Design of low-confinement-loss and highly birefringent index-guiding photonic crystal fibers

We present a systematic scheme to achieve both high birefringence and low confinement loss in index-guiding photonic crystal fibers （PCFs）, using a structurally-simple PCF with finite number of air holes in the cladding region. By increasing the size of the outermost-ring air holes in the cladding region, highly birefringent PCFs with low confinement loss can be successfully achieved. The design strategy is based on the fact that the modal birefringence of PCFs is dominated by the inner-ring air holes in PCF, which is verified by a full-vector finite element method with anisotropic perfectly matched layers. Numerical results show that modal birefringence in the order of 10-3 and confinement loss less than 0.1 dB/km can be easily realized in the proposed PCF with only four rings of air holes in the cladding region. We expect that such fibers will be much easier to be fabvicated than those with more air holes in the cladding region.     

低折射率芯PCF基模损耗的数值模拟与分析

应用多极法理论计算了低折射率芯光子晶体光纤（PCF）基模的损耗并与未掺杂芯PCF进行了比较，发现可以从损耗的角度来理解低折射率芯PCF的截止特性：传输波长靠近短波长时，模式的损耗会突然变大，从而导致基模截止；而处于长波长时，这种光纤的传输特性和普通PCF相类似。通过改变纤芯折射率的大小和包层中空气孔的大小，可以对光纤的截止波长进行调节。     

高双折射光子晶体光纤特性分析

建立了基于透明边界条件(TBC)的全矢量迦辽金有限元法(FEM)分析二维光子晶体光纤(PCF)的模型,并对椭圆芯等5种高双折射光子晶体光纤基模的模式双折射、限制损耗及色散特性进行了数值分析和比较.通过减小内包层中沿x方向的空气孔,增大沿y方向的空气孔构成的一种光子晶体光纤的模式双折射在波长1550 nm处高达5.96×10-3,而椭圆芯光子晶体光纤为1.52×10-3.研究表明,可通过增加内包层中两个正交方向上空气孔的尺寸差来获得高双折射;同时还得出内包层中放大的空气孔减小限制损耗,增加色散,而减小空气孔尺寸带来的影响则刚好相反;内包层上空气孔数量越少,色散越平坦.     

掺Yb3+铝硅酸盐玻璃纤芯的光子晶体光纤

为了获得用于掺Yb3+脉冲光纤激光器的具有反常色散的光子晶体光纤,设计了一种掺Yb3+铝硅酸盐玻璃纤芯的结构,包层部分为普通的六边形结构,分布着直径相同的空气孔,其纤芯横截面为椭圆形,在包层和纤芯之间设计了4个小椭圆空气孔。研究了包层的空气孔直径d与空气孔中心间距Λ以及二者的比值d/Λ这些参量变化时,色散随波长变化的情况;同时研究了4个小孔对色散和双折射的影响。结果表明,这一结构的光子晶体光纤,当Λ=2.3μm、d/Λ=0.5时色散呈现反常色散,作为掺Yb3+脉冲光纤激光器的增益部分是可行的。该研究对掺Yb3+光子晶体光纤在脉冲光纤激光器方面的使用是有帮助的。     

Dispersion-flattened photonic crystal fiber with large effective area and low confinement loss

A photonic crystal fiber (PCF) can realize a flat dispersion over a wide wavelength range that cannot be realized with a conventional single-mode fiber. However, the confinement loss tends to increase in a conventional dispersion-flattened PCF (DF-PCF) that has uniform air holes. In this paper, a novel PCF that has two cladding layers with different effective indices is proposed. The authors numerically show that the proposed PCF can achieve an ultralow dispersion variation of less than 0.8 ps/nm/spl middot/km in all telecommunication bands, with both a large effective area greater than 100 /spl mu/m/sup 2/ and a low confinement loss less than 0.01 dB/km.     

混合双包层高双折射光子晶体光纤的特性

提出了一种新型的混合双包层结构的光子晶体光纤。利用多极法对光纤基模的模场分布、双折射、限制损耗及色散特性等进行了数值模拟,通过调节包层空气孔的孔径大小可以有效地控制光纤的双折射和限制损耗特性。结果发现:新设计的光纤具有高双折射低限制损耗特性,光纤结构参数为=1.0 m,d1=d2=d3=0.8 m时,该光纤在C波段（1.53~1.565 m）及L波段（1.57~1.62 m）呈现负色散及负色散斜率。在波长为1.55 m处,双折射高达10-2,限制损耗小于10-5 dB/m。     

高双折射高非线性低损耗八边形光子晶体光纤特性

为了同时实现高双折射高非线性并得到低损耗,设计一种在光纤纤芯附近引入椭圆形空气孔和圆形空气孔组成的新型优化的八边形光子晶体光纤。采用全矢量有限元法结合各向异性完美匹配层,对该光纤的有效面积、非线性、双折射和损耗特性进行了模拟分析。数值模拟结果表明,通过选择适当的结构参数,在波长1.55 m处,该光纤具有高双折射高达B=1.6810-2,比普通光纤高两个数量级,高非线性系数为=60 W-1km-1和低损为0.6 dB/km。这种具有高双折射高非线性系数的光纤可用于光通信、偏振敏感的各种设备和产生超连续普等领域。     

椭圆孔微纤芯光子晶体光纤的数值模拟

提出了一种在纤芯引入四个近矩形排列的椭圆空气孔,包层空气孔呈阶梯结构的高双折射光子晶体光纤,采用全矢量有限元方法,对光纤基模的模场分布、双折射、色散、限制损耗、有效模面积及非线性系数等特性进行了数值模拟.这种设计为获得高双折射光子晶体光纤提供了一种新的方法,为改善光子晶体光纤其他性能(如色散、非线性特性)提供了一种新的...     

Highly birefringent photonic crystal fibers with flattened dispersion and low confinement loss

A highly birefringent index-guiding photonic crystal fiber (PCF) with flattened dispersion and low confinement loss is proposed by introducing two small air holes with the same diameter in the core area. The fundamental mode field, birefringence, confinement loss, effective mode area and dispersion characteristic of the fibers are studied by the full-vector finite element method (FEM). Simulation results show that a high birefringence with the order of 10 -3 and a low confinement loss of 0.001 dB/km are obtained at 1550 nm. Furthermore, flattened chromatic dispersion from 1450 nm to 1590 nm is obtained.     

High birefringence photonic bandgap fiber with elliptical air holes

In this paper, we proposed a high birefringence photonic bandgap fiber (PBGF) with elliptical air holes in cladding and circular air hole in core. The forbidden gaps of the honeycomb structure are calculated when the circular air holes are deformed to the elliptical shape. And the birefringence of the PBGFs is investigated by using a full-vector finite element method (FEM) and the numerical results are presented.     

Design of nonlinear photonic crystal fibers with ultra‐flattened zero dispersion for supercontinuum generation

The study reports on the design and performance of two air‐filled and two partial ethanol‐filled photonic crystal fiber (PCF) structures with a tetra core for supercontinuum generation. The PCFs are nonlinear with ultra‐flattened zero dispersion. Holes with smaller areas are used to create a tetra‐core PCF structure. Ethanol is filled in the holes of smaller area while the larger holes of cladding region are air‐filled. Optical properties including dispersion, effective mode area, confinement loss, normalized frequency, and nonlinear coefficient of the designed PCF structures are investigated via full vector finite difference time domain (FDTD) method. A PCF structure with lead silicate as wafer exhibits significantly better results than a PCF structure with silica as wafer. However, both structures report dispersion at a telecommunication wavelength corresponding to 1.55 μm. Furthermore, the PCF structure with lead silicate as wafer exhibits a very high nonlinear coefficient corresponding to 1375 W^?1 km^?1 at the same wavelength. This scheme can be used for optical communication systems and in optical devices by exploiting the principle of nonlinearity.     

光子晶体光纤的设计与应用研究综述

光子晶体光纤具有较强的可设计性,一般通过改变光子晶体光纤包层中空气孔的大小、形状或者排列方式对光纤的传输特性进行调节,以此实现高双折射、高非线性、平坦色散及低限制性损耗等特性。光子晶体光纤的传输特性在不同领域中具有较大的应用价值,如分布式传感、飞秒激光器和气体传感器等。文章首先介绍了光子晶体光纤的结构特征以及与普通单模光纤的区别,在此基础上针对各种典型的光子晶体光纤结构分析了其色散和非线性等传输特性。详细介绍了基于光子晶体光纤的分布式光纤传感、飞秒激光器和气体传感器的传感机理以及达到的传感性能,并与非基于光子晶体光纤的传感器的传感性能进行了比较,验证了基于光子晶体光纤传感器的优异性能。最后对光子晶体光纤的发展及应用进行了总结与展望。     

A kind of photonic crystal fiber with high birefringence and low cofinement loss

The triangular-lattice highly birefringent photonic crystal fibers（PCFs） with gradually increasing diameter of the air holes along radial axis are put forward. The modal birefringence, dispersion and confinement loss of the fundamental mode are simulated by full vector Galerkin finite element method（FEM） with a perfectly matched layer（PML）. The results show that this PCF can keep low confinement loss when the rings of air holes are few. When the wavelength is 1.55 μm, the birefringence, the confinement loss of quick-axis and slow-axis are 1.365×10^-3, 0.017 dB/m and 0.051 dB/m, respectively. A new way is proposed to fabricate polarization-mainting fibers with high performance.     

Analysis on photonic crystal fibers with circular air holes in elliptical configuration

In this paper, two novel structures of photonic crystal fibers (PCFs) containing elliptical rings of circular air holes are presented. The circular air holes in both structures are arranged in seven elliptical rings, but the number of holes in each ring is different for these structures. Moreover, air hole diameter and hole-to-hole pitch are altered along the distance from the center of the fiber’s cross section. Properties, such as birefringence and confinement loss, of these structures with different numbers of air hole rings are numerically analyzed by using the multipole method. Numerical results show that a high birefringence of 1.626 × 10⁻³ can be reached at the wavelength of 1.55 μm, and a low confinement loss on the order of 10⁻⁸ dB/m can be achieved at the same wavelength. Furthermore, it is also found that elliptic ratio obviously affects birefringence and confinement loss, but the number of air hole rings has little impact on birefringence.     

宽带色散平坦光子晶体光纤的优化设计与特性分析

设计了一种第一层为椭圆空气孔缺陷的宽带色散平坦光子晶体光纤,借助全矢量有限元法对这种结构的光子晶体光纤的色散特性、模场面积、双折射和限制损耗特性进行了数值模拟.结果表明改进的光子晶体光纤的色散曲线可以在很宽的波长范围内保持色散平坦并具有较低的色散值,其模场面积较未改进光子晶体光纤的模场面积要大,光纤的限制损耗变小且双折射也相当小.主要分析了这种光纤的结构参数的优化后,光纤的色散特性、有效模面积、双折射以及限制损耗特性的变化规律,最终设计了在1 200～1 800 nm波长范围内超平坦色散的光子晶体光纤.     

Design of Wideband Single-Polarization Single-Mode Photonic Crystal Fiber

The present paper proposes a novel design for achieving single-polarization single-mode (SPSM) operation in photonic crystal fiber (PCF), using a rectangular-lattice PCF with two lines of three central air holes enlarged. The proposed PCF that is composed entirely of silica material is modeled by a full-vector finite element method with anisotropic perfectly matched layers. The position of the region of single polarization can be tuned freely by adjusting the size of the central enlarged air holes. Using this structure, an SPSM PCF with confinement loss less than 0.1 dB/km within the wavelength range from 1.20 to 1.66 mum and effective mode area about 5.9 mum² at 1.55 mum has been successfully designed. The proposed fiber is a nonlinear SPSM, which may be useful for nonlinear optical applications or applications with a wide SPSM operating bandwidth requirement     

Design of a bending-insensitive single-mode photonic crystal fiber

We present a design of a bending-insensitive single-mode photonic crystal fiber (PCF) based on the existence of a triangular core formed by three neighboring air holes missing in the center of the fiber, and two cladding layers of air holes with different diameters. By optimizing the design parameters, the designed PCF with bending-insensitive characteristics can match the requirements of fiber to the home applications very well. Simulation results show that the designed PCF has an effectively single-mode operation, a small bending loss below 0.15 dB/m for the bending radius of 5 mm, as well as a stable effective mode area of 80 μm² whatever the designed PCF is straight or bent, which can connect well with conventional single-mode fibers (SMFs).     

Birefringence and Confinement Loss Properties in Photonic Crystal Fibers Under Lateral Stress

Using the finite-element method, we investigate lateral stress-induced novel characteristics of birefringence and confinement loss in a photonic crystal fiber (PCF) of hexagonal symmetry. The results of simulation show us strong stress dependence of birefringence and confinement loss. We also find that the contribution of the geometrical effect that is related only to deformation of the PCF and the stress-related contribution to birefringence and confinement loss are entirely different. Furthermore, polarization- dependent stress sensitivity of confinement loss is proposed in this letter.      

Numerical modeling of photonic crystal fibers

Recent progress on numerical modeling methods for photonic crystal fibers (PCFs) such as the effective index approach, basis-function expansion approach, and numerical approach is described. An index-guiding PCF with an array of air holes surrounding the silica core region has special characteristics compared with conventional single-mode fibers (SMFs). Using a full modal vector model, the fundamental characteristics of PCFs such as cutoff wavelength, confinement loss, modal birefringence, and chromatic dispersion are numerically investigated.     

Design on a highly birefringent and highly nonlinear tellurite ellipse core photonic crystal fiber with two zero dispersion wavelengths

In this paper, a new photonic crystal fiber (PCF) with two zero dispersion wavelengths (ZDWs) based on the tellurite ellipse core is designed. The air holes in the cladding region have a V-shape distribution, which can increase the birefringence. By adjusting the size of tellurite ellipse core, different birefringence and nonlinearity coefficient can be obtained, and the dispersion can also be tailored. When the long axis of the tellurite ellipse core is 0.5 μm and the short axis is 0.25 μm, the birefringence of 7.66 × 10⁻² and nonlinearity of 3400 W⁻¹ km⁻¹ around 1550 nm are obtained. This PCF structure provides a way to get the high birefringence and nonlinearity at the same time, which can find extensive applications in the optical communication and sensor system.