共查询到19条相似文献,搜索用时 234 毫秒
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发射度是描述束流品质的重要物理量,根据发射度和传输矩阵可以准确计算束流包络和发散角的变化。在考察传统加速器束流发射度测量方法的基础上,提出采用多狭缝法对激光尾场产生的电子束发射度进行测量。采用宽度为20 m的多狭缝板对发射度为0.05 mmmrad的激光尾场加速电子发射度进行测量,数值模拟结果表明采用多狭缝法测量的相对误差可以控制在5%以内。并给出了不同狭缝参数对测量精度的影响,模拟结果表明狭缝宽度对发射度测量精度影响最大。狭缝宽度越窄,测量精度越高,反之,则越低。 相似文献
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合肥软X射线波段自由电子激光项目是基于直线加速器的软X射线光源. 其注入器由光阴极微波电子枪与两个直线加速3米段构成. 光阴极微波电子枪产生束团电荷量1nc、峰值流强100A、重复频率10Hz电子束流, 并利用螺线管磁场在其出口处进行发射度补偿, 在经过一段漂移距离后电子束流进入增强直线段加速. 使在低能端由于空间电荷效应产生的横向发射度增长基本被完全补偿. 本文中利用PARMELA对注入器进行了模拟计算, 对发射度的补偿效果进行了优化, 同时对注入器内各元件的布置也进行了优化. 在注入器出口可以得到归一化横向发射度小于1.5mm.mrad的低发射度束流. 相似文献
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Li Cheng Wang Wenxing Li Weiwei Zhang Haoran Jiang Shimin Gao Panyun He Zhigang Zhang Shancai 《强激光与粒子束》2021,33(9):094002-1-094002-6
为满足合肥先进光源对高品质注入束流的要求,合肥先进光源预研项目研制了一套光阴极微波电子枪系统作为注入器电子源。为降低空间电荷效应引起的束流发射度增长,对驱动激光整形及传输系统进行了理论和实验研究。通过双折射晶体的脉冲时间整形以及采用光阑高斯截断的空间整形,得到了近似均匀分布的激光脉冲。像传递激光传输光路,实现了光阴极表面激光位置的高稳定性。实验结果显示,光阴极表面的激光位置抖动小于4 μm,激光性能满足实验要求。 相似文献
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利用已经建成的4 MeV LIA注入器,结合时间分辨测量系统研究了三种测量技术:发射度测量法、无场准直器和磁场准直器测量法。介绍了强流束亮度定义和典型方法理论分析及测量技术的物理概念,提出了用于猝发多脉冲电子束发射度测量装置的设计与调试,通过对时间分辨测量系统的分幅相机记录的光强度分布信息处理,得到电子束束斑均方根半径和发射角,分析某一时刻数据,即可得到电子束某一时刻发射度,从而获得多脉冲电子束时间分辨发射度。在4 MeV LIA注入器上对多脉冲电子束流的发射度进行测量,得到电子束归一化均方根发射度约为114 mmmrad、双脉冲456 mmmrad的归一化发射度。最后结合电子束的高斯分布初步分析并给出均方根发射度、实测发射度和边发射度的关系。 相似文献
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新一代粒子加速器中磁铁位置与姿态的准确测量和安装依赖于各项技术的综合运用。实现磁铁在全局坐标系中准确定位,并且快速精密安装测量,为了建造高亮度、低发射度的第四代同步辐射光源,国家同步辐射实验室开展了"合肥先进光源(HALF)"的预研工作。作为准直测量系统的重要研究内容,创新性地提出了准直参考网络方法。为了保证准直测量精度,对准直参考网络的机械系统本身的形变要求很高,通过ANSYS软件对机械系统整机进行了静力学仿真,根据分析结果对准直基准板进行了优化设计,使其满足工作条件要求。 相似文献
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为了验证国产质子注入器的参数是否满足需求,注入器团队设计了束流测量系统用于测量国产质子直线注入器束流的流强、发射度、能量以及能散等关键指标。此测量系统包含了采用变聚焦法测量发散度、采用分析磁铁测量束流能量和能散的主要功能。利用束流输运线设计软件Tracewin(版本2.11.4.1)进行了系统束线的物理设计,对束测系统测量质子束流的发散度和能量的精度进行了模拟计算。由于经过RFQ-(APF)DTL加速后的粒子束团为“拖尾”的非理想粒子束团,需要针对非理想束团对束测系统测量发射度和能量产生的影响进行分析。通过对模拟计算结果的分析,发现相对于测量理想粒子束团的结果非理想粒子束团对束测系统测量发射度精度影响较大;非理想粒子束团对束测系统测量能量精度影响较小。 相似文献
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论文介绍RF腔光阴极注入器中热发射度的测量方法,在注入器中有三个因素影响热发射度的测量,它们是:射频场效应、空间电荷效应和发射度测量误差. 在注入器出口处,电子束发射度由:热发射度、射频场效应引起的发射度增长和空间电荷效应的发射度增长三部分组成. 论文从注入器中发射度增长理论和模拟出发,给出了一个能够消除射频场效应和空间电荷效应的热发射度测量方法. 相似文献
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A combined unit, which has the ability to measure the current and emittance of the high intensity direct current(DC)ion beam, is developed at Peking University(PKU). It is a multi-slit single-wire(MSSW)-type beam emittance meter combined with a water-cooled Faraday Cup, named high intensity beam emittance measurement unit-6(HIBEMU-6). It takes about 15 seconds to complete one measurement of the beam current and its emittance. The emittance of a 50-mA@50-kV DC proton beam is measured. 相似文献
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Based on the multi-slit
method,
a new method is introduced to measure the non linear
force caused emittance growth in a RF photoinjector. It is possible to
reconstruct the phase space of a beam under some
conditions by the multi-slit method. Based on the reconstructed
phase space, besides the emittance, the emittance
growth from the distortion of the phase space can also be measured. The
emittance growth results from the effects of nonlinear force acting on
electron, which is
very important for the high quality beam in a RF photoinjector. 相似文献
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Beam emittance is one of the most important parameters for electron sources. To investigate the beam emittance of the 3.5-cell DC-SC photocathode injector developed at Peking University, a multi-slit emittance measurement device has been designed and manufactured. The designed slit width, mask thickness and beamlet drift length are 100 μ m, 3 mm and 430 mm respectively. It is suitable for the electron beam with energy of about 5 MeV and the average current less than 0.1 mA. The preliminary measurement result of the rms emittance of the electron beam produced by the DC-SC injector is about 5-7 mm·mrad. 相似文献
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The well-known Fraunhofer multi-slit diffraction is described as the multi-slit interference modulated by the singleslit diffraction, namely the multiplication between the single-slit diffraction factor and the multi-slit interference factor. By considering the simplified argument we show that the multi-slit diffraction of evanescent waves which are in the near-field region also has the interference and diffraction effects, and that this two-fold effect can be expressed as the convolution of the diffraction factor and the interference factor. Our conclusion could be helpful to understand the contribution of evanescent waves to the optical responses of sub-wavelength structures such as slits and grooves. 相似文献
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Streak-tube lidar (STIL) is an excellent laser-imaging system, which can provide a high-resolution 4D-image. Compared to multi-slit STIL (MS-STIL), single-slit STIL (SS-STIL) can offer much higher image resolution using beam compression. This advantage is important for identification of a long distance target. We propose a method for increasing the SS-STIL-system resolution and perform an experiment on high-resolution imaging of a long-distance target. Since the beam-compression rate is limited due to the resolution of the streak-tube photocathode, we propose a method for defining the proper laser-beam shape in the STIL-system design. 相似文献
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One kind of instantaneous electron beam emittance measurement system based on the optical transition radiation principle and double imaging optical method has been set up. It is mainly adopted in the test for the intense electron-beam produced by a linear induction accelerator. The system features two characteristics. The first one concerns the system synchronization signal triggered by the following edge of the main output waveform from a Blumlein switch. The synchronous precision of about 1 ns between the electron beam and the image capture time can be reached in this way so that the electron beam emittance at the desired time point can be obtained. The other advantage of the system is the ability to obtain the beam spot and beam divergence in one measurement so that the calculated result is the true beam emittance at that time, which can explain the electron beam condition. It provides to be a powerful beam diagnostic method for a 2.5 kA, 18.5 MeV, 90 ns (FWHM) electron beam pulse produced by Dragon I. The ability of the instantaneous measurement is about 3 ns and it can measure the beam emittance at any time point during one beam pulse. A series of beam emittances have been obtained for Dragon I. The typical beam spot is 9.0 mm (FWHM) in diameter and the corresponding beam divergence is about 10.5 mrad. 相似文献