兰州重离子加速器冷却储存环

 兰州重离子加速器冷却储存环HIRFL-CSR,是一个多用途、多功能的双冷却储存环同步加速器系统,由主环CSRm和实验环CSRe构成,并以兰州重离子级联回旋加速器HIRFL作注入器。CSR利用高频变谐波的方法,将重离子束的能量从7～25 MeV/u同步加速到２00～1 000 MeV/u,同时利用重离子储存环中空心电子束冷却技术将束流品质提高１个数量级,并通过储存环的快引出及慢引出,提供多种类的重离子束以及放射性次级束(RIBs),以开展范围更广精度更高的物理实验。该装置于2007年投入运行,已取得了重要的运行结果,如实现了剥离注入与多圈注入、空心电子束对重离子束的冷却与累积、变谐波宽能区同步加速、等时性环型谱仪、RIBs的产生收集与ToF高分辨质量测量以及高能重离子束的变能慢引出等。     

HIRFL-CSR实验环高频同轴谐振腔设计原理

介绍了同步加速器高频铁氧体加载腔体的设计原理和设计计算过程。 详细说明了腔体加载铁氧体材料的作用和意义, 并对传统的传输线理论计算结果、 CST(Computer Simulation Technology)软件模拟计算结果和实际腔体测量结果进行了比较。 In this paper, the principle and the process of design and calculation based on RF ferrite loaded coaxial cavity in synchrotron are presented. The function and significance of cavity loaded by ferrite are elaborated in detail. Then the calculated results by traditional transmission line theory, software simulated results by Computer Simulation Technology(CST ) and the actual cavity measured results are compared.     

RF system design and measurement of HIRF-CSRe

An RF system for the CSRe （cooling storage experimental ring） is designed and manufactured domestically. The present paper mainly describes the RF system design in five main sections： ferrite ring, RF cavity, RF generator, low level system and cavity cooling. The cavity is based on a type of coaxial resonator which is shorted at the end with one gap and loaded with domestic ferrite rings. The RF generator is designed in the push-pull mode and the low level control system is based on a DSP＋FGPA＋DDS＋USB interface and has three feedback loops. Finally we give the results of the measurement on our system.     

HIRFL-CSR重离子束内散射效应

电子冷却本质上是电子冷却作用与重离子束内散射作用的动态平衡过程. 在Bjorken和Mtingwa束内散射理论的基础上, 应用对称椭圆积分的方法做束内散射增长率的数值模拟, 并应用于HIRFL-CSR的磁铁聚焦结构. 计算结果表明, 束内散射不会成为CSR磁聚焦结构设计的障碍, 并且CSR可以达到冷却设计指标.     

HIRFL-CSRm纵向随机冷却-槽形滤波冷却模拟研究

 通过Fokker Planck方程,对拟在HIRFL-CSRm上建造的纵向槽形滤波器（notch filter）的冷却机理进行了研究,得出了冷却原理及冷却时间的表达式,并对影响冷却时间和冷却效果的因素进行了模拟和讨论,模拟结果表明,噪信比越小,冷却时间越短,冷却效果越好;带宽越宽冷却越快。该研究为具体纵向冷却系统的设计和优化提供了依据。     

重离子治癌装置研究

介绍了重离子治癌装置的最新发展状况 ,比较了两类典型的旋转机架的结构及光学特性 ,给出了离子光学的限制条件 .设计了一台桶形机架 ,为兰州重离子冷却储存环应用于医学治疗进行了预研. A simple plane rotating gantry is proposed at the Heavy Ion Research Facility in Lanzhou (HIRFL), where a new project named Cooling Storage Ring is under construction. The gantry is 18 metre long, 5 metre high from upper beam axes to rotation axes. It consists of eight quadruples, two 45° and one large aperture 90° dipole magnets. It is equipped with a two direction magnetic raster scanning system. A beam spot of radii between 2 to 5 mm can be achieved at∶...     

HIAF-BRing束团合并过程中的束流负载效应模拟

强流重离子加速器HIAF-BRing在加速完成后进行束团合并，为研究BRing中的束流负载效应对束团合并的影响，对238U35+束流进行了粒子跟踪模拟。模拟结果显示，在束团合并过程中，束流负载效应引起束团长度和束团中心位置的振荡，导致束流动量分散和束团长度的增长。束团合并过程中尾场电压以及不同束团间尾场的耦合导致的势阱畸变，是引起束团长度和束团中心振荡及束流发射度增长的原因。为了降低束流负载效应的影响，采用多谐波前馈系统进行补偿，达到了补偿束团合并过程中的束流负载效应的目的，从而确保了BRing中引出束流的品质，同时根据模拟结果确定了前馈系统需要覆盖的频率范围和需要补偿的最大尾场电压。     

300 MeV质子重离子同步加速器慢引出动力学研究

300 MeV质子重离子同步加速器是SESRI(空间环境模拟研究装置)的重要组成部分，慢引出系统动力学研究是该同步环设计的关键。引出系统采用三阶共振慢引出与RF-Knockout(RF-KO)方案为终端提供2～8 s准连续束，在引出静电偏转板处利用3-bump局部凸轨可适当调节螺距和引出角度，但同时也会减小水平工作点，缩小相空间稳定区面积，影响束流正常引出。模拟结果表明，凸轨内二极磁铁和六极磁铁会引起水平工作点减小，造成引出初始阶段粒子大量溢出。因此，基于自主编写的粒子追踪程序SESP对束流时间结构进行了分析，并通过优化激励调幅曲线改善了束流时间结构的均匀性。     

HIRFL-CSR commissioning in 2006 and 2007

HIRFL-CSR, a new heavy ion cooler-storage-ring system at IMP, had been in commissioning since the beginning of 2006. In the two years of 2006 and 2007 the CSR commissioning was finished, including the stripping injection (STI), electron-cooling with hollow electron beam, C-beam stacking with the combination of STI and e-cooling, the wide energy-range synchrotron ramping from 7 MeV/u to 1000 MeV/u by changing the RF harmonic-number at mid-energy, the multiple multi-turn injection (MMI), the beam accumulation with MMI and e-cooling for heavy-ion beams of Ar, Kr and Xe, the fast extraction from CSRm and single-turn injection to CSRe, beam stacking in CSRe and the RIBs mass-spectrometer test with the isochronous mode in CSRe by using the time-of-flight method.