一种基于增益调制技术的全光纤化脉冲Yb光纤激光器

以波长为975 nm的半导体激光器作为泵浦源,周期性地脉冲泵浦一个包含Yb掺杂光纤和光纤光栅对的Yb光纤激光器,实现了基于增益调制技术的全光纤化高功率Yb光纤激光器的稳定脉冲输出.在50 kHz重频下,采用20 W的泵浦功率和2.4 μs的泵浦脉冲宽度,获得了1 060 nm波长脉冲宽度仅100 ns的稳定脉冲激光输出,单脉冲激光能量约为20 μJ.以此作为脉冲激光种子进行功率放大,获得了性能稳定的全光纤结构高功率脉冲激光输出,放大后单脉冲能量超过200 μJ,激光放大器斜率效率达到60%.     

1.8 mJ高倍率Nd:YAG板条皮秒激光放大器

设计了一种高倍率的固体皮秒脉冲激光放大器,采用Nd:YAG板条作为激光增益介质。借助板条结构的角度选通结构,搭建了板条五通放大系统,实现了对注入皮秒脉冲激光的高倍率放大。种子源工作在脉冲模式,放大器泵浦源在连续模式工作。皮秒光纤激光器可以在不同的重复频率下工作,脉冲宽度为13.4 ps。种子光经过隔离和耦合系统之后,注入板条的单脉冲能量为25 nJ。当种子源工作重复频率为24.46 MHz时,板条放大器输出平均功率377 W,单脉冲能量15.5 μJ;当种子源工作重复频率为49.8 kHz时,板条放大器输出平均功率89 W,单脉冲能量1.8 mJ,峰值功率为134 MW,放大倍率达到7.2×104。     

多波长半导体激光阵列端泵Nd:YAG脉冲激光器

研制了无温控多波长激光二极管阵列端面泵浦Nd：YAG电光调Q激光器。采用4 000 W多波长准连续激光二极管阵列作为泵浦源,快轴准直镜与透镜导管作为泵浦耦合系统,端面泵浦φ6 mm×60 mm的Nd：YAG晶体,并采用RTP晶体进行电光调Q实验。在重复频率5 Hz、室温（25℃）时,激光器获得了最大输出能量74.4 mJ、脉宽15 ns的1 064 nm脉冲激光输出,光光转换效率达到11%。在25~55℃的工作温度下,对多波长LDA的光谱特征与激光器的输出特性作了测试,激光器输出能量随着工作温度的上升而先迅速下降再逐步保持稳定,当重复频率分别为5 Hz和10 Hz时,激光器对应的最低输出能量分别为48 mJ与37 mJ。     

200W级高亮度半导体激光器光纤耦合模块

光纤激光器系统需要高可靠性、高亮度、高功率光纤耦合输出二极管激光器模块作为泵浦源。基于mini-bar二极管激光器芯片,采用光束精密准直技术、自由空间合束技术来获得高亮度、高功率光纤耦合输出,针对光纤芯径为200μm、数值孔径为0.22的多模光纤,开展了线偏振二极管激光光纤耦合实验,实验结果表明:光纤稳定输出功率达280 W,对应亮度为5.87 MW/(cm2·sr),电-光效率为45.0%。采用偏振合束技术,光纤预期输出功率可达500 W,对应亮度超过10 MW/(cm2·sr)。该方法可应用于研制数百瓦级高亮度二极管激光光纤耦合输出激光器模块。     

LD泵浦瓦级单模高掺铒中红外光纤激光器(英文)

中红外激光在激光医疗、激光光谱学和红外对抗等领域有着广泛的应用前景.为了获得结构紧凑、便携性好的中红外激光源,采用975nm半导体激光器泵浦高掺铒氟化物双包层光纤实现了2.8μm的中红外光纤激光输出.将光纤耦合输出的中心波长为975nm的半导体激光,经过消像差非球面透镜系统耦合进双包层光纤,激光谐振腔由高反镜和具有4%菲涅耳反射率的光纤端面组成,当注入到增益光纤的泵浦功率高于0.37 W时,获得了中红外激光输出.实验结果表明:中红外光纤激光器中心波长为2.785μm,谱宽0.9nm;工作阈值为0.37W,最大输出功率为0.98W,斜率效率为17%,激光工作模式为单模.利用高掺杂浓度铒离子间的能量转移上转换,获得了高效率瓦级单模中红外光纤激光输出.     

太阳光泵浦激光器侧面泵浦效率的提高

太阳光泵浦激光器直接利用太阳光作为泵浦源,实现了太阳光能量到激光能量的直接转化。设计了分腔水冷型金属锥形泵浦腔,以直径8mm,长115mm的Nd:YAG晶体棒作为激光工作物质,用有效面积1.03m2菲涅尔透镜会聚太阳光,实验获得了23.7 W的稳定激光输出,斜效率为7.87%。通过对比实验,改进后的分腔水冷型太阳光泵浦激光器较原有锥形腔激光器有55.92%的激光输出功率提升。分别从侧面泵浦光在冷却水中的吸收损耗以及其耦合效率等方面对新型腔体结构进行了分析,证实了分腔水冷型腔体结构对侧面泵浦效率的提高,并提出了陶瓷漫反射材质的分腔水冷型激光腔的设计。     

双端泵浦保偏光纤激光器

 以两台808 nm半导体激光器LD1和LD2为泵浦源,对光纤激光器双端泵浦进行了研究,获得了6.5 W的激光输出。实验分别测出了LD1和LD2半导体激光器单端泵浦和双端泵浦时的输出功率,对双端泵浦输出功率与单端泵浦功率之和进行了比较,利用双端泵浦提高了泵浦效率和输出激光功率。同时测量了输出激光的偏振度,通过计算得到双端泵浦输出激光的偏振度为0.5。     

强泵浦下掺Yb3+双包层光纤激光器输出特性数值分析和实验研究

对强泵浦下线形腔掺Yb3+双包层光纤激光器输出特性进行了理论和实验研究。通过数值模拟,分析了泵浦光及激光在光纤中的分布、输出功率与泵浦功率的关系、光纤长度及腔镜反射率对激光输出功率的影响。在实验中,利用D型掺Yb3+双包层光纤获得了输出功率10 6W的光纤激光输出,斜率效率达86%。测量了在不同输出耦合条件下的输出功率、阈值泵浦功率和斜率效率,理论分析与实验结果基本一致,为进一步提高光纤激光器功率提供了理论和实验依据。     

67.9W高功率全光纤白光超连续谱激光器

利用自主研发的全光纤被动锁模激光器以及高功率光纤模场匹配器,将145 W的皮秒脉冲耦合进国产光子晶体光纤,实现了67.9 W的高功率全光纤结构白光超连续谱输出,光谱范围为500~1700nm,10dB光谱宽度大于1000nm(泵浦波长除外)。整个激光器系统的光-光(半导体泵浦源输出激光-超连续谱输出激光)转化效率达到33.8%。     

单端泵浦光纤放大器获得4 kW单模窄谱激光输出

窄谱光纤激光器在光束合成等领域有着广泛的应用,然而模式不稳定效应的出现严重限制着窄谱光纤激光器的功率提升。提出并验证了采用新型981 nm稳波长泵浦方案,能够应用于窄谱激光放大并提升模式不稳定效应阈值,通过采用单端后向泵浦结构,将单模窄谱光纤放大器功率提至4 kW以上。实验中采用白噪声相位调制展宽单频激光作为窄谱种子,主放大级分别采用稳波长976 nm和981 nm两种泵浦源单端后向泵浦。在采用976 nm泵浦源泵浦时,窄谱激光最高放大至3.4 kW,出现典型的模式不稳定效应特征,功率提升受到限制。在采用981 nm泵浦源泵浦时,窄谱激光最高放大至4.05 kW,且并未出现模式不稳定效应,输出光束质量M2因子为1.3,进一步功率提升仅受限于泵浦功率。通过优化激光器设计、结合双向泵浦结构,有望实现更高功率的窄谱光纤激光输出。     

高功率高效率光纤耦合半导体激光模块研制

采用光束整形和空间合束的方法,研制出高功率、高效率多阵列光纤耦合半导体激光模块。将波长为976nm连续工作的5个标准半导体阵列,通过对快轴进行准直和快慢轴光束旋转的方式进行光束整形,准直后进行空间合束,经耦合透镜聚焦,耦合入芯径400μm、数值孔径0.22的光纤。测量结果显示:光纤的出光功率最大可达到327 W,光纤耦合效率大于93.6%。     

多芯片半导体激光器光纤耦合设计

应用ZEMAX光学设计软件模拟了一种多芯片半导体激光器光纤耦合模块,将12支808nm单芯片半导体激光器输出光束耦合进数值孔径0.22、纤芯直径105μm的光纤中,每支半导体激光器功率10 W,光纤输出端面功率达到116.84W,光纤耦合效率达到97.36%,亮度达到8.88MW/(cm2·sr)。通过ZEMAX和ORIGIN软件分析了光纤对接出现误差以及单芯片半导体激光器安装出现误差时对光纤耦合效率的影响,得出误差对光纤耦合效率影响的严重程度从大到小分别为垂轴误差、轴向误差、角向误差。     

Performance of optical fibers for transmission of high-peak-power XeCl excimer laser pulses

The simple and efficient fiber delivery of 5-ns pulses from a XeCl excimer laser operating at a wavelength of 308 nm is demonstrated. The coupling scheme uses all of the output energy of the XeCl excimer laser and benefits from a simple and easy-to-adjust fiber coupling. Experiments on the 308-nm fiber delivery for more than 2.5 million laser pulses of 8-ns pulse width (FWHM) and up to 8-mJ stabilized pulse energy are performed. The long-time pulsed UV laser transmission is found to be different for individual samples of optical fibers that perform very similarly in low-intensity UV light applications. For applications with strict demands on the long-time stability, a critical evaluation of the fiber performance with the 308-nm laser under operating conditions is necessary. Measurements between 1 and 200 Hz show a negligible dependence of the fiber delivery performance on the repetition rate of the transmitted laser pulses. PACS 42.55.Lt; 42.81.Cn; 07.69.Vg     

100-mW linear polarization single-frequency all-fiber seed laser for coherent Doppler lidar application

A compact short-cavity fiber laser configured with Er³⁺/Yb³⁺ highly co-doped phosphate glass fiber with stable linear polarization and single frequency output is proposed and investigated experimentally. The fiber laser is composed of a high-reflectivity fiber Bragg grating (HRFBG) and a polarization-maintaining fiber Bragg grating (PMFBG) with the matched wavelengths at 1540.3 nm, which aims at one of the center wavelengths of the atmospheric transmission windows and may be used as the local oscillator (LO) of the coherent Doppler lidar (CDL). The output power of the laser reaches more than 114-mW, the signal-to-noise ratio is larger than 70 dB and the laser linewidth is about 4.1-kHz. Moreover, the linear polarization with 40.5 dB extinction ratio, the power fluctuation of less than ± 0.25% and the frequency fluctuation of less than ± 80 MHz are also obtained. Compared with the DFB fiber laser, the proposed fiber laser is more suitable for the CDL applications.     

High-efficiency hybrid brillouin/ytterbium fiber laser

A high-efficiency hybrid Brillouin/ytterbium fiber laser (BYFL) is demonstrated using a 41.5-cm-longhighly ytterbium-doped fiber and a 10-m-long single-mode optical fiber. The BYFL operates at 1 052.92nm, and the difference between it and the Brillouin pump (BP) wavelength matches the expected stimulated Brillouin scattering (SBS) Stokes shift. Its output power reaches 70.1 mW, which is more than seven times higher than the seeded BP power. The BYFL has an optical signal-to-noise ratio that is greater than 65 dB and has many potential applications, such as in controllable optical delay lines, sensing, and RF photonics.     

All-fiber eye-safe pulsed laser with Er-Yb Co-doped multi-stage amplifier

We report an all-fiber pulsed laser with multistage fiber amplifier which was suitable for high power eye-safe free space optical communications. Tapered structure has been utilized between booster and final amplifiers, which could increase the power coupling from the former fiber into the core of the latter fiber, and the beam quality of the output laser could be improved simultaneously. A maximum output power over 6 W has been achieved from the master-oscillator-power-amplifier system. With the multi-stage configuration and forward pumping, the optical signal to noise ratio was measured to be better than 50 dB.     

Wavelength and duration tunable soliton generation from a regeneratively mode-locked fiber laser

A 10-GHz soliton source with pulse duration between 4-8 ps and wavelength continuously tunable from 1530 to 1563 nm is presented. Using regeneratively mode-locking technology, the harmonically modelocked fiber ring laser could work without pulse dropout at room temperature when no cavity length or polarization maintaining mechanism is available. Applying only one 980-nm laser diode pump, the average output power reaches more than 4 mW.     

30.6 W CW Tm3+ fiber laser of seed amplification

We use all fiber single-mode lasers as seed source, all fiber amplifiers and pump laser coupling amplifier has been experimentally investigated, respectively. The max output power of all fiber amplifier is 30.6 W, corresponding slope efficiency is 39.1%. The two setups, amplifier output laser spectrum finely holds the property of seed laser spectrum, the wavelength of output laser are both 1947.6 nm, the spectrum width is less than 2 nm as same as the wavelength of seed laser. We estimate the beam quality to be M ² = 2.42, clearly indicating nearly diffraction-limited beam propagation.     

Local-cooled watt-level Nd-doped phosphate single-mode fiber laser

Efficient and stable continuous-wave (CW) laser operation at 1053 nm in a Nd-doped phosphate single-mode fiber (Nd:PSMF) has been demonstrated experimentally. The fiber laser consisted of a 21 cm Nd:PSMF placed in a F-P cavity formed by high reflector butt-coupled to coupling end of the fiber and Fresnel reflection of the other end facet. An output power of 1.42 W and a slope efficiency of 34.1% (18.4%) with respect to absorbed pump power (incident pump power) were obtained with 808 nm diode pumping. An increment as much as 9.7 and 15.0% in slope efficiency of the input coupling efficiency and the output power, respectively, were obtained by using a local-cooling design provided by watered sealing the coupling point. The repeatable results indicate that the design, featuring fluid sealing the coupling point of the fiber laser, which was capable of offering an effective alleviation of thermal effects and an elevation of the quality of the laser cavity, could be expected to be a convenient and effective scheme to improve the performance characteristics of the non-silica fiber lasers and the high power fiber lasers, generally in free-space coupling configuration.     

LD泵浦光纤激光放大器实现13 kW高光束质量输出

光纤耦合半导体激光器（LD）泵浦的光纤激光放大器具有体积小、功质比高、稳定性好等优点,在工业加工和军事国防等诸多领域都有着广泛且重要的应用。然而,受限于器件制作工艺水平及光纤中的受激拉曼效应和模式不稳定效应,LD泵浦的光纤激光放大器难以同时实现高功率及高亮度激光输出。为实现更高功率、更高亮度的光纤激光输出,需要结合现有的器件工艺水平并同时实现对放大器中的受激拉曼散射效应和模式不稳定效应的有效抑制。报道了基于单位自研大模场增益光纤成功实现13 kW功率、高光束质量激光输出。激光器采用主振荡功率放大结构,放大级采用单后向981 nm泵浦自研大模场增益光纤,在总泵浦功率为15 kW时,输出功率达到12.94 kW,光束质量M2因子约为2.85。通过进一步优化器件性能及光纤模式控制,有望实现更高功率、更高亮度的光纤激光输出。