掺镱硅酸盐激光玻璃的制备与光谱特性分析

采用高温熔融工艺制备了两块组分差别不大的掺镱(Yb3+)硅酸盐激光玻璃.测试出两块玻璃样品的吸收光谱和荧光光谱;计算了Yb3+掺杂玻璃的积分吸收截面、受激发射截面、荧光线宽、能级寿命、最小粒子数、饱和泵浦强度、最小泵浦强度等参数,比较发现样品的吸收截面图与倒易法计算所得的受激发射截面图线型相似,而与F-L法计算所得的受激发射截面图筹别较大,这与理论分析相吻合.两块玻璃样品的吸收光谱的线型基本一致,吸收主峰位于975 nm,次峰位于908 nm,这就说明影响激光玻璃吸收光谱线型的主要因素足玻璃基质的组成.两块玻璃样晶的荧光光谱差别比较大,样品1主峰位于993 nm,次峰位于1 029 nm;样品2主峰位于1 035 nm,次峰位于994nm,差别原因主要在于Yb3+离子的掺杂浓度不同.     

Numerical Simulation and Experimental Analysis of Photonic Band Gap in Hollow-Core Photonic Crystal Fibres

Based on the full-vector plane-wave method （FVPWM）, a hollow-core photonic crystal fibre （HC-PCF） fabricated by using the improved stack-and-draw technique is simulated. Under given propagation constants β, several effective photonie band gaps with different sizes emerge within the visible wavelength range from 575 to 720 nm. The fundamental mode and second-order mode lying in a part of PBGs are investigated. In the transmission spectrum tested, the positions of PBGs are discovered to be shifting to shorter wavelengths. The main reason is the existence of interstitial holes at nodes in the cladding region. In the later experiment, green light is observed propagating in the air-core region, and the result is more consistent with our theoretical simulation.     

一种阶梯结构的色散平坦光子晶体光纤的研究

以多极法理论为基础,提出了一种阶梯结构的光子晶体光纤.通过改变其内四层的三个结构参量(内两层孔孔径,外两层孔孔径和孔间距),实现色散绝对值在1.1～1.8μm的波段内变化仅为0.05～2 ps/(km·nm)的平坦甚至超平坦的特性.在此情况下对其有效模场面积进行数值模拟,充分展示了达到色散平坦和超平坦时,相对于传统光子晶体光纤,此种结构的光纤对芯区内光场的局域能力有很大程度的增强,其有效模场面积可仅为传统光子晶体光纤的1/30.最后,经过大量的数值计算和理论分析,归纳出若要此种阶梯结构的光纤在1.1～1.8μm的波段内达到色散平坦甚至超平坦特性的设计依据.     

飞秒泵浦不同锥长微结构光纤超连续谱的产生

对飞秒脉冲泵浦下,不同锥长及锥腰直径的微结构光纤的超连续谱产生进行了实验研究。采用“快速低温拉锥方法”,在保持d/Λ不变的情况下,对实验室自制的空气孔间距Λ=6.53 μm,归一化孔径d/Λ=0.79的微结构光纤进行了拉锥,分别得到6,8,10 mm等不同锥长微结构光纤。理论计算表明,随着锥长变长,锥腰直径变小,锥腰处零色散波长向短波移动：未拉锥及6,8和10 mm锥微结构光纤锥腰处零色散波长分别为1 129,885,806和637 nm。利用中心波长为810 nm,重复频率76 MHz,脉宽120 fs的钛蓝宝石飞秒激光器对拉锥后微结构光纤进行了实验研究：锥长为6 mm时,泵浦光中心波长位于整根光纤的正常色散区,锥腰的零色散点附近,内脉冲拉曼散射和级联四波混频是光谱初始展宽的主要因素。泵浦功率达到450 mW时,在可见波段390～461 nm及红外波段1 134～1 512 nm形成-5 dB的平坦宽带连续光谱。泵浦功率达到500 mW时,出现366～2 450 nm覆盖紫外、可见、近红外、中红外的超连续谱,其光谱红蓝移边缘已经接近实验用微结构光纤的传输带宽。锥长为8 mm、泵浦功率为450 mW时,在群速度匹配和群加速度失配的共同影响下,连续谱蓝移边缘达到366 nm,比6 mm锥时蓝移9 nm;锥长为10 mm时,由于锥腰处零色散点移动到可见光区域,可见区光谱仍能满足相位匹配条件。通过级联四波混频效应,在可见区域实现了频率上转换及光谱蓝移。泵浦光功率达到500 mW时,在382～412 nm得到谱宽仅为30 nm,转换效率达到27.7%的频率上转换。     

光子晶体光纤四波混频光谱中相位匹配特性的研究

与传统光纤不同,光子晶体光纤可以具有多个零色散波长,在四波混频光谱中,具有更丰富的相位匹配特性。目前很多文献报道了光子晶体光纤非线性光学特性的实验结果,但对其产生机理及光谱的变化规律缺乏详细的理论分析。为此对光纤中四波混频原理进行了分析,给出了高增益的相位匹配条件。利用多极法计算了光子晶体光纤的非线性系数及色散特性。对具有多个零色散波长光子晶体光纤的相位失配特性进行了分析,得到了相位匹配波长随泵浦波长及泵浦功率的变化规律。给出了相位匹配曲线,分析了不同色散曲线的相位匹配波长特点,两个零色散波长光子晶体光纤,在四波混频光谱中将激发出四个新的波长。实验得到了两个零色散波长光子晶体光纤的四波混频光谱,与理论分析一致,验证了相位匹配理论的可靠性。多个零色散波长光纤,能产生丰富的相位匹配曲线,会出现更多的四波混频波长,可以有效的控制光孤子及超短脉冲的四波混频及共振散射产生的光谱特性。为光子晶体光纤中基于四波混频的波长变换及超连续谱的研究提供了理论指导。     

Broad and ultra-flattened supercontinuum generation in the visible wavelengths based on the fundamental mode of photonic crystal fibre with central holes

By coupling a train of femtosecond pulses with 100 fs pulse width at a repetition rate of 76 MHz generated by a mode-locked Ti:sapphire laser into the fundamental mode of photonic crystal fibre(PCF) with central holes fabricated through extracting air from the central hole,the broad and ultra-flattened supercontinuum(SC) in the visible wavelengths is generated.When the fundamental mode experiences an anomalous dispersion regime,three phases in the SC generation process are primarily presented.The SC generation(SCG) in the wavelength range from 470 nm to 805 nm does not emerge significant ripples due to a higher pump peak power and the corresponding mode fields at different wavelengths are observed using Bragg gratings.The relative intensity fluctuations of output spectrum in the wavelength ranges of 530 nm to 640 nm and 543 nm to 590 nm are only 0.028 and 0.0071,respectively.     

Effects of matrices on Mie scattering in the mid-infrared region

Various Mie scattering systems, each having a transparent matrix, are studied in the mid-infrared region. Our three theoretical scattering systems correspond to a lossless scatterer, an anomalous dispersive dielectric scatterer and a metal scatterer, each in a non-air usual matrix. The refractive-index effects of the matrix on scattering and extinction efficiencies in the mid-infrared region are found to be quite different in different cases. Although the non-air usual matrix reduces scattering and extinction efficiencies in the first kind of system, it may or may not help scatter and extinguish the mid-infrared radiation in the second, and it has little effect on them in the third.     

基于“耦合-耦合-吸收”机理的超宽带单模单偏振微结构光纤

通过在高双折射微结构光纤包层构建缺陷并在其外侧空气孔镀金的方法，实现一种基于“耦合-耦合-吸收”滤波机理的新型单模单偏振微结构光纤（SMSP-MSF）。纤芯中需要滤除的偏振态模式能量通过“纤芯与缺陷芯耦合”和“缺陷芯与金缺陷耦合”两次耦合作用传递至镀金孔中，再利用金缺陷的等离子体共振效应对能量进行吸收，以实现宽带的单模单偏振传输。基于上述机理，利用全矢量有限元法，得到了两种宽带SMSP-MSF。所设计的正六边形晶格SMSPMSF的纤芯x偏振模式与缺陷芯模式、金层二阶表面等离子极化激元模式在多个波长分别谐振，实现380 nm的单模单偏振传输带宽。所设计的正方形晶格SMSP-MSF利用纤芯及缺陷芯相互垂直的排布方式，保证了纤芯与缺陷芯x偏振模式耦合，而y偏振模式不耦合，在1.55μm处实现了偏振消光比高达113 dB的高质量单模单偏振传输。