无序介质的非相干背散射

J4 ›› 2010, Vol. 27 ›› Issue (6): 693-699.

无序介质的非相干背散射

付方正李明

南昌大学物理学系, 江西南昌 330031

出版日期:2010-11-28 发布日期:2010-11-19
通讯作者: 付方正（1956—）男，博士,教授 ,主要从事激光方面的研究。 E-mail:ffz050919@sohu.com
基金资助:
国家自然科学基金(10464002)资助项目

Incoherent backscattering of random medium

FU Fang-zheng , LI Ming

Department of Physics, Nanchang University, Nanchang 330031, China

Published:2010-11-28 Online:2010-11-19

摘要/Abstract

摘要：

讨论两种散射，导出相应的分布函数，运用蒙特卡罗法模拟光子在无序介质中的随机行走过程，得到非相干背散射空间分布及反射率。计算结果表明：1、散射不同，非相干背散射空间分布和反射率不同，非相干背散射反射率随光入射角增大而增大；2、非相干背散射反射率随无序介质吸收系数增大而减小，通过测量非相干背散射反射率可得吸收系数，进一步可得每次散射光子被微粒吸收的概率；3、非相干背散射反射率随光子平均自由程增大而减小，通过测量非相干背散射反射率可得平均自由程，这比检测相干背散射来得到平均自由程要容易。最后，讨论了背散射对无序激光器的影响。

关键词: 激光物理, 非相干背散射, 蒙特卡罗法, 无序介质

Abstract:

Two kinds of scatterings are discussed and the corresponding distribution functions are deduced . The spatial distribution of incoherent backscattering and reflectivity are deduced by simulating the process of stochastic photon movement in random medium using the Monte Carlo method. The results show that different scattering have different reflectivity and spatial distribution of incoherent backscatter. As the angle of incidence increasing, the reflectivity of incoherent backscattering increases. Reflectivity of incoherent backscattering decreases as the absorption coefficient of random medium increasing. By measuring the reflectivity of incoherent backscattering, we can get first the absorption coefficient and then the probability that photon is absorbed by particle each time scattering. Reflectivity of incoherent backscattering decreases as the mean free path of photon increasing .The mean free path can be gotten by measuring the reflectivity of incoherent backscattering , it is easier than testing coherent backscattering to get the mean free path. Lastly, the effect of backscattering on random laser is discussed.

Key words: laser physics, incoherent backscattering, Monte Carlo method, random medium

中图分类号:

O469

付方正李明. 无序介质的非相干背散射[J]. J4, 2010, 27(6): 693-699.

FU Fang-zheng , LI Ming. Incoherent backscattering of random medium[J]. J4, 2010, 27(6): 693-699.

参考文献

[1]Letokhov V S. Generation of light by scattering medium with negative resonance absorption
[J] .Sov.Phys.JEPT，1968，26:835.

[2] Lawandy N M , Selschandran R M , Lgomes A S , et al . Laser action in strongly scattering media
[J ] . Nature , 1994 , 388 (3) : 436-438.

[3] Wiersma D S，Lagendijk A. Light diffusion with gain and random lasers.Phys.Rev.E1996，54:4256.

[4]Cao H , Zhao Y G, Ho S T , et al . Random laser action in semiconductor powder
[J ] . Phys Rev L ett , 1999 , 82 (11) : 2278-2282.

[5] Cao H , Zhao Y G. Ultraviolet lasing in resonators formed by scattering in semiconductor polycrystalline films
[J]. Applied Physics Letters ,1998,73:3656-3658.

[6]Strangi G, Ferjani S, Barna V, DeLuca A,Versace C,Scaramuzza N,and Bartolino R.Random lasing and weak localization of light in dye-doped nomadic liquid crystals
[J].Opt. Expr., 2006，14(17):7737-7744.

[7]Anderson P W, Absence of Diffusion in Certain Random Lattices
[J], Physical Review, 1958, 109:1492-1505.

[8] Cao H. Lasing in random media(J). Waves Random Media,2003,13: R1-R39.

[9] Fu Fangzheng，Li Ming. Calculating the threshold of random laser by using Monte Carlo method
[J],Acta Physica Sinica(物理学报),2009,58(9):6258-6263(in Chinese)

[10] Fu Fangzheng, Li Ming.Spatial distribution of output laser in random laser
[J],Chinese J. Quantum Electronics(量子电子学报),2009,26(5):543-547(in Chinese)

[11]Niginov M A, Bahoura M, Noginova N E, et al. stimulated emission in scattering and composite dielectric media(random lasers): effect of particle size
[C]. SPIE, 2003, 5218: 124~129

[12] Wolf P E and Maret G, Weak Localization and Coherent Backscattering of Photons in Disordered Media
[j],Phys.Rev.Lett.,1985,55,2696-2699

[13] van der Mark M B, van Albada M P and Lagendijk A, Light scattering in strongly scattering and weak localization
[J]. Phys.Rev.B,1988,37,3575-3592.

[1]	武安华 , 赵向阳 , 尚加敏 , 申慧 , 苏良碧 , . 稀土正铁氧体晶体的太赫兹光学调控研究[J]. 量子电子学报, 2023, 40(3): 293-300.
[2]	洪慧慧, 叶佐东. 二硫化钨薄膜双共振上转换荧光增强研究[J]. 量子电子学报, 2022, 39(4): 605-612.
[3]	冯立强. 共振电离对原子分子谐波光谱强度的影响[J]. 量子电子学报, 2021, 38(4): 529-538.
[4]	张译文, 刘航, †, 冯立强. 啁啾延迟调控在双原子分子谐波辐射中的作用[J]. 量子电子学报, 2020, 37(3): 314-320.
[5]	刘航, 冯立强. 啁啾波形调控产生水窗区间光谱连续区和阿秒脉冲[J]. 量子电子学报, 2020, 37(2): 150-156.
[6]	李义, 冯立强. 利用啁啾-紫外组合激光增大谐波能量及强度[J]. 量子电子学报, 2019, 36(6): 738-744.
[7]	冯立强. He+在蝴蝶型金属纳米结构下辐射谐波的特点[J]. J4, 2018, 35(4): 479-485.
[8]	李宁馨，秦朝朝，于可新. 基于Labview的分振幅激光偏振动态检测研究[J]. J4, 2018, 35(4): 408-413.
[9]	杨波，刘子龙，徐志兵，张波 . 铷原子偶极阻塞特性的数值模拟[J]. J4, 2017, 34(3): 357-362.
[10]	杨娟冯庆江. 应用改进的简单方程法求(2+1)维ZK-MEW方程的精确解[J]. J4, 2016, 33(3): 287-291.
[11]	孙丽，韩琦，赵崇谊，黄兆聪，翟亚，徐永兵. 聚焦磁光克尔效应研究坡莫合金图形阵列中的局部磁性[J]. J4, 2015, 32(4): 492-497.
[12]	杨奕婷乔豪学. 利用频率相近的双色激光驱动氢原子产生单个短脉冲[J]. J4, 2013, 30(4): 405-410.
[13]	何志红陈长水刘颂豪张会云张玉萍罗锡璋. 连续激光泵浦重水气体分子产生THz激光辐射的阈值分析[J]. J4, 2013, 30(4): 411-417.
[14]	刘海港杨艳芳何英常强刘健. 贝塞尔高斯径向偏振光束在衍射光学元件调制下多光球的产生[J]. J4, 2013, 30(4): 385-390.
[15]	杜传梅，张明旭，庞建勇. 激光诱导镍等离子体发射光谱Stark展宽和电子密度的空间分辨特性[J]. J4, 2013, 30(3): 268-274.