效率将会得到进一步提高。     

Yb:Y2O3陶瓷薄片激光器获得10.5 W连续激光输出

室温下采用中心波长约970 nm准直输出的大功率激光二极管模块作为抽运源,端面抽运双程吸收的腔型结构,抽运原子数分数为8%的Yb:Y2O3多晶透明陶瓷片获得连续激光输出.抽运阈值功率为7 W,当抽运功率达到35 W时,获得优化连续激光输出功率为10.5 W,光光转换效率为30%,斜率效率为37.5%.激光输出功率随抽运功率基本呈线性增长.采用更高功率抽运源、优化谐振腔结构和减小热效应的影响,Yb:Y2O3陶瓷激光器的输出功率和效率将会得到进一步提高.     

Yb:Y2O3透明陶瓷的光学性能研究

介绍了一种基于纳米粉末真空烧结技术的新型固体激光材料--Yb:Y2O3多晶陶瓷的制备工艺、物理化学特性、能级结构和光谱特性,并与Yb:YAG单晶进行了对比.采用紧凑型有源镜激光器(CAMIL)的抽运方式,验证了Yb:Y2O3透明陶瓷的激光输出性能.在35W的最大抽运功率下,得到波长1078 nm,功率10.5 W的连续激光输出.斜率效率达到37.5%.实验中还观察到激光输出波长随抽运功率增加而红移以及随输出耦合镜变化而漂移的现象.Yb:Y2O3多晶陶瓷是一种理想的激光材料,不仅具有与Yb:YAG单晶同样优秀的物理化学性能和光谱特性,而且其热导率和发射带宽约为Yb:YAG单晶的两倍,非常适合于高亮度激光器和超短脉冲激光器领域的发展应用.     

掺Yb光纤激光器激射波长与阀值关系研究

依据石英中Ｙｂ＾３＋的能级和光谱特性,推导了掺Ｙｂ光纤激光器中激射波长与抽运阀值等的关系式。依据所得到的关系式,深入分析、研究了抽运功率、损耗及阀值对激光运行波长的影响。进行了相关实验,理论与实验结果符合得很好。     

端抽运Yb3+:YVO4激光准三能级理论模型研究

立足于Yb离子能级结构、谐振腔增益损耗和布居数分配情况, 利用爱因斯坦辐射理论和速率方程理论, 建立了适合Yb³⁺离子激光的准三能级理论模型. 该模型引入有效腔长增益贡献因子对腔内光强进行了从头计算, 获得了阈值方程. 利用此模型与Yb激光的实验结果相比较, 发现有效腔长对增益的贡献可以改变腔内损耗和粒子数反转的概率, 也继而影响激光阈值和输出功率效率. 应用于LD端抽运Yb³⁺:YVO₄激光实验中, 在971 nm LD抽运, 有效晶体长度 L=1 mm, 输出镜透过率对激光波长1016 nm为1%条件下, 获得阈值为1.1 W; 有效晶体长度L=2 mm, 输出镜透过率为10%条件下, 阈值获得为3.9 W. 关键词： 3+:YVO₄')" href="#">Yb³⁺:YVO₄ 准三能级模型 有效腔长增益贡献因子     

紧凑的新型Yb:GdYAB自倍频激光器

报道了一种新型自倍频晶体Yb∶Gd0.2Y0.75(BO3)4(Yb∶GdYAB)在二极管激光器端面抽运条件下的连续光激光运转。为了实现紧凑的新型全固态激光器的激光运转,设计了一个平平谐振腔,两个镜子的分开距离仅为1 cm,在这种腔结构下,得到了中心波长为1044 nm的基频激光输出,当吸收抽运功率为4.22 W时,基频激光的最大输出功率为1.38 W,相应功率曲线最大斜效率为54%。为获得有效的自倍频激光输出,换用了平凹腔进行了自倍频实验。自倍频光运转阈值仅为900 mW,在吸收抽运功率为3.9 W的条件下,得到144 mW的自倍频绿色激光输出,获得从二极管激光器到绿光的直接光-光转换效率为3.7%。实验结果表明Yb∶GdYAB作为一种新型的自倍频晶体,对于紧凑的1μm波段的基频光和自倍频可见光激光器都有着很大的应用潜力。     

Pump-Induced Lasing Wavelength Shift in Er/Yb Codoped Fiber Grating Lasers

１ＩｎｔｒｏｄｕｃｔｉｏｎＥｒｂｉｕｍ／Ｙｔｅｒｂｉｕｍｃｏｄｏｐｅｄｆｉｂｅｒｓａｒｅｉｄｅａｌｇａｉｎｍｅｄｉａｆｏｒｃｏｎｓｔｒｕｃｔｉｎｇｓｉｎｇｌｅｆｒｅｑｕｅｎｃｙｆｉｂｅｒｌａｓｅｒｓ．Ｔｈｅｉｒｂｒｏａｄａｂｓｏｒｐｔｉｏｎｂａｎｄ...     

掺Yb双包层光纤激光器波长调谐输出

采用调节腔损耗以调节阈值的方法实现了掺Yb双包层石英光纤激光器的波长调谐输出 调谐范围达50nm 、步长约2nm 当损耗增大阈值升高时,激射波长向短波方向漂移.利用石英中Yb³⁺的能级结构和光谱特性对以上规律进行了定性解释.     

掺Yb3+光纤环形激光器研究

报道了采用环形腔结构,使用偏振敏感的光隔离器构成掺Yb3+光纤激光器激光输出特性研究结果.用976 nm半导体激光器作为泵浦激光,获得了2.35 mW的最大输出功率,激光的中心波长为1.0537 μm,泵浦阈值功率为42 mW.在改变腔内偏振控制器的状态时,激光器的输出波长移动到1.066 μm.在时域,实验观测到掺Yb3+环形激光器的自脉动信号输出.     

Influence of pump wavelength on the laser performance of Yb:KLu(WO4)2 crystal

By employing a tunable Ti:sapphire laser, we conducted an investigation into the effects of pump wavelength deviation on the laser performance of Yb:KLu(WO₄)₂ crystal. Pumping efficiencies exceeding 70% could be reached under lasing conditions with a 3-mm crystal of Yb concentration of 5.24 at.%, when the pumping wavelength was within the main absorption band centered at 981 nm extending from 974 to 990 nm. For different pumping wavelengths, the laser exhibited a single output–input relation with respect to absorbed pump power, giving an average slope efficiency amounting to 51%.     

Collective spontaneous emission of dye molecules and lasing

The threshold pump power density for lasing in dye solutions is found to depend on the photon energy of pumping radiation. An increase in the pumping photon energy can significantly lower the threshold pump power of dye lasers. For an ethanol solution of rhodamine 6G with a concentration of 4×10¹⁸ cm^?3, the threshold power density for pumping radiation with a wavelength of 532 nm is 20-fold higher than for pumping radiation with a wavelength of 347 nm. This phenomenon is associated with the competition of collective spontaneous emission, which can lead to the efficient deactivation of excited molecules in femtosecond times, and the dephasing of excited molecules due to the intramolecular nonradiative processes of absorbed-energy conversion. An increase in the dephasing rate with the increasing energy of exciting photons lowers the efficiency of collective spontaneous emission and increases the concentration of dephased excited molecules responsible for lasing.     

Raman lasing and other nonlinear effects based on ultrahigh-Q CaF2 optical resonator

The calcium fluoride (CaF₂) whispering gallery mode crystalline resonator is an excellent platform for nonlinear optical applications because of the decreasing in threshold caused by ultrahigh quality (Q) factor. In this paper, we achieved the observation of Raman lasing, first-order Raman comb, and second-order Raman lasing in a CaF₂ disk resonator with a diameter of 4.96 mm and an ultrahigh-Q of 8.43× 10⁸ at 1550-nm wavelength. We also observed thermal effects in CaF₂ disk resonator, and the threshold of thermo-optical oscillation is approximately coincident with Raman lasing, since the intracavity power increases rapidly when the power reaches the threshold, and higher input pump power results in longer thermal drift and higher Raman emission power. With a further increase in pump power, the optical frequency combs range is from 1520 nm to 1650 nm, with a wavelength interval of 4× m FSR. It is a promising candidate for optical communication, biological environment monitoring, spectral analysis, and microwave signal sources.     

Threshold power of induced thermal scattering in silica microcavities

The threshold power of Iaser-induced thermal scattering in a high-Q spherical silica microcavity is investigated theoretically as a function of diffraction parameter and the laser pump wavelength for twomode coupling. The threshold power is found to be comparable in order of magnitude with the threshold of Raman lasing and thermal instability in spherical silica microcavities and amounts to 100 fuW for a resonator with a radius of 35 fu m at a pump wavelength of 0.840 fu m. This ensures the application of microcavities as high-sensitive tools for measuring temperature, thermal conductivity, and heat capacity and as stabilizers for microlasers.     

Acousto-optic Q-switched laser performances of Er3+:Yb3+:LuAl3（BO3）4 crystal at 1.5-1.6 μm

Diode-pumped acousto-optic Q-switched pulse laser at 1.5-1.6 μm is obtained in an Er3+:Yb3+:LuAl3 (BO3)4 crystal. Single-pulse laser operation with slope efficiency of 14% and threshold of approximately 100 mW is realized at an average absorbed pump power of 314 mW and repetition frequency of 20 kHz. Output pulse energy is 67 μJ. The effects of pulse repetition frequency, absorbed pump power, and duty cycle on the wavelength and pulse profile of the Q-switched Er3+:Yb3+:LuAl3(BO3)4 laser are also investigated.     

Comparison of spectroscopic properties of Yb:YAP and Yb:YAG crystals

The Yb:YAG and Yb:YAP crystals have been grown by Czochralski method. The absorption spectra and the fluorescence spectra of Yb:YAG and Yb:YAP crystals have been investigated. It is shown that the Yb:YAG crystal has better laser properties and smaller threshold power than Yb:YAP crystal. In addition, the absorption cross-section of the Yb:YAP crystal is 2.16 times of that of the Yb:YAG crystal,so laser diode pumped Yb:YAG lasing can be easily realized. Because YAP single crystal is anisotropic, it is provided with polarization characteristics.