基于角谱传播理论的衰荡腔光场传输模型及调腔评价准则研究

在光腔衰荡技术中,腔失调与腔损耗观测值之间存在复杂的非线性映射关系,导致调腔过程易陷入局部寻优,对测量准确性造成影响.本文基于角谱传播理论,建立了一种衰荡腔高斯光场传输模型,对典型调腔评价准则进行对比,并以模型仿真与实验研究相结合的方式,验证模型合理性.在仿真模型和实验系统中对特定腔镜施加二维倾斜角度扫描,获取两种典型调腔评价准则(即光强峰值和衰荡时间)的二维扫描分布.对比光强最大峰值和最长衰荡时间所对应的腔损耗观测状态.仿真结果表明光强最大峰值对应的腔损耗观测误差更小,观测重复性更高.实验结果同样表明光强最大峰值评价准则具有更好效果.模型仿真和实验研究的结果验证光强最大峰值评价准则在仿真和实验中具有更好的调腔重复性精度.同时,仿真与实验结果基本吻合,初步验证了本衰荡腔光场传输模型的合理性.本光场传输仿真模型对光腔衰荡技术在测量应用、光场响应及自动化调腔技术等方面的研究具有一定参考意义.

单模锥形光纤锥区光场及超短脉冲的传输特性

根据光波导理论,采用数值方法分析了单模锥形光纤锥区传输常数和光场分布的变化情况.采用分步傅里叶法数值求解广义的非线性薛定谔方程,对超短脉冲在锥区的传输演化进行了研究.结果表明:传输常数沿拉锥方向缓慢减小,在拉锥末端迅速减小;在拉锥初始阶段,能量主要集中在纤芯中,"转换点"之后能量在纤芯和包层中重新分布,光强在拉锥末端变强;脉宽小于80fs的超短脉冲沿锥区传输时,沿拉锥方向,脉冲不断展宽,而当脉宽大于80fs时,脉冲展宽不明显.

一种快速实现光场传输的算法研究

针对目前实现光场传输的两种算法无法同时满足运算速度和精细度的问题,提出了矩阵相乘算法,阐明了其实现思想,推导了其实现过程。结合激光相干合束实例进行了仿真分析,结果表明,对于六路高斯光束的相干合束,快速傅里叶变换算法耗时短,但无法得到精确的计算结果;积分算法和矩阵相乘算法均可获得远场准确的光强分布,但积分算法需耗时15.7 h,而矩阵相乘算法仅需2 s,提高了运算效率。证明了矩阵相乘算法具有快速、准确的优点。

基于FDTD的高深宽比沟槽结构低相干显微干涉信号仿真分析

低相干垂直扫描干涉技术是微结构形貌特征参数无损检测的有效手段。但当微结构的沟槽深宽比高于5∶1时,遮挡效应以及阶跃边缘复杂的衍射效应会导致本应仅包含一个包络的垂直扫描测量干涉信号异常,形成两个甚至多个包络,继而影响形貌检测结果。本文解析低相干垂直扫描干涉的测量过程,采用时域有限差分法对低相干显微干涉测量系统的显微成像、相干扫描测量过程进行数值仿真,计算待测微结构表面返回场及显微成像后的像面干涉场,得到低相干显微干涉信号。分别仿真了深宽比为5∶1、80∶3的硅基沟槽微结构的干涉信号,并与实验室自研的Linnik型低相干垂直扫描干涉系统对沟槽微结构的检测信号进行对比,匹配其高深宽比沟槽结构干涉信号的双包络及幅频双峰性的特征,验证所提方法的准确性。该仿真方法可应用于实测前对被测结构低相干显微干涉信号的先验性仿真计算,通过提前分析信号特征,为形貌复原算法的选取及改进指引优化方向。

双M-Z干涉仪中Y分支波导设计与分析

介绍了分支波导和S形弯曲波导,设计了对称双Y分支S形弯曲波导的结构,并计算了其弯曲损耗。对1/2Y和1/4Y分支波导的传输及弯曲损耗随长度的变化进行了模拟仿真,结果表明,设计的双Y分支波导达到了低损耗的要求。最后对双M-Z干涉仪的光场传输进行了二维各向同性仿真,得到其光场传输图和折射率分布图。结果表明,设计的双M-Z干涉仪的分光比可达1∶1∶1∶1。

拉盖尔-高斯幂指数相位涡旋光束传输特性

建立了一种新型拉盖尔-高斯幂指数相位涡旋光束(PEPVB)理论模型,并基于广义柯林斯公式建立了拉盖尔-高斯PEPVB在傍轴近似下的传输理论模型。采用MATLAB数值计算软件仿真了拉盖尔-高斯PEPVB的自由空间传输特性和聚焦特性与径向阶数、拓扑荷数、幂指数和传输距离的关系。研究结果表明拉盖尔-高斯PEPVB及其传输特性不仅与幂指数和拓扑荷数有关,还与拉盖尔-高斯多项式的径向阶数有关,且在传输过程中光束能量沿着环形旋转聚集。这为光学操控微粒沿弯曲路径移动并避开障碍物打下了基础,对促进新型光场调控的理论及应用研究具有重要的意义。

Quantum Information Transfer from a Double Quantum Dot System to a Cavity Field

In this paper, we propose a scheme to realize quantum information transfer from a double quantum dot （DQD） system to a quantized cavity field. The DQD and the cavity field are treated as a two-state charge qubit and a continuous-variable system, respectively. It is shown that quantum information encoded in the two-state DQD system can be transferred to quantum states of the cavity field with a continuous-variable basis through appropriate projective measurements with respect to the DQD.

Effect of Ultrafine Particles on Flow Field and Transport Properties near the Interface Around a Moving Bubble

Laser Doppler Anemometer has been used to measure the flow field characteristics near the interface around a moving bubble in the presence of ultrafine particles. In order to model a moving bubble, the bubble was fixed into the counter flow liquid by a metal mesh. Experimental materials are air and water, and the particles are complex oxidate powder. Experiments were carried out under the operating conditions: the liquid flow velocity u 0 is 12.6 cm/s, the equivalent diameter d e is 0.6 cm, the mass concentration of particle is 0.2 0 0 ,the average particle diameter is about 10 nm and the density is 2 g/cm 3. The velocity profiles of both frontal and tail vortex areas were measured respectively. The experimental results show that the velocity fields are obviously changed in the existence of particles. In the frontal area of the bubble, both tangential and normal velocities decrease due to the presence of particles, but in tail vortex area, the tangential velocities increase remarkably, and normal velocities rise gradually from the center towards the fringe in the opposite tendency to that of no particles. The influences of flow field change in the presence of particles on gas liquid mass transfer are analyzed and discussed.