Widely tunable/wavelength-swept SLM fiber laser with ultra-narrow linewidth and ultra-high OSNR

We propose and demonstrate a novel single-longitudinal-mode(SLM) erbium-doped fiber laser(EDFL) capable of operating at fixed-wavelength lasing mode with a tunable range more than 54 nm, an ultra-narrow linewidth of 473 Hz and an ultra-high optical signal-to-noise ratio(OSNR) more than 72 dB, or operating at wavelength-swept mode with tunable sweep rate of 10—200 Hz and a sweep range more than 50 nm. The excellent features mainly benefit from a triple-ring subring cavity constructed by three optical couplers nested one another and a fiber Fabry-Pérot tunable filter which can be driven by a constant voltage or a periodic sweep voltage for fixed or wavelength-swept operation, respectively. The proposed EDFL has potential applications in high-resolution spectroscopy and fiber optic sensing.

An ultra-narrow linewidth solution-processed organic laser

Optically pumped lasers based on solution-processed thin-film gain media have recently emerged as low-cost,broadly tunable,and versatile active photonics components that can fit any substrate and are useful for,e.g.,chemo-or biosensing or visible spectroscopy.Although single-mode operation has been demonstrated in various resonator architectures with a large variety of gain media-including dye-doped polymers,organic semiconductors,and,more recently,hybrid perovskites-the reported linewidths are typically on the order of a fraction of a nanometer or broader,i.e.,the coherence lengths are no longer than a few millimeters,which does not enable high-resolution spectroscopy or coherent sensing.The linewidth is fundamentally constrained by the short photon cavity lifetime in the standard resonator geometries.We demonstrate here a novel structure for an organic thin-film solid-state laser that is based on a vertical external cavity,wherein a holographic volume Bragg grating ensures both spectral selection and output coupling in an otherwise very compact(,cm3)design.Under short-pulse(0.4 ns)pumping,Fourier-transform-limited laser pulses are obtained,with a full width at half-maximum linewidth of 900 MHz(1.25 pm).Using 20-ns-long pump pulses,the linewidth can be further reduced to 200 MHz(0.26 pm),which is four times above the Fourier limit and corresponds to an unprecedented coherence length of 1m.The concept is potentially transferrable to any type of thin-film laser and can be ultimately made tunable;it also represents a very compact alternative to bulky grating systems in dye lasers.

Multi-objective optimization of process parameters for ultra-narrow gap welding based on Universal Kriging and NSGA Ⅱ

The successful confinement of the arc by the flux band depends on the welding process parameters for achieving single-pass,multi-layer, and ultra-narrow gap welding. The sidewall fusion depth, the width of the heat-affected zone, and the line energy are utilized as comprehensive indications of the quality of the welded joint. In order to achieve well fusion and reduce the heat input to the base metal.Three welding process characteristics were chosen as the primary determinants, including welding voltage, welding speed, and wire feeding speed. The metamodel of the welding quality index was built by the orthogonal experiments. The metamodel and NSGA-Ⅱ(Non-dominated sorting genetic algorithm Ⅱ) were combined to develop a multi-objective optimization model of ultra-narrow gap welding process parameters. The results showed that the optimized welding process parameters can increase the sidewall fusion depth, reduce the width of the heataffected zone and the line energy, and to some extent improve the overall quality of the ultra-narrow gap welding process.

小型磁选态铯原子钟性能测试数据的统计与分析

LIP Cs-3000是一种国产的小型磁选态铯原子钟,在时频计量、卫星导航等领域获得应用。对近期交付的LIP Cs-3000性能测试数据进行统计与分析,得到了准确度的分布与范围,同时得到了峰谷比、信噪比、Ramsey线宽等指标的分布。从理论上估计了铯原子钟输出信号的稳定度指标范围,验证了该范围与实际测量相符。同时对电子倍增器电压每日增幅进行了统计,结合装铯量给出了LIP Cs-3000铯钟倍增器寿命的分布。统计与分析结果不仅有助于磁选态铯钟的性能提高,也有助于其他小型铯原子钟的性能提升。

基于保偏布喇格光栅的窄线宽半导体激光器

为了研制面向量子精密测量应用的近红外波段光纤光栅外腔半导体激光器,采用独立设计的高偏振依赖增益芯片和双折射光纤布喇格光栅,通过法布里-珀罗等效谐振腔模型,系统分析了光栅反射率、外腔和芯片长度对激光线宽的影响。结果表明,所研制激光器实现了54.46 mW的输出功率、58.88 dB的边模抑制比和24.46 dB的偏振消光比,利用延迟自外差拍频方法测得的洛伦兹线宽低至2.69 kHz。此研究为独立设计制备分立器件的单频窄线宽外腔半导体激光器提供参考,有望应用于雷达成像、陀螺仪、磁力仪和原子钟等量子精密测量领域。

高功率线偏振窄线宽光纤激光器TMI抑制

高功率线偏振窄线宽光纤激器在功率光谱合成、相干探测等方面具有广泛的应用前景。在高功率线偏振窄线宽光纤激光器中,模式不稳定(TMI)效应是限制其功率提升的主要因素之一。本文分析了TMI效应对高功率线偏振窄线宽光纤激光器输出功率的影响,提出了TMI效应的抑制方法。文章采用长波泵浦技术,输出功率100 mW的单频激光器作为种子源,相位调制器将种子源线宽展宽至25 GHz,经三级放大,最终实现了线宽25 GHz、功率2.2 kW、中心波长1064 nm、消光比98%的线偏振窄线宽激光输出,光束质量M_(x)^(2)=1.2、M_(y)^(2)=1.21。分析了泵浦波长对TMI效应的影响:由于光线芯径较小(20μm),增益光纤对泵浦光吸收系数较高(1.8 dB/m@976 nm),纤芯温度较高,加上泵浦光量子亏损引入的热,导致纤芯折射率发生变化,较低功率下发生TMI效应,当泵浦波长向长波偏移时,泵浦光的量子亏损降低,同时泵浦吸收系数也降低,无论在光纤全长、还是单位长度上的热分布均减小,增大了TMI阈值,提升了线偏振窄线宽光纤激光器的输出功率。

基于光学反馈频率锁定的窄线宽稳定中红外激光产生技术研究

中红外精密激光光谱技术在痕量气体检测、基本物理常数测定等领域都有重要应用,然而由于缺乏窄线宽、稳定的中红外光源,很难实现中红外精密光谱测量.本文介绍了一种基于光学反馈频率锁定的窄线宽稳定中红外激光产生技术,分析了光学反馈实现激光到F-P腔锁定的可行性,利用一个高精细度中红外超稳F-P腔作为频率参考,基于光学反馈技术实现了量子级联激光器到该超稳腔的锁定.经过评估得到激光器线宽被压窄到1.1 Hz,压窄激光线宽的同时稳定了激光频率,将激光器的长期漂移控制在20 kHz/12 h.其中,为了获取长时间稳定的光学反馈,基于PDH技术获取了误差信号,用于对反馈相位的实时伺服控制.

Effect of DBR Geometry on Reflectivity and Spectral Linewidth of DBR Lasers

The linewidths of InGaAs-GaAs-AlGaAs DBR lasers with varied DBR dimensional parameters are measured and analyzed. These lasers were built with different DBR grating lengths and depths in order to explore the effect of the size of the DBR on its coupling coefficient and reflectivity,and hence on the linewidth of the laser diodes. The linewidths were measured by employing a self heterodyne linewidth measurement system. The experimental and calculated data for DBR reflectivity and spectral linewidth are given. The relationship between these data and the dimensions of the DBR is analyzed. Based on this analysis,the effect of the DBR geometry on the linewidth of the lasers is explored. The results give useful information related to the design and fabrication of such DBR lasers.

光纤布拉格光栅长外腔反馈半导体激光器特性研究

窄线宽激光器是光谱学和精密计量学等实验的基本组成部分。由于半导体激光器对外部光学反馈十分敏感,所以可以利用光反馈的高带宽抑制半导体激光器的相位噪声,进而压窄线宽。本文采用光纤布拉格光栅作为反馈元件,搭建了长外腔反馈回路。为了降低外界环境温度起伏和气流扰动的影响,对反馈光路的光纤控温,使得1小时内最大温度起伏从0.039℃降低到0.003℃。此外,测试了反馈带宽对激光线宽的影响,尽管实验所用光纤布拉格光栅的带宽远大于自由运转的激光线宽,但仍然可以观察到激光线宽被压窄,且光纤光栅的带宽越小,激光线宽越窄。对于此现象,分析认为在反馈回路中应该存在一种负反馈机制,可以将激光线宽稳定到反馈光谱的某个斜率处,所以光纤光栅的反馈带宽越窄,反馈光谱的斜率越大,反馈越灵敏。通过调整光纤光栅的反馈功率在0~1 mW范围内改变,观察到当反射功率为0.8 mW时,光反馈将激光线宽从自由运转的100.5 kHz压窄到最窄的11.5 kHz,0.2 kHz~2 MHz范围内的相位噪声降低约20 dB。

用于可移动量子重力仪的光纤拉曼激光源研究

基于两个窄线宽光纤激光器和自制的锁相控制系统,研制了一个低相位噪声窄线宽拉曼光纤激光源,建立了拉曼光纤激光系统的相位噪声模型,研究了拍频光功率、不同频率参考源对拉曼激光相位噪声的影响。实验结果表明,该拉曼光纤激光源在10 Hz~1 MHz范围内相位噪声功率谱密度可达到^(-11)8 dBc/√Hz,相应的相位噪声为22.7 mrad,将其应用到重力仪中获得的重力测量灵敏度为10.93μGal/√Hz。对拉曼激光源进行连续3 h的相位噪声稳定性测试和连续25 min的频率稳定性测试,得到的相位噪声标准差为0.734 mrad,相应的重力灵敏度标准差仅为0.349μGal/√Hz。当积分时间为1 s时,相位锁定时频率稳定度为2.675×10^(-11),验证了该激光源具有低相位噪声和高稳定性。利用相位噪声模型得到的理论结果与实验结果一致,证实了理论模型的正确性。

基于三次样条插值的M-QAM载波相位估计

在基于高阶调制的相干光通信传输系统中,接收端信号受相位噪声干扰会对系统性能产生直接的影响。传统的盲相位搜索(BPS)算法具有较高的线宽容差,适用于多种调制格式,但随着调制阶数的增加,用于BPS的测试相位数量会急剧加大。针对M元正交振幅调制(M-QAM)格式,本研究提出了一种新的低复杂度载波相位估计(CPE)算法。首先利用BPS算法,得到B个测试相位和平均欧氏距离之间的关系;然后在此基础上,提出了一种基于三次样条插值(CSI)的两级BPS载波相位估计算法,得到(2B−1)个等间隔插值相位和平均欧氏距离之间的光滑曲线关系;最后取曲线的最小值处所对应的相位值为最优相位估计值。仿真结果表明,在使用少量测试相位的前提下,通过CSI算法可以有效地对载波相位进行恢复,与BPS算法相比,CSI算法乘、加法器计算复杂度分别降低了38%和42%(16-QAM),为载波相位恢复提供了新思路。

基于多纵模振荡种子源的高功率窄线宽光纤激光器关键技术分析及研究现状

基于多纵模振荡种子源的窄线宽光纤激光器具有光路简单、结构紧凑、可靠性高、成本低等特点,在实际工程应用以及在空间受限的载荷平台上有着显著优势,是高功率光谱合成的理想子束模块。受自脉冲效应的影响,多纵模振荡种子源的时域特性较差,导致放大过程中会产生较强的光谱展宽与受激拉曼散射效应。这限制了其输出功率的进一步提升并降低了其光谱纯度。本文首先介绍了4种常见的窄线宽种子源,并重点分析了多纵模振荡种子源中自脉冲效应产生的机理及抑制方法,对优化多纵模振荡种子源和放大器的关键技术进行了详细介绍,归纳总结了近几年的技术突破与研究成果,对未来的发展方向进行了展望分析。本文研究对基于多纵模振荡种子源的窄线宽激光器的功率提升和光谱优化提供一定思路。

用于激光频率参数测量的飞秒光学频率梳

近年来随着光纤制造技术和飞秒激光技术的成熟,以掺铒(Er)光纤光学频率梳为代表的频率梳技术,逐步突破了光学频率测量领域,在长度测量、精密光谱分析、超低相位噪声微波频率产生、精密时间频率传递、温度测量等领域发挥出越来越重要的作用,已成为许多高端科研领域的基础性工具。但飞秒光学频率梳所解决的重要问题是对激光频率进行测量。本文主要面向激光频率参数测量的需求,研制基于掺Er光纤飞秒激光器的光学频率梳,在实现光学频率梳稳定运转的前提下,通过非线性光学频率变换技术,实现光谱范围从掺Er光纤光学频率梳的中心波长向各个待测激光波长的转换,并完成与多个不同波长激光的拍频信号探测。目前已验证的飞秒光梳可测频率范围为500~2000 nm;频率稳定度和准确度为10^(-16)量级;线宽为Hz量级。该指标满足了激光频率特性参数测量的需求,为激光绝对频率、频率漂移、线宽等参数的测量提供了基础性的测量工具。

增厚DBR型894 nm窄线宽VCSEL

垂直腔面发射激光器(VCSEL)是芯片级原子钟(CSAC)的主流光源,其光束质量会影响CSAC的各项性能。扩展VCSEL内部有效腔长能够以压缩冷腔线宽的方式压窄器件最终辐射激光的线宽,从而可以减小CSAC短时间内的计时频率噪声。根据所计算的VCSEL表面反射谱,将VCSEL中4层下分布式布拉格反射镜(DBR)的厚度由常规的四分之一波长增加至404 nm,压缩了VCSEL冷腔线宽,并生长了对应的外延结构,制备了通过增厚DBR扩展有效腔长的894 nm窄线宽VCSEL。测试结果表明,研制的VCSEL在90℃下波长为893.1 nm,功率为0.335 mW,线宽约为32 MHz,且具有稳定的偏振特性。

基于MEMS反射镜的窄线宽外腔可调谐半导体激光器

基于大转角的电磁式MEMS反射镜和闪耀光栅作为外腔调谐元件,设计了Littman-Metcalf结构的外腔半导体可调谐激光器,MEMS反射镜可准确控制偏转角度,2 h内角度复位调谐波长漂移小于20 pm,该可调谐激光器实现了1435.81~1555.83 nm(120.02 nm)的稳定的波长调谐,全波段波长调谐过程中激光器边模抑制比大于30 dB,相同调谐电流下,激光器波长控制误差小于20 pm。注入电流350 mA时,外腔激光器输出功率达25.89 mW,最小阈值电流68 mA。利用延迟自外差法测得可调谐激光器的线宽优于69 kHz。该研究成果有望在激光雷达、相干激光通信、光学传感器及计量检测等诸多领域发挥重要作用。

可移动光学超稳腔的研制及其稳定性测试

可移动超稳腔可以减小环境振动对激光稳定性带来的影响,适合振动强度较大的运输条件。本文展示了一种由低膨胀系数玻璃制作的光学谐振腔,并测试了激光锁定到该可移动超稳腔的频率稳定性。支杆固定于金属热屏蔽罩内的机械设计使其具有良好的稳定性和可移动性。采用短延迟自外差干涉法测量了激光器锁定到超稳腔后的线宽,并且借助振动平台测试其稳定性。实验发现锁定后的激光器线宽和振动频率存在线性关系,激光器线宽会随着振动加速度增大出现饱和效应。去除振动时激光线宽可以恢复到无振动时的数值,证实该超稳腔具有较高稳定性。

基于双F-P标准具的宽调谐窄线宽Tm:YAP脉冲激光器

设计了一种宽调谐、窄线宽、高重频的Tm:YAP脉冲激光器。采用三个切轴方向的Tm:YAP晶体作为增益介质,通过0.5 mmYAG材质F-P标准具和0.025 mm熔石英材质F-P标准具,激光器分别实现了49 nm、44 nm、51 nm波长连续调谐,具体分别为1 951~2 000 nm、1 932~1 976 nm、1 943~1 994 nm。同时测得激光线宽均在0.4 nm左右。声光调Q 10 kHz脉冲重复频率下,分别实现了最大平均功率5.08 W、6.29 W、4.83 W的脉冲激光输出。对比发现,b轴Tm:YAP激光器的平均功率最大,测得最大平均功率下的脉宽为65.7 ns,光束质量因子M2在x方向上为1.84,y方向上为1.93。结果表明b轴Tm:YAP晶体具有宽调谐、窄线宽、高功率、大能量激光的潜力。

窄线宽外腔半导体激光器研究进展

窄线宽外腔半导体激光器具有结构简单、可调谐、噪声低等优势,广泛应用于量子精密测量、光通信、激光雷达等领域。根据外腔选频器件的不同,本文主要介绍光栅型激光器、干涉滤光型激光器、波导型激光器和法拉第激光器四类外腔半导体激光器,分析各类激光器的基本结构与选频机制、介绍各自的优缺点以及国内外研究进展。其中,前三类激光器采用非量子器件进行频率选择,而法拉第激光器利用共振法拉第旋光效应选频,输出波长直接对应原子跃迁谱线,对激光二极管的电流与温度变化具有良好的鲁棒性。随后介绍外腔半导体激光器的应用情况,尤其是在精密测量领域中的典型应用。最后总结并展望窄线宽外腔半导体激光器的未来发展方向。

面向小型化窄线宽激光的光学锁定硬件系统研究

研制小型化、数字化、高带宽的光学锁相控制系统是实现面向实际应用的小型化窄线宽激光光源的关键。但目前的通用及专用型系统存在着诸如依靠商业平台、带宽不足、集成化程度不高等问题。研究研制的数字伺服系统基于现场可编程门阵列(FPGA)以及高速模数转换器(ADC)与数模转换器(DAC),实现数字综合器、调制器、鉴相器、滤波器以及伺服控制单元,成功研制高速、可重构、双通路的光学锁相环集成硬件平台,系统开环带宽为2.63MHz。与具有高品质因子特性的回音壁模式(WGM)光学微腔相结合,通过相位调制光外差稳频方法(PDH)实现积分线宽为20Hz的窄线宽激光,光学闭环反馈带宽达到450M。该系统具有良好的通用性与扩展性,可以适用于各种原子分子光谱以及光学频率的伺服锁定。

Widely-wavelength-tunable brillouin fiber laser with improved optical signal-to-noise ratio based on parity-time symmetric and saturable absorption effect

A widely-wavelength-tunable Brillouin fiber laser(BFL)with improved optical signal-to-noise ratio(OSNR)based on parity-time(PT)symmetric and saturable absorption(SA)effect is present.This novel BFL realizes PT symmetry and SA effect through polarization-maintaining erbium-doped fiber(PM-EDF)Sagnac loop,which is composed of a PM-EDF,a coupler and two polarization controllers(PCs).By using the inherent birefringence characteristic of PM-EDF,two feedback loops in orthogonal polarization state are formed when the Strokes signal in injected.One of these loops provides gain in the clockwise direction with in the Sagnac loop,while the other loop generates loss in the counterclockwise direction.By adjusting the PCs to control the polarization state of the PM-EDF,a single-longitudinal-mode(SLM)BFL can be achieved,as the PT symmetry is broken when the SA participating stimulated Brillouin scattering(SBS)gain and loss are well-matched and the gain surpasses the coupling coefficient.Compared to previous BFLs,the proposed BFL has a more streamlined structure and a wider wavelength tunable range,at the same time,it is not being limited by the bandwidth of the erbium-doped fiber amplifier while still maintaining narrow linewidth SLM output.Additionally,thanks to SA effect of the PM-EDF,the PT symmetric SBS gain contract is enhanced,resulting in a higher optical signal-to-noise(OSNR).The experimental results show that the laser has a wide tunable range of 1526.088 nm to 1565.498 nm,an improved OSNR of 77 dB,and a fine linewidth as small as 140.5 Hz.