Transverse Effects in Slow Light Propagation

The effect of finite control beam on the transverse spatial profile of the slow light propagation in an electromagnetically induced transparency medium is studied. From the second-order wave equation and linear response of an EIT medium to the signal field, we find it is possible to produce an effective waveguide for the signal field. The existence and properties of a set of localized, stationary transverse modes are demonstrated. Especially, by carefully manipulating the profile of the control beam, we can realize single-mode propagation for the signal field, which may be important for potential applications.     

光电法研究JO-9159炸药反应区宽度

采用光电法研究炸药反应区结构的实验装置如图1所示，炸药装置用平面波透镜起爆。为了屏蔽炸药爆轰发光，在炸药样品和窗口材料氯仿之间用0．01mm厚的铜箔隔开。然后用硅油将铜箔紧紧地贴在被测样品的表面，其目的是避免炸药样品与铜箔之间有空气隙存在，以免其影响测试精度。为了防止氯仿的渗漏，在铝套筒和炸药样品之间用真空油脂密封。光纤一端直接插入装置之中，另一端和高温计的各通道相连。炸药爆轰后，在透明液体氯仿中产生冲击波，在冲击波作用下液体发光，光纤和光电倍增管将光信号转变为电信号，记录在示波器上，计算得到氯仿中的冲击波温度随时间的变化曲线。     

电磁诱导透明和导致极慢光速的机制

根据有关文献 ,描述了电磁诱导透明和导致光速极慢的物理机制 ,并对实验结果也做了介绍     

激光能俘获粒子吗?

 随着科学技术的深入发展.特别是六十年代激光诞生,使光学领域发生了一次重大飞跃,它不仅开创了光学技术的新局面,而且几乎没有那一门自然科学不感受到激光的巨大魅力的影响.与此同时,作为对光自身性质的研究,人们对光的力学效应产生了浓厚的兴趣.每个光子具有的动量虽小,但高亮度的激光束所表现出来的动量则可产生令人惊叹的宏观效应.目前已做到将Na原子的运动速度从600m/s冷却到平均速度近似为零.将原子冷却到10^-4K后进一步采用磁陷阱、射频陷阱或激光陷阱等把原子囚禁其中.     

有机硅耐磨透明涂层的固化分析

ＦＴＩＲ、ＴＧ、ＴＢＡ等对有机硅耐磨涂料（有机硅溶胶）的热固化过程研究表明有机硅胶体中缔合羟基间的脱水缩合速率很高；羟基脱水程度与固化温度有关，温度越高，达平衡时羟基的浓度越低，在１０５～１３０℃间羟基的浓度变化最大，加入适当的固化剂，对羟基的脱水交联有促进作用，在较高的固化温度下，反应体系中出现了环氧环异构化产生的酮羰基的吸收峰     

低温燃烧法制备Nd:YAG透明激光陶瓷粉体

以硝酸盐和柠檬酸为初始原料，用低温燃烧法制备出掺钕钇铝石榴石（Nd：Y3Al5O2，Nd：YAG）多晶超细粉体，并采用XRD，SEM等测试手段对粉体的结构和形貌进行了表征。结果表明，在950oC煅烧2h得到了结晶性能良好的Nd：YAG超细粉体，该粉体分散均匀、粒级分布窄、平均粒度为50nmo上述粉体加入0．5％正硅酸乙酯成型后，采用SPS于1600℃，30MPa下烧结5min后相对密度达98．5％，晶粒尺寸在1μm左右，显微结构均匀，气孔率低。     

透明陶瓷的研究进展

透明陶瓷性能优异,应用广泛,是一类备受关注的新型材料.目前已经成功开发的透明陶瓷有氧化铝透明陶瓷、氧化钇透明陶瓷、氮化铝透明陶瓷以及PLZT电光透明陶瓷和激光透明陶瓷等.本文介绍了几种透明陶瓷的研究进展以及性能和应用,并且对透明陶瓷的研究趋势提出展望.     

掺钛氧化锌纳米薄膜的研究进展

在论述磁控溅射制备的掺钛氧化锌薄膜研究意义的基础上,介绍了目前国内外有关采用磁控溅射制备的掺钛氧化锌薄膜的研究现状,并展望了掺钛氧化锌薄膜的未来研究方向。     

石墨烯玻璃透明薄膜加热特性

Graphene has become a research focus in recent years owing to its excellent characteristics, and glass is a commonly used material with high transparency and low cost. Graphene glass combines the excellent properties of both graphene and glass; graphene glass has not only high thermal conductivity, high electrical conductivity, and good surface hydrophobicity but also exhibits superior electrothermal conversion and wide-spectrum high-light-transmittance characteristics. Therefore, the study of graphene glass films is of theoretical value and practical significance. In this study, a high-purity glass-based (JGS1 quartz glass) multilayer graphene film was developed based on an atmospheric-pressure chemical vapor deposition (APCVD) method, and its electrical characteristics, light transmittance, and electrical heating characteristics were experimentally investigated in detail. The results show that graphene glass with different surface resistance values obtained through direct growth on a high-purity quartz glass substrate using the APCVD method, not only has excellent uniformity and quality, but also has considerably flat and high transmittance across the entire visible light region and exhibits excellent heating performance and fast response time. For graphene glass with a surface resistance of 1500 Ω·sq^-1, the light transmittance can reach 74%, and the saturation temperature can rise to 185 ℃ by applying a bias voltage of 40 V. In addition, when the resistance value of the graphene glass is 420 Ω·sq^-1, the graphene glass reaches a high saturation temperature of 325 ℃ in 40 s, and the corresponding heating rate can exceed 18 ℃·s^-1, achieving a significantly higher heating rate than other heating films at the same voltage. Compared with the polyethylene-terephthalate- (PET-) based and silicon-based graphene films obtained by the transfer, graphene glass has a higher saturation temperature, shorter thermal response time, and faster heating rate. Furthermore, graphene glass exhibits better heating cycle stability and longer-term heating stability at a constant voltage. In addition, an experiment using the graphene glass to thermally tune the wavelength of a vertical-cavity surface-emitting laser was conducted and gave good results. The position of the laser peak controlled by the graphene glass was red-shifted by 1.78 nm by applying a voltage of 20 V, and the wavelength tuning efficiency reached 0.059 nm·℃^-1. Compared with PET-based and silicon-based graphene films, the actual electrical heating capacity of graphene glass increased by 195%. These experimental findings demonstrate that graphene glass transparent films with excellent electric heating characteristics can be used in various transparent electric heating fields and have relatively wide application prospects.