光学测试 材料光学性能测试与设备

TB962006010677用光学方法测量液体的物理参数=Optical measurement inphysical parameter of liquid[刊,中]/杨宗立(陕西师范大学物理学与信息技术学院.陕西,西安(710062)),苗润才∥光学技术.—2005,31(5).—729-731,735就液体表面声波对入射光波的衍射进行了研究。实验发现,激光束照射在振动的液面上,表面波对入射光可产生衍射;插入液体里的金属细丝被拉出液面时,由于液体的润湿效应,其周围的液体拉伸一定高度而断裂。以上两种实验现象机理可用于液体表面张力系数的测定。激光经小孔透射样品池中的液体介质,在液体上表面发生遮光效应,根…     

表面等离子体共振的热致折射率EI北大核心CSCD

激光束照射液体产生的热累积效应会引起其折射率变化,从声光方程出发分别分析了液体瞬态折射率与稳态热致折射率产生的机理,研究了透镜焦距以及入射波长对去离子水折射率的影响.利用表面等离子体共振检测系统对温度改变的高度敏感性,建立了一种新型的液体棱镜检测系统,数值模拟了不同功率下去离子水的稳态共振曲线,当功率变化为0.7 W时,其折射率变化为1.4×10-3.采用功率可调的980nm的连续激光器对去离子水的热光效应进行了实验研究,得到了其稳态热致折射率随功率的变化关系,当功率变化0.7 W时,其折射率变化为3.35×10-3,最后剖析了实验与理论之间误差的可能来源.     

表面等离子体共振的热致折射率

激光束照射液体产生的热累积效应会引起其折射率变化,从声光方程出发分别分析了液体瞬态折射率与稳态热致折射率产生的机理,研究了透镜焦距以及入射波长对去离子水折射率的影响.利用表面等离子体共振检测系统对温度改变的高度敏感性,建立了一种新型的液体棱镜检测系统,数值模拟了不同功率下去离子水的稳态共振曲线,当功率变化为0.7 W时,其折射率变化为1.4×10-3.采用功率可调的980nm的连续激光器对去离子水的热光效应进行了实验研究,得到了其稳态热致折射率随功率的变化关系,当功率变化0.7 W时,其折射率变化为3.35×10-3,最后剖析了实验与理论之间误差的可能来源.     

碳纳米管悬浮液对532nm激光限幅机理的实验研究

通过光限幅、Z扫描、非线性吸收和散射能量分布实验,研究了碳纳米管悬浮液对532 nm激光的限幅机理以及样品厚度对光限幅机理的影响。结果表明:碳纳米管悬浮液的光限幅机理并非单纯的非线性散射,对低能量入射激光光限幅特性主要源于对入射激光的非线性吸收;对高能量入射激光,碳纳米管的吸收效应和它电离形成的微等离子体以及液体汽化所形成气泡散射效应的共同作用,使其具有较强的光限幅能力,对浓度一定的悬浮液,增加样品厚度虽然会增强其限幅效果,但却会减弱其非线性散射效应。     

磁性液体在磁场中产生光的双折射效应机理

磁性液体是一种特殊的高分子稳定胶体,在磁场中会产生光的双折射效应,对磁性液体在胶体学科方面展开研究,发现磁性液体在磁场中的弱絮凝行为表现异常明显,显示出特有的方向性,且又不至胶体系统失稳,证明了磁性液体中的磁性微粒在磁场中聚集成方向性的链状而又不失稳的临界状态存在。从而揭示了方向性弱絮凝是磁性液体在磁场中产生光的双折射效应的机理。     

液体表面光场环状暗斑效应及折射率测量

实验发现透过液体介质的光场出现了一环状暗斑效应。进一步研究表明,该效应是由于光在液体介质表面发生全反射引起的,环状暗斑半径的大小与液体折射率和液体厚度有关,当液体折射率一定时,液体厚度越厚,暗斑半径越大;光液体厚度一定时,折射率越大,暗斑半径越小。进而建立了环状暗斑半径与液体折射率之间的关系,提出了一种测量液体折射率的新方法。     

含有圆孔平板电极结构的双凸液体透镜的设计与分析

基于平行平板电极的变焦液体透镜的有关研究,通过应用介电泳效应,提出了一种含有圆孔平板电极结构的双凸液体透镜模型,是一种新型的三层液体透镜结构.利用Comsol,Matlab和Zemax软件仿真分析了该模型在不同电压下的面型变化与成像光路,得出其变焦范围为22.6—15.9 mm,并对制备的器件进行具体的实验分析,获得了不同电压下双凸液体透镜的液滴上下界面面型和该透镜的变焦范围23.8—17.5 mm,与仿真结果基本一致,而且其成像分辨率可达到45.255 lp/mm.结果表明,所提出的这种新型三层液体结构的双凸液体透镜具有结构简单、易于实现的特点,而且具备良好的成像质量.     

液体折射率的一种新型测量方法

利用液体薄膜的遮光效应原理,建立了一种新的测量液体折射率的方法和装置。选择了3种常见液体:蒸馏水 、无水乙醇 和1,2-丙二醇。利用新建的装置对其折射率进行了测量。实际测量过程中,对实验形成的图样进行了2种测量分析:一种是利用读数显微镜直接测量分析实验结果;一种是利用CCD拍摄记录实验结果,并利用计算机对拍摄结果进行了智能化处理分析。分析了实验误差,实现了实时、全自动化测量。测量结果均与理论值吻合。该方法操作简便、设备简单、重复性好、准确度高。     

超声清洗装置空化噪声谱分析法空化噪声级测量

空化强度是用以衡量液体介质中空化活动的剧烈程度,同时空化效应在超声清洗中起关键作用,因此,测量超声清洗槽中的空化强度便可了解其中空化活动的情况.当发生空化时,液体介质中会产生成分复杂空化噪声,对空化噪声谱进行分析和计算得到空化噪声级,据此可判断空化强度.实验测得结果表明:超声清洗装置内稳态空化分布广泛、均匀,瞬态空化分...     

几种液体金属自由表面的MHD不稳定性实验研究

介绍了在核工业西南物理研究院的液态金属实验回路(LMEL)上获得的几种可供液态偏滤器-限制器系统选用的液体自由表面的磁流体动力学(MHD)效应不稳定性的实验结果。实验发现：自由表面射流在穿越梯度横磁场时射程变短、截面变扁平,但MHD效应稳定,调节射流与磁场的夹角可以控制射流的流动特性;自由表面膜流MHD效应存在三种现象,即层流、溪状流和湍流。层流是由多束射流打到固体表面产生的(简称“射-膜流”),从MHD效应角度考虑,“射-膜流”将是四种可选液态偏滤器-限制器系统的液体自由表面形式中最佳的选择。同时,探讨了从物理的角度来理解四种自由表面形式的MHD效应的现象。     

液体对微振动的放大效应

根据表面波声光效应的原理,实验上建立了固体表面微振动的激光衍射测量系统.当激光斜入射到微振动引起的液体表面波上,观察到了清晰、反衬度非常高的衍射图样.利用MATLAB软件对拍摄的衍射图样进行扫描,得到了衍射光斑的光强分布图,并根据衍射图样宽度与表面波振幅的解析关系式,求出了液体表面波的振幅,其大小在微米量级.改变样品池中液体的深度,测得不同深度下液体表面波的振幅,给出了表面波振幅与液体深度之间的解析关系,并发现了液体对微振动的放大效应.利用液体对微振动的放大效应,求出了固体表面微振动的振幅,实现了固体表面微振动的探测.     

液体对微振动的放大效应

根据表面波声光效应的原理,实验上建立了固体表面微振动的激光衍射测量系统.当激光斜入射到微振动引起的液体表面波上,观察到了清晰、反衬度非常高的衍射图样.利用MATLAB软件对拍摄的衍射图样进行扫描,得到了衍射光斑的光强分布图,并根据衍射图样宽度与表面波振幅的解析关系式,求出了液体表面波的振幅,其大小在微米量级.改变样品池中液体的深度,测得不同深度下液体表面波的振幅,给出了表面波振幅与液体深度之间的解析关系,并发现了液体对微振动的放大效应.利用液体对微振动的放大效应,求出了固体表面微振动的振幅,实现了固体表面微振动的探测.     

激光反射法测量弯曲液面特性

发现了弯曲液面上边界反射光场的带状暗场扩张效应.当平行激光束垂直入射到由平板润湿效应引起的弯曲液面上时，边界反射产生特殊的反射图样，图样的中间为带状暗场，两侧有清晰的衍射条纹，并且带状暗场宽度随入射光束宽度的缩小而迅速变大.分析了反射图样的带状暗场宽度与入射光束宽度的解析关系，得出了弯曲液面的斜率曲线和高度曲线.建立了一种利用弯曲液面边界反射的暗场扩张效应来实时测量液面特性的新方法.     

液体薄膜遮光效应的研究

当激光束通过静态液体薄膜时,由于表面的全反射效应能够观察到液体薄膜的遮光效应.在此基础上,以白光为光源研究了液体薄膜的遮光效应.结果显示,白光光源的遮光图样非常清晰,且无激光散斑效应|遮光图样的中心是一个光强极强的亮域,该区域的外部为两个同心的环状暗场,两个暗场之间是亮场,亮暗边界十分清楚|液体薄膜遮光图样的半径大小与液体的折射率有关,液体折射率越大,遮光图样的半径越大.本文给出了液体薄膜遮光半径与液体折射率的解析关系,分析了遮光图样产生的必要与充分条件,并根据液体薄膜的遮光效应,建立了一种测量液体折射率的新方法,测量了纯净水的折射率.结果表明,该测量值与传统方法所测折射率的值相吻合且该方法具有设备简单、操作简便、重复性好、准确度高等特点.     

单CCD彩色相机激光干扰模型及外场干扰实验

开展了多波段激光(750~970 nm)对彩色CCD成像系统的外场干扰实验,测得了不同辐照条件下对外场1.3 km处彩色CCD成像系统的干扰效果;建立了彩色CCD相机的激光干扰模型,对实验结果进行了理论验证与分析。理论与实验结果表明:强激光对彩色CCD成像系统的干扰效果明显,CCD靶面出现了明显的光饱和和串扰现象,光饱和区域的形成是由激光束进入光学系统后发生衍射效应造成的;到靶激光功率密度越强,CCD靶面光饱和面积越大,激光干扰效果越好;单波段750 nm激光作用下,到靶功率密度为4.2 kW/cm²,CCD靶面的光饱和面积为0.88 mm×0.97 mm;多波段激光(750~970 nm)作用下,到靶功率密度为20.7 kW/cm²,CCD靶面发生全靶面饱和现象;仿真结果与实验结果基本一致,证明了理论模型的正确性。对远场干扰能力计算结果表明:随着干扰距离的增加,到靶功率密度减小,激光干扰效果变差。     

Mechanism and characteristics of steam laser patterning

Steam laser patterning of thin films and/or solid surfaces has been studied by jetting a beam of steam, such as water vapor, onto a sample surface to form a thin liquid film on it and patterning the sample by laser etching along predetermined path. In steam laser patterning, bubbles are formed in a thin liquid film on a sample surface irradiated by a pulsed laser. When the collapsed shock wave generated at the moment of bubble collapse and the high-speed liquid jet formed during bubble collapse are strong enough, cavitation erosion of the sample surface takes place. Compared to dry laser patterning, the etching rate can be greatly enhanced and no shoulder-like structure is formed at the rim of the laser-irradiated spot in steam laser patterning due to this cavitation erosion effect. PACS 81.65.cf; 52.38.Mf; 79.20.Ds; 42.62.-b; 62.50.+p     

Laser ablation of liquid surface in air induced by laser irradiation through liquid medium

The pulse laser ablation of a liquid surface in air when induced by laser irradiation through a liquid medium has been experimentally investigated. A supersonic liquid jet is observed at the liquid–air interface. The liquid surface layer is driven by a plasma plume that is produced by laser ablation at the layer, resulting in a liquid jet. This phenomenon occurs only when an Nd:YAG laser pulse (wavelength: 1064 nm) is focused from the liquid onto air at a low fluence of 20 J/cm². In this case, as Fresnel’s law shows, the incident and reflected electric fields near the liquid surface layer are superposed constructively. In contrast, when the incident laser is focused from air onto the liquid, a liquid jet is produced only at an extremely high fluence, several times larger than that in the former case. The similarities and differences in the liquid jets and atomization processes are studied for several liquid samples, including water, ethanol, and vacuum oil. The laser ablation of the liquid surface is found to depend on the incident laser energy and laser fluence. A pulse laser light source and high-resolution film are required to observe the detailed structure of a liquid jet.     

用于高功率密度光束控制的光寻址光阀研制

为解决光寻址液晶光阀在高功率密度光束控制领域的应用限制,介绍一种可用于高功率密度激光系统的光寻址液晶光阀,该光阀开关比不低于140∶1,可在高于2300 W/cm²的连续激光系统中正常工作。同时,所研制的光阀可在高重频吉瓦(GW)级功率密度的fs脉冲激光系统中正常工作,在该系统最大功率密度激光作用下,光阀未见明显温度变化,该脉冲激光系统最大平均功率密度超过300 W/cm²。     

Boundary reflection from curved liquid surfaces and its application

A boundary light reflection from curved liquid surfaces was discovered. Due to the wetting effect, the liquid surface near the plate which was inserted into the liquid was deformed. When a collimated light beam vertically illumined the curved liquid surface, special reflective patterns of a strip-shape dark region in the center and the visibility interference fringes on both sides was observed for the up-curved liquid surface. The width of the dark region increases with the decreasing width of the incident beam. The relation of the dark region width and the incident beam width was derived theoretically. The slope and the height of curved liquid surface were obtained directly from measuring the dark central region width of the reflection pattern and the incident beam width. Furthermore, the analytic expression of the profile of the curved liquid surface was derived. As a result, it shows that an effective and practical technique for measuring the characterization of curved liquid surface was found.     

Pulse laser ablation at water–air interface

We studied a new pulse laser ablation phenomenon on a liquid surface layer, which is caused by the difference between the refractive indices of the two materials involved. The present study was motivated by our previous study, which showed that laser ablation can occur at the interface between a transparent material and a gas or liquid medium when the laser pulse is focused through the transparent material. In this case, the ablation threshold fluence is reduced remarkably. In the present study, experiments were conducted in water and air in order to confirm this phenomenon for a combination of two fluid media with different refractive indices. This phenomenon was observed in detail by pulse laser shadowgraphy. A high-resolution film was used to record the phenomenon with a Nd:YAG pulse laser with 10-ns duration as a light source. The laser ablation phenomenon on the liquid surface layer caused by a focused Nd:YAG laser pulse with 1064-nm wavelength was found to be followed by the splashing of the liquid surface, inducing a liquid jet with many ligaments. The liquid jet extension velocity was around 1000 m/s in a typical case. The liquid jet decelerated drastically due to rapid atomization at the tips of the ligaments. The liquid jet phenomenon was found to depend on the pulse laser parameters such as the laser fluence on the liquid surface, laser energy, and laser beam pattern. The threshold laser fluence for the generation of a liquid jet was 20 J/cm². By increasing the incident laser energy with a fixed laser fluence, the laser focused area increased, which eventually led to an increase in the size of the plasma column. The larger the laser energy, the larger the jet size and the longer the temporal behavior. The laser beam pattern was found to have significant effects on the liquid jet’s velocity, shape, and history.