Au粒子在不同基质中Mie散射特性的研究

根据Mie散射理论,给出了金属粒子的散射、消光和吸收截面以及散射场强度的计算公式,并数值计算了在λ=r=1μm时,金属Au粒子在五种不同的基质中的散射截面和散射光强,结果表明基质折射率越大散射特性越强。     

金属类散射体的Mie散射特性研究

基于Mie散射理论研究发现,各种金属在中红外区的的散射行为极为相似,是一种反照率极高但散射效率极低的散射体,数值研究揭示了这类散射体系的光学截面以及散射强度的分布的内在联系.     

基于Mie散射理论的MgF_2颗粒散射特性研究

本文应用Mie散射理论对微球体颗粒光散射的性质进行了理论分析与数值计算,得到了吸收截面与波长,散射强度与散射角以及散射强度与参数x的关系。结果表明,入射波长在300~4800 nm,粒子的吸收截面都为零;当λ>4800 nm,吸收截面随着粒子半径的增大而增大。     

高分子介质中Al_2O_3微粒子的光学截面及散射强度分布的计算

本文利用 A.L.Aden和 M.Kerker微粒子 Mie散射理论计算了处于高分子介质中的Al2 O3微粒子的消光截面、散射截面以及散射强度分布函数 ,并和它们在空气介质中的结果进行了比较。     

基于Mie散射理论的铌酸锂晶粒散射特性

基于Mie散射理论,对铌酸锂晶粒光散射特性进行了理论分析与数值计算,得到了散射强度分布、偏振度与散射角、散射强度与粒子尺寸参数,以及光学截面与粒子半径的关系。研究表明:前向散射占优势,并随粒子半径的增大而增强;当粒子半径为0.1 μm 左右,散射截面和吸收截面达到最大值。     

基质折射率对金属粒子散射特性的影响

基于Mie散射理论,给出了金属粒子的散射、吸收和消光截面以及散射场强度的计算公式,并计算了三种金属(金、银、铜)粒子在不同折射率基质中的光学截面和散射强度.结果表明,在近红外区,这三种金属粒子的散射行为随基质折射率的变化规律相同,折射率越大散射特性越明显.     

TiO2 颗粒紫外区Mie散射特性

应用Mie散射理论对紫外光下TiO₂微粒光散射特性进行了理论分析与数值计算,得到了散射强度分布、偏振度与散射角、散射强度与参数X以及光学截面与粒子半径的关系。结果表明,前向散射强度随着粒子半径的增大而增强;当粒子半径为50 nm左右,散射截面和吸收截面达到最大值。     

基质折射率对金属粒子散射特性的影响

基于Mie散射理论，给出了金属粒子的散射、吸收和消光截面以及散射场强度的计算公式，并计算了三种金属粒子在不同折射率基质中的光学截面和散射强度。结果表明，金属粒子的散射行为随基质折射率的变化规律相同，折射率越大散射特性越明显。     

皮肤组织可见与近红外Mie散射光学特性分析

依据Mie单次散射理论, 并考虑到皮肤组织复折射率实部的色散, 分析了在可见与近红外波段皮肤组织对光的吸收、散射及散射的方向特性。研究表明, 散射系数和吸收系数均随皮肤组织中散射粒子半径的增加而增加, 而且, 对于大粒子, 在某一波长处表现出强烈的散射和吸收特性。当粒子半径大于临界半径时, 散射系数呈现振荡特性, 随着折射率虚部的增加, 振幅减小。皮肤组织呈现前向散射特性, 且散射粒子的半径越大, 前向散射特性越明显。     

关于折射率对散射光场分布影响的研究

根据Mie散射理论,采用理论计算和实验相结合的手法,研究了光散射现象以及散射介质的折射率对散射光场分布的影响.通过对空气中不同折射率的散射介质形成的散射光场光强的实验比较,论证了散射介质折射率的实部变化对散射光强的影响不大,其主要影响是通过对相位的变化来实现的,也即散射介质折射率的虚部变化对光强的影响很大,在实际应用中不可忽略.这一结论对以散射光场的分布为基础的各种研究具有一定的指导意义.     

A bubble detection technique based on light intensity and Mie scattering theory for spinning solution

A novel bubble detection technique based on light intensity and Mie scattering theory for spinning solution is presented theoretically and experimentally. With the light intensity in every direction, the particle or bubble size distribution can be calculated with the Mie scattering theory. The light intensity distribution in every direction, corresponding to the light intensity received by every assumed annulus of the detector has been calculated theoretically. According to the light intensity distribution, the size distribution of bubbles can be deduced. A series of standardized polystyrene micro-sphere (with 7 μm diameter) solution has been used not only as sample for experiments and calibration, but also as the bubbles in the glycerin. Theoretical and experimental results show that the technique can be used for bubble detection, in order to improve the traditional bubble detection scheme, and to lower production costs.     

红外区磷化稼散射强度的计算与分析

根据Mie散射理论,对磷化稼粒子光散射特性进行了数值计算与理论分析,得到了散射强度与散射角、入射波长以及偏振度与散射角的关系。研究表明,红外波段光散射很小,前向散射占有优势,粒子半径越大,前向散射越强,并且在散射角900方向上能观测到线偏振光,对研究GaP红外光学特性提供了理论参考。     

球形粒子Mie散射特性分析

越来越多的与微粒相关的技术问题在许多领域出现,这些问题都与Mie散射理论有关。利用Matlab改进算法,对球形微粒子Mie散射特性做了较为全面和深入的分析,有助于Mie散射理论的研究和应用。     

Nanoparticle size characterization by laser light scattering

Spherical semiconductor nanoparticles (ZnS) were specially fabricated by an inexpensive chemical route. The scattering profile of the nanoparticles was investigated by laser light scattering technique. A beam of polarized light from a diode laser (λ ₀ ≈ 630 nm) was allowed to fall on the nanospheres embedded in flexible host matrix Polyvinyl Alcohol (PVA). The light scattered from the samples were detected by means of analyzer mounted photodiode array from 10° to 170° in steps of 1°. Signals from the detectors were interfaced with a high resolution data acquisition system and the whole experiment was carried out in differential mode. Size of the nanoparticles was obtained by using Mie theory and verified by T-matrix approach. The results obtained agree with the XRD and TEM results.      

Two-particle characterization by pulse induced and time resolved Mie scattering

With this numerical investigation we demonstrate the determining of particle size and particle distance for a two-particle system by time resolved Mie scattering. The optical interaction of the fs-laser pulse with the particle configuration produces a sequence of scattered light signals on the femtosecond time scale. The temporal differences between these signals represent typical dimensions of the particle system. The different ray tracks of the specific scattering orders, which are the reason of the temporal behaviour, have been verified by models of geometric optics. We have simulated the Mie scattered light by an algorithm for multi-particle scattering. For all examples the detector was positioned in the back scattering region at a scattering angle of θ=150°.