石墨烯拉曼光谱信号干涉增强特性

拉曼光谱技术是探测和分析石墨烯特性最有效的方法之一,其拉曼光谱信号主要包括D峰、G峰和2D峰。由于通常不受外界因素的影响,2D峰与G峰的强度比可以用来分析石墨烯的基本特性。以SiO_2/Si基底上的石墨烯为研究对象,基于多层膜系菲涅尔理论,研究了2D峰与G峰的强度比随石墨烯层数(厚度)变化的关系。研究结果表明2D峰与G峰的强度随着石墨烯层数增加而减小。进一步,研究了SiO_2厚度对拉曼光谱增强因子以及2D峰与G峰的强度比的影响,得到其最大增强因子和强度比分别为5.15、4.21和13.1。最后,讨论了2D峰与G峰的强度比与激发激光波长的关系,结果表明2D峰与G峰强度比随激发波长的增加先增加后减小,其最大比值为13.1,对应的激发波长为585nm。

Simulation of Dynamic Property for Wave Reflection in Basin over a Half Infinite Space by Staggered Grid RFFT Differentiation

Simulations for seismic wave propagation in the sedimentary basin over half-infinite rock space were performed in this analysis. The results indicated that the basin shape in heterogeneous structures affected wave dynamic characteristics in propagating. The refraction wave from the rock brought the multireflection wave and the secondary surface wave in the basin. The waves oscillating up-down within the basin shook the buildings time after time resulting in heavy damage. The geometrical focusing by basin corners and the physical interference between waves significantly amplified the ground motions. The location of peak ground motion due to the interference was attributable to the apparent velocity difference between the secondary surface wave and the body wave. The late-arrival waves also resulted in the peak ground motion. The frequencies of the late-arrival waves of multireflection might cause dispersion. The late-arrival conversion waves with various frequencies widened the frequency band of seismic input waves shaking buildings and could seriously damage buildings with corresponding intrinsic frequencies.

日本电子JMS-S3000的开发——具有螺旋状离子轨道的MALDI-TOF/TOF-MS

日本电子开发了一种具有螺旋状离子轨道的新型离子光学系统,它超越了现在市场上多数采用的反射式离子光学系统的基本性能;而且还开发了MALDI-TOF/TOF-MS(型号为JMS-S3000),在第1个TOF MS中采用螺旋状轨道离子光学系统,第2个TOF MS中采用反射式离子光学系统,从而实现了以前的质谱仪器达不到的高质量分辨率和高母离子选择性。JMS-S3000质谱图显示:在m/z2093质量分辨率不仅超过60,000(FWHM),而且在很宽的质量范围也能达到高质量分辨率。JMS-S3000具有高母离子选择性,只选择母离子的单一同位素离子,所以各个断裂途径的峰在子离子谱图上能够清晰地被看到其对应的信号峰,使得子离子谱图的解析变的更加简单明确。

环形多反射式可见/短波红外光学镜头设计

为了实现可见/短波红外镜头的小型化设计,参考环形多反射结构的光学系统,针对单片多反射系统难以校正色差的问题,设计了一个130万像素的紧凑型双片结构的环形多反射式光学镜头。通过分析遮拦比和光学参数对系统的光学传递函数的影响,确定了系统的最佳遮拦比和光学参数。优化后的光学镜头包含两片透镜,材料选用氟化钙,两片透镜之间产生4次反射,各反射面均为偶次非球面。镜头的工作波段为400~1700 nm,焦距为75 mm,直径为50 mm,遮拦比为0.75,全视场角为6.2°,系统总长为22.7 mm,系统长度与焦距比为0.302。优化后镜头光学传递函数曲线平滑,100 lp/mm处大于0.35,倍率色差小于0.9μm,成像质量良好。