气体探测器雪崩过程的研究

基于汤逊气体放大电子雪崩模型和一定的物理假设,导出描绘气体探测器中正比模式和有限正比模式的一个统一公式.该公式很好地符合实验事实,由此还得到了描述空间电荷作用强弱的参数──等效电容以及表征探测器工作状态的参量──线性度.同时,在假定SQS雪崩中空间电荷起重要作用的情况下,该公式很好地描述了其输出电量随高压的线性关系.     

光电混合功率谱分析系统实时图象识别时的若干技术问题

本文针对光电混合功率谱分析系统(OPSA)在实际进行图象识别时的若干技术问题作了分析和讨论,并提出了相应的解决办法,实用效果比较好。     

微通道板X射线探测器

在激光等离子体实验研究中,为了更好地了解激光与等离子体相互作用过程中所发生的物理过程,要求能够高时间分辨地观测等离子体所辐射的X射线的特征。测量的关键在于X射线探测元件,既要有快的时间响应,又要能够输出足够大的光电流,以便直接驱动高速示波器,进行显示和照像。普通的闪烁体/光电倍增管X射线探测器,由于闪烁体荧光有着固有的衰减时间,以及普通的光电倍增管中的电子飞行时间离散严重,时间分辨力难以提高。     

A scintillation theory for millimetre and submillimetre wavebands

In the millimetre and submillimetre wavebands the attenuation of signals due to atmospheric water vapour absorption is not negligible. A theory of scintillation is presented which links the phase variation to the observed fluctuations in signal intensity. Analysis of observations shows that, at sea level, scintillation is present under normal observing conditions.     

C imaging by double resonance scalar-coupling editing

The two-dimensional FT Imaging of ¹³C-glucose obtained with twin spin-echo double resonance sequence is presented. The images have been obtained by a doubly tuned surface coil on samples containing water and ¹³C-enriched glucose in water. It is shown, both theoretically and experimentally, that the whole editing capability of the twin spin-echo double resonance imaging sequence is also preserved in the presence of the radiofrequency field inhomogeneity produced by the surface coil. As in an efficient selective irradiation method, the enhancement in the signal-to-noise ratio with respect to the direct ¹³C detection, depends on the number of protons J-coupled to ¹³C.     

Playing with quantum Hall effects and single-electron-tunneling effects

The usefulness of quantum Hall effect (QHE) conductors and quantum dot (QD) devices is revealed by reviewing five remarkable effects. The first is the sensitive detection of terahertz (THz) radiation by QHE conductors. The second is the imaging of THz emission from non-equilibrium carriers in QHE conductors, by using scanning THz microscopes. The third is the single-photon detection of THz radiation in strong magnetic fields, which is carried out by incorporating a QHE electron system into a QD. Individual events of single-THz-photon absorption within the QD via cyclotron resonance cause the QD to electrically polarize, which, in turn, is detected as switches of the tunnel conductance through the QD. The fourth is the single-photon detection of THz radiation by using double QDs in the absence of a magnetic field. Both of the photon detectors are implemented in gate-voltage-induced lateral GaAs/AlGaAs QDs, and exploiting the extraordinary sensitivity of single-electron transistors to the charge. The fifth is the coherent control of nuclear spins in QHE conductors. Nuclear spins are (i) electrically polarized by unequally populating spin-split QHE edge channels via the hyperfine interaction, (ii) coherently controlled via pulsed nuclear magnetic resonance induced by local RF magnetic fields, and (iii) finally detected by the edge channels through resistance change of the Hall device. The controlled nuclear spins are limited to those along the edge channels, on the order of 10⁹.     

窄间隙室探测器性能测试

山东大学承担ATLAS实验T9型窄隙室TGC探测器的研制任务,本工作测量了TGC探测器在32?0?0V工作电压下的稳定性、漏电流和坪曲线,同时在相同工作条件下、相同时间间隔内测量各信号道的计数率的一致性.初步测量结果表明,由山东大学研制的T9型TGC探测器的各项性能指标达到实验设计要求.     

GaAs探测器实验标定

叙述了在闪光Ⅰ上用6MV轫致辐射实验标定快响应GaAs光电探测器的原理实验结果以及分析讨论。     

Size Measurement of Very Small Spherical Particles by Mie Scattering Imaging (MSI)

The Mie Scattering Imaging method (MSI) gathers out‐of‐focus images of dispersed spherical particles present in a laser light sheet and extracts the individual particle diameter from these images. The general idea of the method has been around for more than a decade and a number of papers has dealt with it over recent years. Our work focuses on small particle sizes from 20 μm down to 2 μm, a range which has not been tackled so far although it is of great importance in particle systems. We present an optical set‐up with a special arrangement of camera lenses that allows to work in this range. An evaluation algorithm based on correlation of the experimental optical information with theoretical Mie scattering was found to give the most accurate results for particle sizing. Besides accuracy measurements on solid spheres the versatility of the method is demonstrated by an example of transient droplet growth between 2–7 μm.     

Geometric Analysis and Symbol Calculus: Fourier Transform Magnetic Resonance Imaging and Wavelets

Due to its unequalled advantages, the magnetic resonance imaging (MRI) modality has truly revolutionized the diagnosis and evaluation of pathology. Because many morphological anatomic details that may not be visualized by other high tech imaging methods can now be readily shown by diagnostic MRI, it has already become the standard modality by which all other clinical imaging techniques are measured. The unique quantum physical basis of the MRI modality combined with the imaging capabilities of current computer technology has made this imaging modality a target of interdisciplinary interest for clinicians, physicists, biologists, engineers, and mathematicians. Due to the fact that MRI scanners perform corticomorphic processing, this modality is by far more complex than all the other high tech clinical imaging techniques. The purpose of this paper is to outline a phase coherent wavelet approach to Fourier transform MRI. It is based on distributional harmonic analysis on the Heisenberg nilpotent Lie group G and the associated symplectically invariant symbol calculus of pseudodifferential operators. The contour and contrast resolution of MRI scans which is controlled by symplectic filter bank processing gives the noninvasive MRI modality superiority over X-ray computed tomography (CT) in soft tissue differentiation.