Frequency-stabilized Yb：fiber comb with a tapered single-mode fiber

We demonstrate a stable Yb：fiber frequency comb with supercontinuum generation by using a specially designed tapered single-mode fiber, in which a spectrum spanning from 500 nm to 1500 nm is produced. The carrier-envelope offset signal of the Yb：fiber comb is measured with a signal-to-noise ratio of more than 40 dB and a linewidth narrower than 120 kHz. The repetition rate and carrier-envelope offset signals are simultaneously phase locked to a microwave reference frequency.

Pump-induced carrier envelope offset frequency dynamics and stabilization of an Yb-doped fiber frequency comb

In this paper, we demonstrate a carrier envelope phase-stabilized Yb-doped fiber frequency comb seeding by a nonlinear-polarization-evolution（NPE） mode-locked laser at a repetition rate of 60 MHz with a pulse duration of 191 fs.The pump-induced carrier envelope offset frequency（ f0） nonlinear tuning is discussed and further explained by the spectrum shift of the laser pulse. Through the environmental noise suppression, the drift of the free-running f0 is reduced down to less than 3 MHz within an hour. By feedback control on the pump power with a self-made phase-lock loop（PLL）electronics the carrier envelope offset frequency is well phase-locked with a frequency jitter of 85 m Hz within an hour.

基于锁模光学频率梳的高速数据传输

大数据时代网络数据流量的爆炸式增长给通信系统的容量和数据传输速率带来极大的挑战.本文基于锁模光学频率梳的宽光谱范围和高相位相干性提出了一种高频正交幅度调制信号生成方法,通过电光调制器对光学频率梳进行幅度相位整形并下变频至射频域,生成携带编码信息的高速、高阶、低相位噪声的调制信号,再结合锁模光学频率梳窄线宽、多波长的特性,仅使用单个激光器即可实现基于波分复用技术的大规模并行高速通信.仿真验证了该方案的可行性,随后在100 m的自由空间光链路中使用光子微波信号进行16元正交幅度调制通信实验,实现了误码率低于10^(–6)的14 Gbit/s数据传输.

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。

氟化镁微瓶腔光频梳光谱分析及优化

氟化镁微腔光频梳具有体积小、功耗低、光谱覆盖范围广、色散可调控的优势,在光通信、中红外光谱等领域有着潜在应用前景.本文研究了氟化镁回音壁模式微瓶腔平台产生的光频梳光谱特性.为了优化氟化镁微瓶腔光频梳的光谱分布,利用有限元法迭代求解了瓶腔结构在不同曲率和轴向模式下的二阶色散及高阶色散,通过分步傅里叶法求解非线性薛定谔方程仿真了不同轴向模式激励下的光频梳光谱演变过程.结果表明,在最佳曲率半径下通过低阶轴向模式激励可以实现宽带范围的近零反常色散调谐,而高阶轴向模式将导致微瓶腔呈现弱正常色散.在低阶轴向模式下较弱的反常色散使光频梳的带宽得到展宽,证明了三阶色散和负的四阶色散可以展宽克尔孤子光频梳;在高阶轴向模式下弱正常色散抑制了克尔光频梳的产生,拉曼光频梳占主导地位.在适宜的泵浦条件下通过调控微瓶腔的轴向模式可以实现克尔孤子光频梳和拉曼光频梳的选择性激发.本文工作的开展将为氟化镁微腔色散设计及宽带克尔孤子光频梳、拉曼光频梳实验调控提供指导意义.

基于高Q值Si3N4片上光学微腔的孤子光频梳

高Q值片上微腔已被证明是一种性能优异的克尔孤子光学频率梳产生平台。由片上多模波导构成的Si3N4微腔可以同时实现产生暗孤子所必须的高品质因子和反常色散。为了进一步降低产生单孤子光频梳的阈值功率,文章设计了一种具有欧拉弯曲的新型跑道型Si3N4微腔,与传统的圆形弯曲波导相比,跑道型微腔直波导连接处弯曲半径的突然变化被显著抑制,这抑制了高阶模式耦合并降低了传播损耗,从而获得了超过5×10^(6)的品质因子。基于该新型微腔,使用辅助激光加热方法仅用47mW泵浦激光器(估计片上泵浦功率为33mW)就产生了重复频率在Ka波段且带宽超过20nm(对应于129fs的脉冲持续时间)的单孤子微腔光频梳。

Midinfrared optical frequency comb based on difference frequency generation using high repetition rate Er-doped fiber laser with single wall carbon nanotube film

We demonstrated stable midinfrared(MIR) optical frequency comb at the 3.0 μm region with difference frequency generation pumped by a high power, Er-doped, ultrashort pulse fiber laser system. A soliton mode-locked161 MHz high repetition rate fiber laser using a single wall carbon nanotube was fabricated. The output pulse was amplified in an Er-doped single mode fiber amplifier, and a 1.1–2.2 μm wideband supercontinuum(SC) with an average power of 205 m W was generated in highly nonlinear fiber. The spectrogram of the generated SC was examined both experimentally and numerically. The generated SC was focused into a nonlinear crystal, and stable generation of MIR comb around the 3 μm wavelength region was realized.

Numerical simulation and temporal characterization of dual-pumped microringresonator-based optical frequency combs

Dual-pumped microring-resonator-based optical frequency combs(OFCs) and their temporal characteristics are numerically investigated and experimentally explored. The calculation results obtained by solving the driven and damped nonlinear Schr?dinger equation indicate that an ultralow coupled pump power is required to excite the primary comb modes through a non-degenerate four-wave-mixing(FWM) process and, when the pump power is boosted, both the comb mode intensities and spectral bandwidths increase. At low pump powers, the field intensity profile exhibits a cosine variation manner with frequency equal to the separation of the two pumps, while a roll Turing pattern is formed resulting from the increased comb mode intensities and spectral bandwidths at high pump powers. Meanwhile, we found that the power difference between the two pump fields can be transferred to the newly generated comb modes, which are located on both sides of the pump modes, through a cascaded FWM process. Experimentally, the dual-pumped OFCs were realized by coupling two self-oscillating pump fields into a microring resonator. The numerically calculated comb spectrum is verified by generating an OFC with 2.0 THz mode spacing over 160 nm bandwidth. In addition, the formation of a roll Turing pattern at high pump powers is inferred from the measured autocorrelation trace of a 10 free spectral range(FSR) OFC. The experimental observations accord well with the numerical predictions. Due to their large and tunable mode spacing, robustness,and flexibility, the proposed dual-pumped OFCs could find potential applications in a wide range of fields,including arbitrary optical waveform generation, high-capacity optical communications, and signal-processing systems.

Femtosecond enhancement cavity with kilowatt average power

Femtosecond enhancement cavity(fsEC) has been proved to be a powerful tool in a diverse range of applications.Here, we report the recent progresses in building an fsEC on kilowatt level average power, with the aim of realization of intracavity high harmonic generation(HHG) and extension of the wavelength of femtosecond optical frequency comb from infrared(IR) to extreme ultraviolet(XUV). Upon mode-matching optimization and cavity length locking, an intracavity average power of 6.08 kW is reached and the corresponding buildup is 225. After introducing noble gas of Xe into the focus region, clear sign of plasma has been observed. The generated HHG is also coupled out by a sapphire plate placed at Brewster's angle for the fundamental laser. Our work paves the way for the realization of an XUV comb.

Raman lasing and other nonlinear effects based on ultrahigh-Q CaF_(2)optical resonator

The calcium fluoride(CaF_(2))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 CaF_(2)disk resonator with a diameter of 4.96 mm and an ultrahigh-Q of 8.43×10^(8)at 1550-nm wavelength.We also observed thermal effects in CaF_(2)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×FSR.It is a promising candidate for optical communication,biological environment monitoring,spectral analysis,and microwave signal sources.

自动NPE锁模飞秒激光频率梳研究

基于非线性偏振演化(NPE)锁模技术的光纤光梳具有脉冲宽度窄、光谱覆盖广、重复频率高、相位噪声低等诸多优点,然而,由于锁模稳定性不好,该技术逐渐在工程应用中被非线性放大环形镜(NALM)和半导体可饱和吸收镜(SESAM)锁模技术取代。为了扩展NPE光纤光梳的工程应用范围,研制了具有自动锁模功能的NPE掺铒光纤光梳,采用电控偏振控制器和自动锁模电路实现光纤激光器的自动锁定,锁模脉冲宽度90 fs,重复频率101.5 MHz。采用共线式f-2f自参考技术测得40 dB的载波包络相移频率fceo信号,并采用上混频与64分频相结合的方式将fceo锁定至20 MHz,锁定精度1.5 mHz。通过锁定40次谐波的方法,利用自研的重复频率调节机构实现重复频率frep锁定,锁定后的频率精度为199μHz。

基于双波长激光器的集成化中红外双光梳系统(特邀)

中红外双光梳光谱检测系统因其高分辨、高灵敏、快速测量的特性为极低浓度气体的标定带来了革新技术。本文用单腔双波长激光器输出的异步双波长脉冲替代两台锁模激光器,结合非线性差频技术,发展了集成实用化的中红外双光梳系统。共腔产生的1034 nm与1039 nm双波长脉冲序列,其重复频率差约为1.18 kHz,且因共模噪声被抑制,脉冲间的相对稳定性较高。利用级联放大器将种子脉冲光功率提升至1.1 W后,与2 W的1549.315 nm的连续激光非线性差频,将激光器输出波段拓展至中红外。产生的中红外激光功率可达3.5 mW,光谱覆盖范围超过50 nm。对中红外双光梳的相干性进行测量,与1μm的底层双光梳相比,中红外双光梳拍频梳齿频率间隔、信噪比、线宽等无明显劣化,可为复杂环境下的痕量分析提供可行方案。

拉曼抑制光频梳微腔的设计与仿真

为了解决回音壁模式下的微腔在产生光频梳时受拉曼效应的影响,尤其在重频GHz时难以产生平滑的光梳谱的问题。首先,设计并调节波导和微环的耦合长度;然后,优化耦合角度,调整微环与波导之间的匹配模式,降低在长波段的耦合Q值,增加拉曼产生的阈值,抑制拉曼效应。通过仿真分析得出,相较于一般的直波导微环耦合结构,设计的弯曲波导微环在短波长处拉曼阈值增加了3倍,且在短波长处产生的光频梳功率提高了20 dB。为回音壁模式微腔结构的设计提供了一定的参考价值。

基于FP-LD强反馈的光纤迈克尔逊干涉仪传感系统

针对采用传统自组光纤激光器的光纤传感系统存在成本较高和结构复杂等问题,提出了一种基于商用激光器强反馈的光纤迈克尔逊干涉仪(FMI)传感解调系统。该系统采用商用法布里-珀罗腔型半导体激光器(FP-LD)为光源,由直流电源直接驱动,经FMI的反射、干涉后对其形成强反馈;利用多纵模激光拍频解调技术实现对FMI的传感解调,将FMI光域干涉光强的变化直接转化为电域拍频包络的变化。研究了不同FMI臂长差时拍频信号随温度的变化过程及传感系统灵敏度。实验结果表明:当臂长差分别为0.45、0.40 m时,灵敏度分别为325、358.33 kHz/℃。

基于飞秒激光器光学频率梳的绝对距离测量

提出使用飞秒激光器的光学频率梳测量绝对距离的方法。将一个飞秒激光器作为绝对距离测量的光源,搭建迈克尔逊干涉结构,利用色散干涉原理进行相应的光谱分析,得到干涉光路的光学路径差引起的相位差,最终计算出干涉光路的光学路径差。实验结果表明我们的长度测量方法精确度高,分辨力达到纳米量级。最小测量距离达到9μm,非模糊范围达到5.75mm。相对于传统白光色散干涉技术的有限测量范围,最大测量距离可以扩展到任意长度。

基于飞秒光学频率梳的大尺寸精密测距综述

飞秒光学频率梳的出现对时间频率技术和光谱学技术产生了深远重大的影响,由此衍生的飞秒光学频率梳绝对测距技术以其快速、大尺寸、高精度等优点已成为国际研究热点,并有望直接应用于大装备制造、激光雷达和卫星编队飞行等大尺寸精密测距。在简要阐述飞秒光学频率梳的原理特性及主要应用的基础上,围绕光梳测距的发展历程及前沿方向,着重介绍了飞秒光梳精密测距近两年来的最新研究进展,并对该技术进行了总结和展望。

飞秒光学频率梳高精度气体吸收光谱技术进展

飞秒光学频率梳以其频谱宽、脉宽窄、频率稳定度高等优点,对光学频率计量、绝对距离测量、高精度光谱测定产生重大影响。飞秒光学频率梳的时域特性和频域特性溯源至微波频率基准,使得高精度气体吸收光谱探测成为可能。飞秒光学频率梳光谱技术具有测量速度快、光谱灵敏度高、分辨率高、信噪比高等优点,因此加大对飞秒光学频率梳光谱技术的研究力度将更好地服务于环境保护、工业生产、生物医学、科学研究等各领域。飞秒光频梳高精度气体吸收光谱主要可分为光频梳腔衰荡光谱、光频梳腔增强光谱和双光频梳多外差光谱。其中,根据采集方式不同,光频梳腔增强光谱又可分为梳齿游标测量法、虚拟成像相位阵列测量法和傅里叶变换测量法。目前,国外已广泛开展相关研究,而国内仍处于起步阶段。本文综述了飞秒光学频率梳高精度气体吸收光谱探测的主要技术方法,展示了不同测量方法典型的实验方案,分析了各探测方法的优缺点,并追踪了主要研究小组的前沿成果。

光频标和光频测量研究的历史、现状和未来

本文综合评述了光频标和光频测量研究的历史、现状和未来。在上世纪最后的30年间，光频标已达到10^-11-10^-13量级的准确度，使长度单位“米”进行了重新定义，实际上成为时间单位秒的“导出单位”。最近三年来，该领域的研究出现了重大突破。这是由于飞秒锁模激光技术与光频测量技术两者出人意外的结合，使微波频标与光频标之间建立了简易可行的联系，使光频标的准确度和实用性达到了前所未有的高度，成为计量学和物理学中一个新的亮点。它的进一步发展必将给计量学和物理学带来深远的影响。

基于双波长频率梳的绝对测距系统研究

研制了一套基于双波长飞秒频率梳的绝对测距系统,该系统利用单壁碳纳米管作为可饱和吸收器调节腔内损耗,同时产生重复频率稍有差异并具有高度互相关性的两个不同波长的激光脉冲。利用搭建的异步光学采样原理的双频率梳测距系统进行了测距实验,并与室内80 m长度标准装置进行了比较。结果表明:在采样时间为1 s的情况下,测距系统不确定度为6μm+1×10^(-7)L (k=2)。

用飞秒锁模激光测量光的频率

介绍了2005年诺贝尔物理学奖的获奖工作-用锁模飞秒激光光梳去测量光的频率。飞秒激光光梳技术大大简化了光频的测量。锁模飞秒激光通过光子晶体光纤时,由于自相位调制,在可见光和近红外区能够产生上百万等间隔的梳状频率,其频率间隔等于锁模脉冲的重复率。利用光频梳和倍频技术,把对光频的测量变为对射频的测量,这样就能够很容易地测出光的频率。使得光频测量精度和原子钟精度达到前所未有的高度,从而对物理学和计量学的发展有重要意义。