基于钽酸锂晶体的太赫兹波参量振荡器运转特性的研究

基于晶格振动模受激电磁耦子散射过程的基本原理,对由LiTaO₃（LT）晶体组成的太赫兹波参量振荡器（TPO）的输出调谐特性、增益和吸收损耗特性,以及基于硅棱镜阵列耦合装置的THz波输出特性等方面进行了详细的理论研究和分析.研究结果表明,基于LiTaO₃晶体A₁对称性晶格振动的特点以及自身优异的非线性光学特性,通过利用短波长抽运光、适当提高抽运能量以及缩短TPO谐振腔腔长等方法,完全可以实现LT-TPO的高性能运转,证明了LiTaO₃晶体是一种性能优良的TPO工作介质.理论计算结果及方法为以后的LT-TPO实验工作提供了详实的理论依据和实验指导. 关键词： 非线性光学 THz辐射 3晶体')" href="#">LiTaO₃晶体 电磁耦子     

微型化光纤法布里-珀罗传感器腔长一致性的控制研究

研究了光纤法布里-珀罗腔传感器的腔长一致性的控制技术.通过三维调整架组成微调装置来控制全光纤法布里-珀罗腔的腔长;结合法布里-珀罗腔的工作原理,利用光谱分析仪实时检测加工过程中法布里-珀罗腔的腔长并用装置予以修正;以热熔接的方法将毛细玻璃管与光纤加工成法布里-珀罗腔;利用超景深光学显微系统检查加工的法布里-珀罗腔的关键部位的结构,并对熔接点的牢固性进行了检测.实验结果和数据分析显示:法布里-珀罗腔的腔长得到了较好的控制及一致性,熔接部位的变形和对法布里-珀罗腔的性能的影响也很小.该工艺可用于制备全光纤法布里-珀罗腔传感器.     

短腔长复合式光纤法布里-珀罗压力传感器椭圆拟合腔长解调算法

建立了一种短腔长复合式光纤法布里-珀罗压力传感器反射光谱的模型,提出了一种双参数椭圆拟合腔长解调算法,并对腔长为26～30μm的复合式法布里-珀罗腔的解调进行了仿真。结果表明,采用双参数椭圆拟合算法进行腔长解调的最大误差仅为0.05μm。搭建了光纤法布里-珀罗传感器解调系统,在加压条件下对复合式光纤法布里-珀罗压力传感器进行了解调实验,实现了20 kHz的解调速率,验证了所提算法在解调短腔长复合式光纤法布里-珀罗压力传感器方面的可行性与实时性。     

光纤布拉格光栅法布里-珀罗腔纵模特性研究

分析了光纤布拉格光栅构成的法布里-珀罗（F-P）腔的透射谱特性，讨论了光栅带宽，反射系数相位因子以及腔长对F-P腔透射特性的影响，并对F-P腔随温度和应变的特性进行了分析，然后给出如何设计在光栅中心耦合波长处单模运转的法布里-珀罗腔.并提供了数值模拟结果和实验结果. 关键词： 光纤布拉格光栅 法布里-珀罗（F-P）腔 光纤激光器     

用于显示的透射型法布里-珀罗光调制器

提出了一种用于显示的,基于透射型法布里-珀罗干涉的微机电系统(MEMS)光学调制器。基于多光束干涉原理分析了调制器的光学特性,推导出了调制器结构的特征参量。分析表明,当调制器的腔长为cλ/4时,透射光可以实现暗态显示;当调制器的腔长取为零或cλ/2时,透射光可以实现亮态显示。通过控制法布里-珀罗腔长,就可实现调制器的明暗调制。理论上证明了该调制器用于显示的可行性。设计了一种基于微机电系统的透射型法布里-珀罗光学调制器结构,该调制器的理论衬比度达到150。仿真结果表明,该调制器具有2.4 V的低电压静电驱动性能。     

高精细度微透镜光纤法布里-珀罗干涉仪

通过在镀膜单模光纤端面制作微透镜,构造了微透镜光纤法布里-珀罗干涉仪.利用ABCD矩阵方法分析厂微透镜法布单-珀罗腔的模场.由于微透镜的会聚作用,法布里-珀罗腔模场可以和单模光纤模场良好的匹配,从而达到高精细度和低插入损耗.实验制作的微透镜光纤法布里-珀罗干涉仪,自由光谱区范围32.28 nm,精细度为78,峰值透射比为73%;在法布里-珀罗腔的光学腔长增加到100um的情况下,峰值透射比仍然大于50%.该微透镜光纤法布里-珀罗十涉仪制作容易、对设备要求低,可以封装成光纤法布里-珀罗滤波器和传感器,具有广泛的应用前景.     

基于法布里-珀罗调谐滤波器的傅里叶域锁模扫频激光光源

报道了一个光纤型1300 nm波段的傅里叶域锁模(Fourier domain mode locking, FDML)扫频激光光源, 用于扫频光学相干层析成像技术 (optical coherence tomography, OCT) 成像. 本实验扫频激光光源采用包含增益介质、调谐滤波器和延迟线组成的长腔激光谐振腔以及光功率增强单元. FDML扫频激光光源具有快速和高度稳定运转模式, 相位稳定性好. 基于法布里-珀罗调谐滤波器(fiber Fabry-Perot tunable filter, FFP-TF)的FDML扫频激光光源扫频范围为130 nm, 半高全宽为70 nm, 输出平均功率是11 mW. 与基于FFP-TF的短腔的扫频光源做了对比研究, FDML扫频光源速度从短腔的8 kHz提高到了48.12 kHz, 对应生物组织OCT成像轴向分辨率为7.8 μm, 比短腔的减小了1.9 μm. 关键词： 光学相干层析技术 扫频激光光源 傅里叶域锁模 法布里-珀罗调谐滤波器     

基于层状WS2调制激光泵浦的光学参量振荡中红外运转特性

光学参量振荡器是重要的中红外相干光源.近年来,在激光调制方面,二维过渡金属硫化物展现了非线性可饱和吸收特性,因此有望成为光学参量振荡器基频激光的优良调制元件.本工作中,首先,实验测量了层状二硫化钨(WS₂)调制固体激光的输出特性.其次,结合主动声光Q开关,实现了主被动双调Q光参量振荡的运转,得到了纳秒脉冲宽度的中红外脉冲,并研究了WS₂对光参量转换的优化特性,发现WS₂纳米片除了能够压缩脉冲、提高峰值功率外,还能缓解单主动调Q光学参量振荡器中的"输出饱和下降"现象,这种现象可能起因于砷酸钛氧钾(KTiOAsO₄, KTA)的制冷不均匀. WS₂的可饱和吸收效应能够显著压缩光斑,减少高斯光斑的边缘能量,因此能够缓解KTA的温度梯度分布,从而优化输出特性.最后,基于WS₂的非线性透过率曲线,考虑非均匀展宽机制和大信号下的非饱和吸收,计算了WS₂的可饱和吸收特性参数,并求解了层状WS₂调制光学参量振荡器的速率方程组.本...     

基于闪锌矿晶体中受激电磁耦子散射产生可调谐太赫兹波的理论研究

基于受激电磁耦子散射原理,采用已报道的利用非线性光学参量振荡方法产生可调谐太赫兹波的实验条件作为理论分析的实验模型,以GaAs,GaP, InP,ZnTe晶体为代表,计算分析了在闪锌矿晶体中参量振荡产生太赫兹波的吸收、增益特性,对输出THz波的调谐特性给出了详尽分析.分析太赫兹波高效耦合输出的腔型结构,并与掺氧化镁铌酸锂晶体组成的太赫兹波参量振荡器做对比. 关键词： 太赫兹波 太赫兹波参量振荡 电磁耦子 闪锌矿晶体     

薄膜法布里-珀罗滤光片中反射高斯光束分裂现象

提出了一种模拟薄膜法布里-珀罗滤光片中反射光束分裂现象的方法.根据反射率曲线，简单解释了产生这个现象的原因.实验上制备了薄膜法布里-珀罗滤光片，观察和测量了反射光束分裂的现象，理论计算基本与实验结果符合. 关键词： 薄膜 法布里-珀罗 光束分裂     

高性能85mm短腔光学参变振荡器的THz电磁波输出特性分析

报道了以MgO∶LiNbO3为非线性光学介质,采用85 mm长的法布里珀罗单谐振腔结构形式的光学参变振荡器,产生THz电磁波的实验结果。使用波长为1064 nm的Nd∶YAGQ开关脉冲激光器作为抽运光源,通过改变入射角度使参变振荡器的相位匹配条件发生变化。采用Si真空量热器,并利用THz波干涉测量仪;或通过测量闲频光的频率对产生的THz波频率进行了测量。实验表明该参变振荡器输出频率调谐范围为0.9~3.0 THz。在抽运光能量为20 mJ/pulse,脉冲宽度16 ns,重复频率50 Hz条件下得到输出峰值位于1.2 THz,能量为102.5 PJ/pulse的THz波输出。通过引入Si棱镜阵列减小了THz波在晶体中的全反射,从而提高THz波的能量输出。使用金属缝隙探测器,对辐射的THz波的波束水平方向空间分布进行了测量,分析了Si棱镜阵列的衍射效应对THz波束空间分布的影响。     

Noncascading THz-wave parametric oscillator synchronously pumped by mode-locked picosecond Ti:sapphire laser in doubly-resonant external cavity

A noncascading terahertz (THz) wave parametric oscillator synchronously pumped by a mode-locked picosecond Ti:sapphire laser whose average power was less than 1 W was demonstrated with a noncollinear phase-matching MgO:LiNbO₃ crystal in an external enhancement cavity doubly resonant for both pump (780 nm) and signal (781-784 nm) waves. In the external cavity, in which the pump wave enhanced so as to reduce the pumping threshold of parametric processes, the signal wave could also resonate and thus be enhanced simultaneously, resulting in a THz wave output at approximately 0.9 THz as the idler wave. The novel dual enhancement of pump and signal waves reduced the threshold pumping intensity to approximately 50 MW/cm², which was much lower than that of a conventional externally pumped THz wave parametric oscillator with a crystal.     

Widely tunable photonic crystal fiber Fabry-Perot optical parametric oscillator

We present a widely tunable low-threshold chi(3) optical parametric oscillator. The oscillator cavity is formed by butt coupling dichroic mirrors to either end of a highly nonlinear index-guiding photonic crystal fiber. This yields a singly resonant Fabry-Perot oscillator with a high feedback fraction for the resonant parametric sideband. The tuning range of the output parametric sideband stretches from 23 to 164 THz above the pump frequency. The threshold power of the oscillator is only 15 W.     

Pump-enhanced optical parametric oscillator generating continuous wave tunable terahertz radiation

We demonstrate a tunable cw terahertz (THz) parametric oscillator based on periodically poled MgO-doped lithium niobate, directly converting the 1030 nm pump wave into the THz regime. The tunability ranges from 1.2 to 2.9 THz at output power levels between 0.3 and 3.9 μW. To overcome the high pump threshold caused by THz absorption in the nonlinear crystal, we employ an enhancement cavity with a finesse of 500 at the pump wavelength. The intracavity pump threshold at 1.4 THz is measured to be 350 W for a crystal length of 2.5 cm.     

Dual-wavelength, two-crystal, continuous-wave optical parametric oscillator

We report a cw optical parametric oscillator (OPO) in a novel architecture comprising two nonlinear crystals in a single cavity, providing two independently tunable pairs of signal and idler wavelengths. Based on a singly resonant oscillator design, the device permits access to arbitrary signal and idler wavelength combinations within the parametric gain bandwidth and reflectivity of the OPO cavity mirrors. Using two identical 30 mm long MgO:sPPLT crystals in a compact four-mirror ring resonator pumped at 532 nm, we generate two pairs of signal and idler wavelengths with arbitrary tuning across 850-1430 nm, and demonstrate a frequency separation in the resonant signal waves down to 0.55 THz. Moreover, near wavelength-matched condition, coherent energy coupling between the resonant signal waves, results in reduced operation threshold and increased output power. A total output power >2.8 W with peak-to-peak power stability of 16% over 2 h is obtained.     

Broadband Sheet Parametric Oscillator for x~((2)) Optical Frequency Comb Generation via Cavity Phase Matching

We demonstrate a broadband optical parametric oscillation, using a sheet cavity, via cavity phase-matching. A21.2 THz broad comb-like spectrum is achieved, with a uniform line spacing of 133.0 GHz, despite a relatively large dispersion of 275.4 fs~2/mm around 1064 nm. With 22.6% high slope efficiency, and 14.9 kW peak power handling, this sheet optical parametric oscillator can be further developed for x~((2)) comb.     

Pump tuned wide tunable noncritically phase-matched ZnGeP2 narrow line width optical parametric oscillator

A line tunable singly resonant noncritically phase matched narrow band width ZnGeP₂ (ZGP) optical parametric oscillator pumped by the output idler radiation from a KTA OPO based on a 20 mm long KTA crystal pumped from a Q-switched Gaussian shaped Nd:YAG laser beam with a grating having grooves density 85 lines/mm has been demonstrated in the spectral ranges of 3–7 μm. The measured threshold of oscillation energy was 10 μJ. The conversion efficiency was 20.5% and slope efficiency of the ZGP OPO was 20% using a 23 mm long ZGP crystal at 26 mm cavity length. Line width of the generated infrared radiation from ZGP OPO was 37–60 nm.     

A narrowband optical parametric oscillator tunable over 6.8 THz through degeneracy with a transversely-chirped volume Bragg grating

An efficient nanosecond optical parametric oscillator (OPO) with output energies of 0.75 mJ using a periodically poled KTiOPO₄ crystal pumped at 532 nm and generating narrowband output continuously tunable over the range of 6.8 THz, between 1053 nm and 1075 nm, is demonstrated by employing a transversely-chirped volume Bragg grating. The tunable reflectivity spectrum of the chirped volume Bragg grating allowed a smooth transition between singly-resonant and doubly-resonant operation of the OPO without cavity rearrangement. This gave a unique possibility to experimentally verify theoretical predictions regarding the efficiency of type-I and type-0 phase matched degenerate OPOs pumped by multimode Q-switched lasers.     

An Ho:YAG Laser with Double-Pass Pumping and the ZnGeP2 OPO Pumped by the Ho:YAG Laser

We report an efficient Ho:YAG laser end pumped by Tm:YLF lasers with double-pass pumping. We achieve the maximum continuous wave (CW) output power of 46.0 W with a single-pass pumping and 50.2 W with a double-pass pumping, corresponding to a slope efficiency of 58.0% and 62.8%, respectively. In addition, we use the Ho:YAG laser as a pumping source of the ZnGeP₃ optical parametric oscillator (OPO) and obtain the maximum average output power of 14.2 W with a linear cavity and 17.0 W with a ring resonator, respectively.