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1.
LD端面抽运Nd:YAG 1319 nm/1338 nm双波长激光器研究   总被引:1,自引:0,他引:1       下载免费PDF全文
从LD端面抽运固体激光器的激光阈值公式出发,建立了双波长激光同时振荡的阈值条件,理论计算了腔镜对于两个波长的透过率关系,实现了LD端面抽运Nd:YAG 1319 nm/1338 nm双波长激光连续和准连续输出.双波长激光连续输出功率可达6 W,斜效率为30%;准连续输出功率在重复频率50 kHz时可达4.75 W,斜效率为24.73%,脉冲宽度为55.05 na;腔内插入布儒斯特片,在重复频率为50 kHz时,双波长激光准连续线偏振输出功率可达2.22 W,不稳定性小于0.52%,M2因子仅为1.16.这两条非常接近的谱线为进一步通过非线性光学差频方法获得高相干性太赫兹波提供了实验基础.  相似文献   

2.
从LD端面抽运固体激光器的激光阈值公式出发,建立了双波长激光同时振荡的阈值条件,理论计算了腔镜对于两个波长的透过率关系,实现了LD端面抽运Nd:YAG 1319nm/1338nm双波长激光连续和准连续输出.双波长激光连续输出功率可达6W,斜效率为30%;准连续输出功率在重复频率50kHz时可达4.75W,斜效率为24.73%,脉冲宽度为55.05ns;腔内插入布儒斯特片,在重复频率为50kHz时,双波长激光准连续线偏振输出功率可达2.22W,不稳定性小于0.52%,M2  相似文献   

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4.
利用单根Nd∶YAG晶体棒,实现1 064 nm和1 319 nm双波长基频光振荡及其倍频光532 nm、660 nm激光的输出.采用LD侧面抽运单根Nd∶YAG晶体棒实现1 064 nm和1 319 nm基频光振荡,在此基础上使用非线性频率变换技术获得532 nm和660 nm倍频光的输出.结果表明:1 064 nm和1 319 nm基频激光同时输出时功率分别为30.5 W和8.78 W,单独输出时功率分别为35.6 W和11.2 W|在声光调Q频率分别为10.5 kHz和20.5 kHz时,获得了功率分别为5.34 W和1.353 W的532 nm激光和660 nm激光两路同时运转输出、功率分别为6.72 W和1.902 W各路单独输出,两种情况下倍频转换效率均为17.5%和15.4%,不稳定度小于2%.  相似文献   

5.
利用单根Nd∶YAG晶体棒,实现1064nm和1319nm双波长基频光振荡及其倍频光532nm、660nm激光的输出.采用LD侧面抽运单根Nd∶YAG晶体棒实现1064nm和1319nm基频光振荡,在此基础上使用非线性频率变换技术获得532nm和660nm倍频光的输出.结果表明:1064nm和1319nm基频激光同时输出时功率分别为30.5W和8.78W,单独输出时功率分别为35.6W和11.2W;在声光调Q频率分别为10.5kHz和20.5kHz时,获得了功率分别为5.34W和1.353W的532nm激光和660nm激光两路同时运转输出、功率分别为6.72W和1.902W各路单独输出,两种情况下倍频转换效率均为17.5%和15.4%,不稳定度小于2%.  相似文献   

6.
设计并实现了473 nm和946 nm双波长输出的全固态Nd:YAG激光器.利用激光二极管端面泵浦Nd:YAG晶体,在三镜折叠谐振腔中插入Brewster窗片作为起偏器,通过周期极化晶体PPKTP内腔倍频获得473 nm蓝光输出.同时利用Nd:YAG激光晶体的热退偏效应,把Brewster窗片作为基频光输出耦合镜,实现946 nm激光输出.通过调谐PPKTP的温度,优化了倍频光和基频光的输出功率.泵浦功率25W时,实验获得了1.8W的473 nm倍频蓝光和0.8W的946 nm基频激光输出.  相似文献   

7.
谭雪春  武志超  梁柱 《光子学报》2014,39(10):1762-1765
 针对陶瓷晶体1319 nm的谱线设计了适合的谐振腔腔镜膜系参量,采用激光二极管列阵侧向抽运掺杂1.1at%、Φ3×50 mm的Nd:YAG陶瓷,利用色散棱镜及KTP晶体Ⅱ类匹配腔内倍频,研制了一台660 nm单一波长输出的高重频Nd:YAG陶瓷红光激光器.根据陶瓷晶体的热透镜焦距设计了谐振腔的各个参量,在重复频率为1000 Hz、单脉冲抽运能量约144 mJ时,获得了3.9 mJ的660 nm脉冲激光输出,总的光-光转换效率为2.71%.为进一步研究大功率、高效率的陶瓷红光激光器奠定了基础.  相似文献   

8.
针对陶瓷晶体1319nm的谱线设计了适合的谐振腔腔镜膜系参量,采用激光二极管列阵侧向抽运掺杂1.1at%、Φ3×50mm的Nd∶YAG陶瓷,利用色散棱镜及KTP晶体Ⅱ类匹配腔内倍频,研制了一台660nm单一波长输出的高重频Nd∶YAG陶瓷红光激光器.根据陶瓷晶体的热透镜焦距设计了谐振腔的各个参量,在重复频率为1000Hz、单脉冲抽运能量约144mJ时,获得了3.9mJ的660nm脉冲激光输出,总的光-光转换效率为2.71%.为进一步研究大功率、高效率的陶瓷红光激光器奠定了基础.  相似文献   

9.
利用原有"半导体泵浦激光原理"演示实验装置中的各个器件重新组合,设计了激光二极管双端面泵浦双Nd:YVO4晶体激光器声光调Q输出的实验装置.其输出功率可以得到很大的提高.  相似文献   

10.
高效率LD端面抽运准连续355nm激光器   总被引:1,自引:0,他引:1  
报道了一台激光二极管(LD)端面抽运Nd∶YVO4晶体腔内倍频和腔外和频相结合的声光调Q准连续355 nm紫外激光器。采用LD端面抽运双侧翼键合YVO4基质的Nd∶YVO4晶体,在腔内置入Ⅰ类相位匹配的LiB3O5(LBO)晶体进行倍频实现1 064 nm和532 nm双波长准连续激光输出,通过消色差透镜将双波长激光聚焦耦合到Ⅱ类相位匹配的LBO晶体中进行和频,并采用双向和频光路,获得了高效率、高光束质量、高重复频率的准连续355 nm紫外激光输出。在抽运功率为28.6 W、重复频率为20 kHz时,355 nm激光最大输出功率4.2 W,脉宽为20.6 ns,光-光转换效率为14.7%,激光器光束质量因子Mx2和My2分别为1.29和1.23。  相似文献   

11.
We develop a separate 1319 and 1338 nm Nd:YAG laser system with a blazing grating (600 lines/mm). The resonator of this system has a Littrow grating configuration and a highly reflective mirror, in which the zero-order diffraction of the grating acts as the laser output. By virtue of the wavelength-dependent reflectivity of the grating, a single-wavelength laser at 1319 nm or 1338 nm can be realized. In view of the laser rate equations and using the distribution of the blazing grating, we analyze the oscillation conditions providing single-wavelength laser operation in the system.  相似文献   

12.
Through reasonable coating design to suppress the 1064 nm strongest emission line as well as the 1318.8 nm one, a 1338 nm high-power Nd:YAG quasi-continuous wave (QCW) laser pumped with a Kr lamp has been successfully developed. As high as 102 W of average output power at the 1338 nm single wavelength has been obtained with the overall and slope efficiencies of 4.6% and 6.3%, respectively, when the average pump power is 2200 W. Its threshold power is about 400 W.  相似文献   

13.
We report an LD-end-pumped linearly-polarized continuous-wave (CW) Nd:YAP laser operating at 1341.4 nm. Making use of the plane-concave resonator (T = 2.4%) and the plane-plane resonator (T = 2.6%), we obtain linearly-polarized laser radiation at 1341.4 nm with a power of 3.15 and 2.86 W and corresponding optical slope efficiency of 18.4 and 17.5%, respectively. The effect of the laser oscillation mode on the output is analyzed. An experiment on the intra-cavity frequency doubling with an LBO crystal has been performed, and a laser power of 431 mW in one direction at 670.7 nm was obtained.  相似文献   

14.
刘欢  王巍  巩马理 《物理学报》2013,62(14):144205-144205
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946 nm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20 mm. 当注入抽运功率为50 W时, 946 nm激光连续输出功率最高达5.29 W, 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. 关键词: 角抽运 Nd:YAG晶体 连续波 946 nm激光  相似文献   

15.
Nd:YAG调Q激光器双波长振荡机理分析   总被引:1,自引:0,他引:1       下载免费PDF全文
根据速率方程,研究了二镜腔Nd:YAG双波长调Q激光的振荡机理.通过分析不同透过率下的竞争过程,研究了双波长激光振荡的特点.研究结果表明,在调Q过程中1319nm激光的调Q脉冲起振时间滞后于1064nm激光,并且其最终调Q脉冲来自调Q之后的第一个弛豫振荡尖峰,是该弛豫振荡抑制掉其他弛豫振荡后的结果.通过振荡机理分析,得到了双波长脉冲输出能量相当的透过率条件. 关键词: 双波长 调Q激光 速率方程 弛豫振荡  相似文献   

16.
We report on to our knowledge the first time a diode-side-pumped simultaneous dual-wavelength Nd:YAG laser at 1116 and 1123 nm. By inserting an etalon to balance the gain and loss, a stable dual-wavelength oscillation is acquired. The numerical simulations for wavelength tuning are discussed by principles of laser threshold and Fabry-Perot etalon. Under the pump power of 250 W, a total output power of 23 W is obtained. Meanwhile, the two components have approximately equal intensities. The beam quality of M2 factor was measured to be 7.52.  相似文献   

17.
An investigation of the output characteristics of Nd:YAG lasers operating at a wavelength of 1444 nm using a Xe-flashlamp of 450 Torr, a Xe-flashlamp of 700 Torr, and a Kr-flashlamp of 700 Torr is reported. The highest electrical-to-optical conversion efficiency of 1.83% was attained using the Kr-flashlamp of 700 Torr with a repetition rate of 20 Hz, a pumping pulse width of 144 μs, and an input energy of 31.7 J. The investigation concluded that output energy depends on the temperature of cooling water. The results showed a 3% decrease in output energy at an input energy of 31.7 J as the temperature of cooling water was increased from 23 to 38 °C.  相似文献   

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