单模光纤中弯曲损耗的测试与分析

对单模光纤中弯曲损耗随弯曲半径(1～8 mm)和波长(1530～1565 nm)变化的实验进行了测试,结果显示弯曲损耗随弯曲半径和波长呈现振荡.理论分析表明由于光纤纤芯中的基模和在包层以及涂覆层中传播的Whispering-gallery模式之间的耦合,引起了弯曲损耗的振荡,理论分析结果和实验结果基本一致.     

光纤弯曲损耗特性的理论与实验研究

为了减小在长距离光纤通信中存在的弯曲损耗和利用光纤激光器中的弯曲损耗获得单模输出，利用速度法解释了光纤弯曲损耗机制，采用Marcuse理论研究了弯曲损耗随弯曲半径、波长和纤芯半径变化的关系。通过计算机仿真和实验得出弯曲损耗随弯曲半径的减小而增大，随波长的增大而增大，随纤芯半径的增大而增大，高阶模式的损耗大于低阶模式。利用这一结论就可以通过控制弯曲半径在临界半径以内来减小通信中的弯曲损耗，通过增大模场半径来实现光纤激光器中的单模输出。     

一种与标准单模光纤高适配的低弯曲损耗光子晶体光纤

设计并研制出一种与普通单模光纤高适配的低弯曲损耗光子晶体光纤. 结构采用光纤预制棒制作工艺上易于实现的掺锗芯六孔结构. 应用间接测量方法, 对其模式、弯曲及色散特性进行了系统的评估. 在波长1550 nm处研制光纤的模场面积为79.26 μm², 色散为21.7 ps·km^-1·nm^-1, 模场面积和色散特性与标准单模光纤具有高的适配性. 在光纤弯曲半径为5 mm时, 在波长1550 nm处的弯曲损耗为0.0365 dB/圈, 小于G.657B的弯曲损耗0.5 dB/圈. 研究成果为光纤到户用低弯曲损耗光纤的实用化奠定了良好的基础. 关键词： 光子晶体光纤 低弯曲损耗 光纤到户 高适配性     

掺钕光纤放大器的弯曲损耗对增益的影响

利用掺钕光纤放大器的粒子数速率方程、功率传输方程和光纤弯曲损耗公式,对光纤弯曲损耗所引起的增益变化进行了数值模拟,分析了对于不同半径和波长下光纤弯曲损耗对光纤增益的影响,结果表明,对于一定长度的光纤,其增益随弯曲半径的减小而减小,当弯曲达到一定值时,增益发生急剧的降低;随弯曲半径的减小,其增益谱线发生下移,这对实验研究有着重要的指导意义。     

光子晶体光纤的弯曲损耗振荡特性分析

综合运用弯曲光纤的等效直光纤模型、全矢量频域有限差分法及各向异性完全匹配层吸收边界,计算了两种类型(折射率引导型和带隙型)光子晶体光纤(PCF)的弯曲损耗.通过数值模拟弯曲损耗随弯曲半径的变化关系,证实了两种光子晶体光纤均具有弯曲损耗振荡特性.进而分析了两种光子晶体光纤弯曲损耗振荡的产生机理并给出了与损耗峰对应的包层模式.结果表明,振荡的产生源于基模与包层模式的耦合,其中,折射率引导型光子晶体光纤的弯曲损耗振荡机理类似于传统双包层光纤,带隙型光子晶体光纤弯曲损耗振荡的产生则是两种不同类型的包层模式共同作用的结果.     

光子晶体光纤弯曲损耗特性研究

对光子晶体光纤的损耗特性进行了分析，并在实验上对两种典型的光子带隙型和全内反射型光子晶体光纤进行了研究.分别对两种不同结构的光子晶体光纤在弯曲半径2~15 mm范围内的损耗进行了测量.与传统光纤损耗实验结果的对比表明，两种光子晶体光纤的弯曲损耗均不明显，具有很强的抗弯曲损耗能力.实验也证实了光子晶体光纤弯曲损耗存在临界弯曲半径，在大于临界半径的情况下，几乎没有弯曲损耗.从结构上分析并证明光子晶体光纤弯曲损耗随填充比(d/Λ)的增加而减小，填充比越高弯曲损耗越小.     

采用光纤光栅级联结构实现光纤延迟线

在使用光纤光栅实现皮秒级别时延的基础上,提出一种光纤光栅与单模光纤相结合的微秒级别级联结构,该结构可以实现中心波长1 550~1 553 nm范围内,间距为1 nm的窄波长反射型时延线,共1,1.5,2和2.5 μs四种不同的时延。将单波长反射的啁啾布拉格光纤光栅与103 m单模光纤连接构成延迟单元,再利用光环形器将4个延迟单元级联并使用内半径为3 cm的光纤绕线盘,将四种延时单元的传输光纤进行整合。借助光纤光栅的反射镜作用,控制不同波长光信号通过不同的传输距离,从而达到时延目的。本文通过对啁啾布拉格光纤光栅的反射谱进行仿真分析,发现相邻反射谱的旁瓣会出现交叠现象,因此使用六个切趾函数对旁瓣滤除。结果显示：不同切趾函数的滤除效果也不同,能够完全滤除旁瓣并且对反射谱包络影响最小的是柯西切趾函数,经柯西切趾后能使不同波长光信号在对应中心波长1 nm范围内反射率达到1,而其他位置均为0。由于使用光纤绕线盘整合延迟单元传输光纤会产生一定损耗,因此对弯曲损耗进行仿真分析,结果表明：弯曲半径相同时,损耗与工作波长成正比;工作波长相同时,弯曲损耗与弯曲半径成反比。当弯曲半径大于2.9 cm时,弯曲损耗曲线变化平缓并趋于0,因此当光纤绕线盘内半径为3 cm时保证了在减小延迟模块体积的同时又不会有过大的损耗。通过TDS784D型示波器对频率为2 000 Hz的信号经不同传输距离后的波形进行测试,结果显示经3 m和5 km传输线后信号的各项参数基本保持不变,经过长距离传输后,依然能保持原信号特性,因此使用103 m传输线可达到延迟目的。使用W-GGL型光功率计对不同频率下的输出功率进行测量,与直光纤的输出功率相比,当弯曲半径为2~3 cm时偏差较大,等于3 cm时偏差为0.18 dBm,大于3 cm时则无限趋近,因此设置绕线盘内半径为3 cm符合光纤延迟线的损耗范围。     

光波导-光纤自动调芯系统研究

设计了两种适用于光波导高精度自动对接耦合的调芯方案,从原理上克服了常规调芯过程中微变信号精确测试的困难。完成了调芯系统的光机电一体化、控制程序和接口界面。单模光纤作为标准波导的端面耦合自动凋芯试验显示,平均耦合损耗分别为0．075 dB(1310nm波长)和0．062 dB(1550nm波长),相应的标准误差分别为0．0099 dB和0．0066 dB．调芯过程在2min内完成。单模光纤-单模波导-单模光纤的对接耦合实验结果表明,端面耦合损耗平均值分别为0．140 dB(1310nm波长)和0．109 dB(1550nm波长),标准误差分别为0．0082dB和0．0107dB,调芯时间累计不超过8min。     

新型全固态准晶体结构大模场光纤特性研究

大模场单模光纤在高功率激光器、高功率光传输和高灵敏度传感器等领域具有重要意义.设计了一种新型超低损耗大模场单模光纤,包层空气孔由掺氟硅玻璃棒代替,掺氟硅玻璃棒排列呈六重准晶体结构.基于有限元法对光纤的传输特性进行了数值模拟.研究了光纤结构参量变化对模式特性和有效模场面积的影响.结果表明:波长在1064 nm处,有效模场面积高达5197μm2,基模的限制性损耗低于10-5dB/km,解决了大模场与低损耗之间的冲突;在1064—2000 nm波段内,基模与二阶模的限制性损耗相差7个量级,实现单模传输;半径为10 cm时,弯曲损耗小于0.01 dB/m,具有良好的低弯曲损耗特性.此光纤能够提高光纤热损伤阈值,减少接续损耗,全固态结构有效避免了空气孔塌陷,简化制备工艺,对高功率激光传输、光纤激光器和光纤放大器的发展具有重要意义.     

新型抗弯曲大模场面积光子晶体光纤

研制出一种新型抗弯曲大模场面积石英光子晶体光纤. 利用光子晶体光纤结构设计的灵活性, 通过规划缺陷的位置及空气孔的尺寸, 实现了大模场面积单模及低弯曲损耗特性.应用建立的实际光子晶体光纤特性分析模型, 研究了研制光纤的模式特性和弯曲特性, 在波长1064 nm处, 平直状态下光纤的模场面积可以达到2812 μm², 基模限制损耗为0.00024 dB/m, 高阶模限制损耗高于1.248 dB/m. 基模和高阶模之间的高传输损耗差, 保证了在获得大模场面积的同时实现单模传输. 弯曲半径和弯曲方向角所带来弯曲损耗变化的研究结果显示, 即使在弯曲半径小到5 cm时, 弯曲损耗也在10^-3 dB/m量级以下, 而且在弯曲半径为30 cm时光纤可承受的弯曲方向角范围扩展至-60°–60°. 研制的光纤具有良好的低弯曲损耗特性, 可有效解决非对称结构所带来的光纤弯曲特性对弯曲方向角敏感的问题. 该光纤在高功率光纤激光器、放大器及高功率传输等技术领域具有重要的应用价值. 关键词： 光子晶体光纤 大模场面积 低弯曲损耗 弯曲方向角     

High performance multilayer La/B4C mirrors with carbon barrier layers

Recent results from manufacturing multilayer La/B₄C mirrors at wavelengths above 6.7 nm with carbon barrier layers are presented. It is shown that maximum reflection R = 58.6% is attained at λ = 6.661 nm.     

Inherently gain flattened L band TDFA based on W-fiber design

We present here a detailed theoretical analysis for realizing an inherently gain flattened L⁺ band thulium doped fiber amplifier (TDFA), based on a depressed inner-clad (W-fiber) design, wherein the inherent gain flattening is achieved by an optimized bend induced leakage loss. The leakage loss characteristics of W-fiber have been used to suppress higher wavelength amplified stimulated emission (ASE) in the designed TDFA, which otherwise depletes the population inversion in the amplifier, making it almost impossible to obtain high gain for wavelengths in and close to the conventional L-band. It has been shown through simulations that 20 dB net gain (±0.3 dB ripple) is achievable over 32 nm bandwidth (1604-1636 nm), using this design pumped with 160 mW of power. We also show that inherent gain flattening leads to redistribution of power among signal wavelengths, and hence an inherently gain-flattened TDFA is much more efficient as compared to a configuration that uses discrete filters for gain flattening. The net gain value and gain flattening of the designed TDFA module have been tested against tolerance with respect to fiber parameters as well as bend radius. This is for the first time to the authors knowledge that inherently gain flattened L⁺ band operation has been shown using TDFAs.     

Transmission of slow light through photonic crystal waveguide bends

The spectral dependence of the bending loss of cascaded 60 degrees bends in photonic crystal (PhC) waveguides is explored in a slab-type silicon-on-insulator system. An ultralow bending loss of (0.05 +/- 0.03) dB/bend is measured at wavelengths corresponding to the nearly dispersionless transmission regime. In contrast, the PhC bend is found to become completely opaque for wavelengths corresponding to the slow-light regime. A general strategy is presented and experimentally verified to optimize the bend design for improved slow-light transmission.     

Optical constants and their dispersion of Ag-MgF2 nanoparticle composite films

Ag-MgF2 composite films with different Ag fractions were prepared through a co-evaporation method.Microstructure analysis shows that the films are composed of amorphous MgF2 matrix and embedded fcc-Ag nanoparticles. The optical constants and their dispersion of the films, within the wavelength range of 250 - 650 nm, were measured by reflecting spectroscopic ellipsometry. The maximum of the imaginary part ε" of the complex dielectric permittivity attributing to the surface plasmon resonance polarization of the Ag nanoparticles in an Ag-MgF2 film, and the tangent of the phase-shift angle δ resulting from the dielectric loss of the film, occur at λ = 435 nm and λ = 420 nm, respectively. Based on Maxwell-Garnett effective medium theory, the experimentally observed dispersion spectra were reasonably described.     

Raman scattering and luminescence of yttria nanopowders and ceramics

We have studied Raman scattering in yttria nanopowders and ceramics that was excited by radiation at wavelengths of 514.5 and 632.8 nm. We show that, in undoped nanopowders and cubic phase of doped yttria ceramics, only the Raman scattering by phonons is observed, with no other Raman scattering centers having been revealed. In nanopowders of the monoclinic phase, we have observed an additional Raman line with a Raman shift of 1093 ± 4 cm^?1. If all the objects under investigation are excited by the radiation at a wavelength of 514.5 nm, their spectra exhibit four series of photoluminescence lines, two of which (at λ = 521–523 and 538–564 nm) are emitted by Er³⁺ ions, “impurity” dopants, while the other two lines (at λ = 607–635 and 644–684 nm) are emitted by intrinsic centers. Under excitation by the radiation at a wavelength of 632.8 nm, only a series of bands at λ = 644–684 nm is emitted. In addition to these photoluminescence bands, neodymium-doped ceramics show photoluminescence bands of Nd³⁺ ions. We have shown that intrinsic luminescence centers, which occur in all the examined specimens, are capable of acting as acceptors with respect to neodymium ions excited to the upper laser level.     

Coloring of silica glass with silver nanoparticles

The possibility of doping of surface layers of optical fused silica with silver nanogranules upon heating of a thin Ag film on the silica surface by a CO₂ laser beam (P ≈ 30 W, λ = 10.6 μm) is established. The effect of exposure time on the doped layer structure has been investigated. The absorption band of the colloidal solution of Ag in silica has been studied. It is shown that this band is homogeneously broadened and its peak (at 420 nm) corresponds to the small volume filling factor (q < 0.1) at an average granule radius of about 3 nm. Based on the measurements of the radial distributions of the reflectance and refractive index over the doped region at λ = 633 nm, it is revealed that the doped layer is an area-irregular asymmetric step waveguide.     

离心压缩机弯道最佳r/b值研究

本文将叶轮、无叶扩压器和弯道组合一起对弯道进行研究,充分考虑了叶轮出口的射流/尾迹结构对弯道进口气流的影响.通过对不同弯道半径r与流道宽度b的比值r/b条件下,数值研究其对离心压缩机基本级气动性能的影响.对弯道内部流动及r/b值变化与离心压缩机级的总体性能的变化关系进行详细的对比分析.研究结果表明:r/b值的变化对弯道出口气流角影响显著,并存在一个使级效率为最大值的最佳r/b值。壁面摩擦是引起弯道内部总压损失的主要因素。