LD泵浦的Nd∶GdVO_4/KTP腔内倍频激光器(英文)

基于对Nd∶GdVO4 晶体热焦距的测量及其 1.0 6 μm激光基本性能 ,用三镜折叠腔研究了半导体激光器 (LD)泵浦的Nd∶GdVO4 /KTP晶体的内腔倍频性质 当用从直径为 2 0 0 μm的单光纤输出的低功率的半导体激光泵浦时 ,绿光的阈值是 2 6mW ,光光转换效率为 17.3% 当用从直径为 1.5 5mm的光纤束输出的高功率的半导体激光泵浦时 ,绿光的阈值是 2 0 0mW ,光光转换效率为 19.35 %     

LD泵浦Nd∶YVO4晶体LBO倍频457 nm蓝色激光器

用国产半导体激光二极管泵浦Nd∶YVO4晶体,在室温下获得914 nm激光连续输出，用Ⅰ类临界位相匹配LBO腔内倍频获得457 nm蓝色激光输出.当泵浦注入功率为1.7 W时倍频蓝激光最大输出达20 mW，光光转换效率为1.2%,功率稳定性24 h内优于±3%.     

光纤耦合二极管端泵2μm CW双掺Tm,Ho∶GdVO_4激光器

同YLF和YAG基质相比,在TmHo∶GdVO4晶体中Tm3+离子在800nm附近有非常强的和宽的吸收带,所以该晶体非常适合商品化的GaAlAs激光二极管泵浦.在液氮制冷晶体条件下,利用光纤耦合激光二极管及消色差光学耦合系统端面泵浦双掺5%Tm,0.5%Ho∶GdVO4晶体,在泵浦功率14W、泵浦波长794nm时,实现了2.048μm激光输出,连续运转输出功率3.6W,相应的光光转换效率为25.7%,斜率效率26.6%.相对于吸收的泵浦功率,光光转换效率为35%.由于Tm3+离子间的交叉弛豫效应,泵浦量子效率达到1.3.     

激光二极管泵浦Nd:YVO4/YVO4复合晶体绿光激光器

采用一种新型的Nd:YVO4/YVO4复合晶体,利用V型折叠腔,研究了高功率激光二极管端面泵浦的Nd:YVO4/YVO4复合晶体激光器基频1.06 μm及倍频532 nm激光的输出特性.当泵浦功率为24.6 W时,获得1.06 μm激光的最大输出功率为11.7 W,光-光转换效率为48%.当泵浦功率为17 W时,获得了5.32 W的绿光输出,光-光转换效率达到31.3%.     

LD泵浦Nd∶YVO_4晶体LBO倍频457 nm蓝色激光器

用国产半导体激光二极管泵浦Nd∶YVO4晶体,在室温下获得914nm激光连续输出,用Ⅰ类临界位相匹配LBO腔内倍频获得457nm蓝色激光输出当泵浦注入功率为1.7W时倍频蓝激光最大输出达20mW,光光转换效率为1.2%,功率稳定性24h内优于±3%     

LD抽运Nd:Gd1-xYxVO4连续波激光器的实验研究

报道了一种半导体二极管(LD)抽运Nd:Gd1-xYxVO4晶体,采用简单、结构紧凑的平-平腔设计,实现了1.06 μm连续波激光输出,在8 W的注入功率下,获得3.25 W的1.06 μm连续波激光输出,光-光转换效率为41%,斜效率为45%.KTP腔内倍频实现了稳定的连续波532 nm绿光激光运转,当注入功率为8 W时,单向获得了621 mW的单模绿光输出.     

LD抽运Nd∶Gd_(1-x)Y_xVO_4连续波激光器的实验研究

报道了一种半导体二极管 (LD)抽运Nd∶Gd1-xYxVO4 晶体 ,采用简单、结构紧凑的平 平腔设计 ,实现了 1.0 6 μm连续波激光输出 ,在 8W的注入功率下 ,获得 3.2 5W的 1.0 6 μm连续波激光输出 ,光 光转换效率为 4 1% ,斜效率为 4 5 % KTP腔内倍频实现了稳定的连续波 5 32nm绿光激光运转 ,当注入功率为 8W时 ,单向获得了 6 2 1mW的单模绿光输出     

激光二极管泵浦Nd∶YVO4/YVO4复合晶体绿光激光器

采用一种新型的Nd∶YVO4/YVO4复合晶体,利用V型折叠腔,研究了高功率激光二极管端面泵浦的Nd∶YVO4/YVO4复合晶体激光器基频1.06 μm及倍频532 nm激光的输出特性.当泵浦功率为24.6 W时,获得1.06 pm激光的最大输出功率为11.7 W,光-光转换效率为48%.当泵浦功率为17 W时,获得了5.32 W的绿光输出,光-光转换效率达到31.3%.     

半导体激光端泵腔内倍频Nd∶YVO4/LBO连续波8 W绿光激光器

利用两个半导体激光二极管,双端泵浦Nd∶YVO4晶体,LBO采用I类非临界相位匹配、腔内倍频.在28.9 W的泵浦功率下,获得了8 W连续波0.532 μm绿光输出,其光—光转换效率为27.7%.     

LD泵浦Nd：YAG/Cr：YAG腔外频率变换高功率紫外激光器

用KTP晶体对激光二极管端面泵浦的Nd:YAG晶体;Cr:YAG被动调Q产生的1064nm脉冲激光器进行腔外倍频,用BBO晶体四倍频产生266 nm紫外激光.用15 W的LD阵列;当LD泵浦功率为12 W的情况下;红外(1064 μm)调Q平均输出功率为2.2 W;脉冲序列周期为40 μs;脉宽为18ns;峰值功率高达4.9kW.采用KTP腔外二倍频;532nm的绿光输出平均功率为850mW;用BBO腔外四倍频;266nm的紫外光输出平均功率高达215mW，绿光-紫外光光转换效率为25.2%, 红外到紫外总的转换效率为9.8%.     

Highly efficient 1063-nm continuous-wave laser emission in Nd:GdVO4

Highly efficient 1-microm continuous-wave laser emission in 3-mm-thick, 0.5- and 1.0-at. % Nd:GdVO4 crystals longitudinally pumped at 879 nm into the laser emitting level is reported. Under Ti:sapphire pumping, the slope efficiency in absorbed power is approximately 80% for both crystals, while the slope efficiency, the optical-to-optical efficiency (at 1700-mW pump power), and the laser threshold in incident power are 79%, 78%, and 31 mW for 0.5-at. % Nd and 80%, 77%, and 40 mW for 1.0-at. % Nd, respectively. The slope efficiency is close to the quantum defect limit, the difference being fully accounted for by the residual optical losses. Under 879-nm diode laser pumping, the slope efficiency and the optical-to-optical efficiency in absorbed power of the 0.5-at. % Nd:GdVO4 crystal are 60% and 53%, owing to poorer superposition of the pumped and the laser mode volumes.     

Laser diode pumped LNYAB self-frequency-doubling lasers

The LNYAB self-doubling laser pumped by (LD) has been developed for the first time. The properties of the lasers are much better than those of NYAB self-doubling lasers pumped by LD. The LNYAB self-doubling laser pumped by LD can be operated in TEM_(00) mode with threshold pumping power of 3.6mW which is lower than that of LD pumped NYAB self-doubling lasers by 74%. The output power is 29mW at 0.531μm in green region with optical-to-optical efficiency of 4.8% which is higher than that of NYAB self-doubling laser by 20%.     

NdKYW新型全固体激光器研究

报道了采用半导体二极管抽运的掺钕钨酸钇钾［Nd3+KY(WO4)2］(简称NdKYW)蓝绿光激光器。腔内倍频采用了Ⅰ类临界相位匹配LBO(LiB3O5)晶体作为倍频器,阈值抽运功率为400 mW,在抽运功率为2 W时获得了200 mW的530 nm连续激光输出,其倍频光的光-光转换效率为10%。     

Growth and laser properties of Nd:Ca4YO(BO3)3 crystal

Nd:Ca₄YO(BO₃)₃ (Nd:YCOB) crystal was grown by the Czochralski method, and its structure was measured by using a four circle X-ray diffractometer. The transparent spectrum from 200 to 2600 nm was measured at room temperature. The fluorescence spectrum near 1.06 μm showed that the main emission wavelength of Nd:YCOB crystal was centered at 1060.8 nm. Laser output at 1.06 μm has been demonstrated when it was pumped by a Ti:sapphire laser at the wavelength of 794 nm, the highest output power was 68 mW under pumping power of 311 mW, the pumping threshold was 163 mW and slope efficiency was 46.9%. The self-frequency doubled green light has been observed when it was pumped by a Ti:sapphire or a laser diode (LD). A 14.5 mm Nd:YCOB crystal sample cut at (θ, φ)=(90°, 33°) was used for type I second-frequency generation (SHG) of the 1.06 μm laser pulse. The SHG conversion efficiency was 22%.     

激光二极管抽运的Nd:GdVO4激光器

用高亮度激光二极管作抽运源 ,研究了连续、腔内倍频和被动调 Q Nd:Gd VO4 激光器的输出特性。在抽运功率为 881m W时获得了 119m V的连续绿光输出 ,光 -光转换效率 13.5%。用Cr4 :YAG作可饱和吸收体实现了 Nd:Gd VO4 激光器的被动调 Q运转 ,脉冲宽度为 116～ 2 4 ns,重复频率在 50 0 k Hz～ 1.8MHz范围内可调。     

Efficient Nd:YVO_4 laser in-band pumped by wavelength-locked 913.9-nm laser diode and Q-switch operation

An efficient 1064-nm Nd:YVO_4laser in-band pumped by a wavelength-locked laser diode(LD) at 913.9 nm was demonstrated. The maximum continuous wave(CW) output power of 23.4 W at 1064 nm was realized with the incident pump power of 40 W, corresponding to a total optical-to-optical efficiency of 58.5%. This is to the best of our knowledge the highest total optical-to-optical efficiency and output power of Nd:YVO_4laser in-band pumped by a 913.9-nm laser diode.The Q-switched operation of this laser was also investigated. Through a contrast experiment of pumping at 808 nm, the experimental results showed that an Nd:YVO_4laser in-band pumped by a wavelength-locked LD at 913.9 nm had excellent pulse stability and beam quality for high repetition rate Q-switching operation.     

利用外腔谐振倍频获得高效倍频绿光

用全固化单频Ｎｄ：ＹＡＧ激光器输出的红外激光泵浦由分离元件组成的ＭｇＯ：ＬｉＮｂＯ３倍频腔。通过优化倍频腔的结构，在倍频腔的红外激光输入为４４０ｍＷ时，获得３３０ｍＷ单纵模绿光输出，倍频效率达７５％。     

An efficient and high polarized single cavity Nd:YVO4 microchip laser

An efficient and high polarized microchip green laser with dual Nd:YVO4 crystals is reported. The microchip includes a half-monolithic Nd:YVO4-KTP chip and a second Nd:YVO4 crystal. With two 1 W diode lasers pumped, the output power of TEM₀₀ green laser is 430 mW, and the optical-to-optical conversion efficiency is nearly 21.5 %, when the c-axes of second Nd:YVO4 crystal rotated to 90° from the half-monolithic chip, the polarization ratio of output green laser is 130:1. This laser has the advantages of being simple and easily attainable at a low cost, and suitable for batch production.     

High efficiency passive mode-locked Nd:YVO<Subscript>4</Subscript> laser based on SESAM under direct pumping at 880 nm

We report on an 880 nm LD pumped passive mode-locked TEM₀₀ Nd:YVO₄ laser based on a semiconductor saturable absorber mirror (SESAM), with a high optical-to-optical conversion efficiency of 67.3%, and a slope efficiency of 71%. When the absorbed pump power was 11 W, 7.4 W average output power of 1064 nm continuous-wave mode-locked laser was achieved. To our knowledge, this is the highest optical-to-optical conversion efficiency among all the published reports of 880 nm LD pumped SESAM passive mode-locked lasers. The repetition rate of mode-locked pulse was 80 MHz with 26 ps pulse width. The maximum pulse energy and peak power were 92.5 nJ and 3.6 kW, respectively.     

不同泵浦光下Nd:GdVO4晶体输出特性

为研究808 nm和879 nm两种泵浦光对Nd:GdVO4晶体激光输出特性的影响,并比较两种不同波长泵浦所得连续输出光的效率高低,分析了Nd:GdVO4晶体的能级结构和两种泵浦光作用下的激光输出特性,发现在879 nm也有较强的吸收峰.用808 nm和879 nm两种不同波长泵浦Nd:GdVO4晶体的过程是不同的,808 nm泵浦是一种间接方式能量转移的过程,在此过程中有明显的热负载产生.而879 nm泵浦是将粒子直接激励到激光辐射上能级,降低无辐射弛豫过程产生的热量.从理论上可知,879 nm的泵浦量子效率要高于808 nm的泵浦量子效率,对减少晶体的热产生有很强的优势.实验中采用激光二极管端面泵浦Nd:GdVO4晶体直腔方案,研究了两种不同泵浦光泵浦Nd:GdVO4晶体以获得1 063 nm的连续光,得到了两种光抽运时的斜效率,发现在同样实验条件下,879 nm泵浦的输出光斜效率在小功率泵浦时略高于808 nm|而在大功率泵浦的情况下明显高于808 nm,最高达到38%.同时,在808 nm抽运时,实验上获得了1 341 nm波长的激光,为光通讯的应用提供了一种光源.