衍射极限储存环物理设计研究进展

总结了国内外在衍射极限储存环(DLSR)物理设计方面的研究进展。为了在合理的周长范围内实现超低束流发射度,DLSR线性束流光学设计普遍采用紧凑型多二极铁消色散结构。在非线性动力学优化中,通常采用相移控制技术、解析和数值优化技术减小由色品六极铁导致的强非线性效应。DLSR束流接受度较小,主要考虑脉冲多极铁偏轴注入和快速冲击磁铁在轴注入两种注入方案。束流集体效应(尤其是束流内部散射和托歇克散射效应)随发射度降低而增强,需要采用束长拉伸、横向反馈等方法提高DLSR中束流的稳定性。     

北京散裂中子源RCS注入系统物理设计和研究

北京散裂中子源(BSNS)的主加速器——快循环同步加速器(RCS)采用H^－剥离注入方法, 将从直线加速器预加速的束流进行累积和进一步加速. 束流损失率的控制是该类高功率质子加速器所面临的关键问题之一, 而束流损失中很重要的部分是由空间电荷效应造成的. 为了减小该类束流损失, 注入系统设计中利用H^－剥离注入和相空间涂抹方法将直线加速器预加速的发射度较小的束流尽可能均匀地涂抹到较大的横向相空间中. 与其他的类似加速器相比, RCS注入系统将所有注入元件放在一个长为9m的无色散漂移节中以充分节省RCS环的纵向空间, 并使对注入系统的操作与对RCS主体的操作完全独立. 对于RCS累积的粒子数1.9×10¹³, 空间电荷效应对粒子的运动有非常重要的作用, 本文介绍了采用ORBIT程序进行三维模拟计算并进行设计优化的结果. 还介绍了系统设计时需要考虑的其他重要因素, 如质子穿越、电子收集等.     

带空间电荷效应的横向发射度测量

CADS注入器Ⅰ试验装置由中国科学院高能物理研究所承建。其10 mA的束流由RFQ结构加速到3.2 MeV,经中能传输段匹配到超导加速结构。为了减小失匹配造成的束流损失,需要测量RFQ出口束流参数,以便调整中能传输段Lattice结构,使束流能匹配进入超导腔。CADS注入器Ⅰ采用丝靶扫四极铁参数的方式测量束流截面并计算RFQ出口Twiss参数。强流加速器在低能段空间电荷力很强,常规的基于矩阵的数据处理方法会带来误差。本文分别用常规的未考虑空间电荷效应的矩阵方法和考虑了空间电荷效应的遗传算法对数据进行处理,得到的结果显示低能强流加速器进行Twiss参数测量时,必须考虑空间电荷效应的影响。     

带空间电荷效应的横向发射度测量（英文）

CADS注入器Ⅰ试验装置由中国科学院高能物理研究所承建。其10mA的束流由RFQ结构加速到3.2 MeV,经中能传输段匹配到超导加速结构。为了减小失匹配造成的束流损失,需要测量RFQ出口束流参数,以便调整中能传输段Lattice结构,使束流能匹配进入超导腔。CADS注入器Ⅰ采用丝靶扫四极铁参数的方式测量束流截面并计算RFQ出口Twiss参数。强流加速器在低能段空间电荷力很强,常规的基于矩阵的数据处理方法会带来误差。本文分别用常规的未考虑空间电荷效应的矩阵方法和考虑了空间电荷效应的遗传算法对数据进行处理,得到的结果显示低能强流加速器进行Twiss参数测量时,必须考虑空间电荷效应的影响。     

束流逐圈位置测量在BEPC储存环上的初步应用

介绍了利用合肥同步辐射光源(HLS)的逐束团位置测量系统在北京正负电子对撞机(BEPC)上进行的逐圈位置测量实验. 在不同条件下对束流进行逐圈位置测量, 得到束流的相运动图像并观测了阻尼效应. 利用基频数值分析(NAFF)方法对逐圈位置数据分析得到高精度的束流频谱, 可以由此研究各种效应引起的工作点漂移. 实验中观测到特定工作点下由色品校正六极子引起的束流共振现象, 并对此作了合理解释.     

正对撞束束补偿的理论和模拟研究

束束效应是限制对撞机性能提高的重要因素,其限制作用可以通过补偿机制来改善。针对正对撞束束效应,提出两种实现束束补偿的对撞机结构,并对实现束束补偿的原理和需要满足的条件进行分析。提出利用能量回收型直线加速器产生的电子束流进行正对撞束束补偿的方案,并且基于超级质子质子对撞机进行模拟研究,研究了补偿前后束流粒子分布、频移和粒子损失等变化情况。束束补偿可以减小束团内部粒子的频散,减小束流损失,提高束流寿命,可以大幅提高单束团流强,从而提高对撞机亮度。     

CSNS RCS注入横向相空间涂抹的研究

中国散裂中子源(CSNS)加速器系统由80MeV的直线加速器和1.6GeV的快循环同步加速器(RCS)构成. CSNS第一阶段采用H^－剥离注入方法, 将粒子数累积至1.88×10¹³. 注入束流被涂抹在较大的横向相空间内, 以减小空间电荷效应. 粒子注入后, 为了降低由空间电荷效果引起的工作点漂移和工作点弥散, 束流分布的均匀性很重要. 引入了评估束流分布均匀性的三个参数. 为了抑制注入过程中束流发射度和束晕的增长, 通过采用三维的模拟程序ORBIT, 对不同的横向相空间涂抹方案进行了比较. 同时还介绍了工作点、注入峰值流强和斩波调制比等因素对注入过程的影响.     

Lambertson型切割磁铁漏场的3维模拟计算和优化设计

 Lambertson型切割磁铁的漏场对RCS中的束流运行有较大的影响,包括束流集体不稳定效应以及高阶共振效应,为了对该型磁铁进行优化,利用3维磁场模拟程序OPERA3D/TOSCA,对北京散裂中子源/快循环同步加速环（CSNS/RCS）引出Lambertson型切割磁铁进行了物理设计。通过对不同的磁铁设计方案进行3维模拟计算和优化发现,采用15 mm厚的切割板以及在屏蔽管出口处添加半径为200 mm、厚度为10 mm屏蔽帽的磁场屏蔽措施,将Lambertson型切割磁铁的横向漏场降低到主磁场的0.80‰（y方向）和0.36‰（x方向）,可以满足CSNS/RCS环的束流动力学设计要求。     

CSNS/RCS中的阻抗和束流不稳定性

中国散裂中子源（CSNS）的快循环同步加速器（RCS）是一台强流质子加速器,其束流平均功率达到100 kW。在此强流加速器中,真空部件的阻抗是引起束流不稳定的主要原因,它严重限制了束流强度及品质。对CSNS/RCS设计中的各种真空部件阻抗进行了详细计算,并以计算结果为出发点,理论分析了各种不稳定性强弱,确定了各种不稳定性发生的阻抗阈值,为真空部件结构设计提供了参考。对比较严重的电阻壁阻抗,采用阻抗壁尾场模型进行跟踪模拟,得到不稳定性增长率与理论计算值符合较好。自然色品有助于束流稳定,加入自然色品后模拟,电阻壁不稳定性消失。     

北京大学ERL装置交汇段的研究与设计

 在交汇段设计理论的基础上,针对北京大学ERL的具体情况,对交汇段的束流传输结构进行了优化设计,通过模拟得到了满足要求的一组设计参数;研究了空间电荷效应以及相干同步辐射对束流发射度、能散及包络的影响。结果表明：空间电荷效应对发射度影响不大,但对束流包络影响较明显;相干同步辐射引起的发射度增长及能散较小,且不影响束流包络。     

Study on the effects of chromaticity and magnetic field tracking errors at CSNS/RCS

The Rapid Cycling Synchrotron (RCS) is a key component of the China Spallation Neutron Source (CSNS). For this type of high intensity proton synchrotron, the chromaticity, space charge effects, and magnetic field tracking errors between the quadrupoles and the dipoles can induce beta function distortion and tune shift, and induce resonances. In this paper, the combined effects of chromaticity, magnetic field tracking errors and space charge on beam dynamics at CSNS/RCS are studied systemically. 3-D simulations with different magnetic field tracking errors are performed by using the code ORBIT, and the simulation results are compared with the case without tracking errors.     

Study on space charge effects of the CSNS/RCS

The Rapid Cycling Synchrotron (RCS) is a key component of the China Spallation Neutron Source (CSNS). The space charge effect is one of the most important issues in the CSNS/RCS, which limits the maximum beam intensity, as well as the maximum beam power. Space charge effects are the main source of emittance growth and beam loss in the RCS. Space charge effects have been studied by simulation for the CSNS/RCS. By optimizing the painting orbit, the optimized painting distribution was obtained. The space charge effects during the acceleration are studied and dangerous resonances, which may induce emittance growth and beam loss, are investigated. The results are an important reference for the design and commissioning of the CSNS/RCS.     

中国散裂中子源磁铁系统和样机研制

中国散裂中子源(China Spallation Neutron Source, CSNS)快循环同步加速器(Rapid Cycling Synchrotron, RCS)磁铁由24块二极磁铁、48块四极磁铁、16块六极磁铁和若干斜四极磁铁以及校正磁铁组成, 其中二极磁铁和四极磁铁是带直流偏置的25Hz正弦交流励磁, 铁芯和线圈导体将产生不可忽视的涡流效应. 为了积累批量生产磁铁的制造经验, 探索磁铁后期处理和磁场测量方法, 已完成了中空水冷铝绞线试样线圈的研制, 启动了二极磁铁和四极磁铁样机的研制. 本文将对相关进展进行介绍.     

The compensation of quadrupole errors and space charge effects by using trim quadrupoles

The China Spallation Neutron Source (CSNS) accelerators consist of an H-linac and a proton Rapid Cycling Synchrotron (RCS). RCS is designed to accumulate and accelerate proton beam from 80 MeV to 1.6 GeV with a repetition rate of 25 Hz. The main dipole and quadruple magnet will operate in AC mode. Due to the adoption of the resonant power supplies, saturation errors of magnetic field cannot be compensated by power supplies. These saturation errors will disturb the linear optics parameters, such as tunes, beta function and dispersion function. The strong space charge effects will cause emittance growth. The compensation of these effects by using trim quadruples is studied, and the corresponding results are presented.     

Studies of dual-harmonic acceleration at CSNS-Ⅱ

The Rapid Cycling Synchrotron(RCS) of the China Spallation Neutron Source(CSNS) complex is designed to provide 1.56×1013 protons per pulse(ppp) during the initial stage,and it is upgradeable to 3.12×1013 ppp during the second stage and 6.24×1013 ppp during the ultimate stage.The high beam intensity in the RCS requires alleviation of space charge effects to reduce beam losses,which is key in such high beam power accelerators.With higher intensities in the upgrading phases,a dual-harmonic RF system is planned to produce flat-topped bunches that are useful to reduce the space charge effects.We have studied different schemes to apply the dual-harmonic acceleration in CSNS-,and have calculated the main parameters of the RF systems,which are presented in this paper.     

Producing terahertz coherent synchrotron radiation at the Hefei Light Source

This paper theoretically proves that an electron storage ring can generate coherent radiation in the THz region using a quick kicker magnet and an AC sextupole magnet. When the vertical chromaticity is modulated by the AC sextupole magnet, the vertical beam collective motion excited by the kicker produces a wavy spatial structure after a number of longitudinal oscillation periods. The radiation spectral distribution was calculated from the wavy bunch parameters at the Hefei Light Source(HLS). When the electron energy is reduced to 400 Me V, extremely strong coherent synchrotron radiation(CSR) at 0.115 THz should be produced.     

Theoretical study of a dual harmonic system and its application to the CSNS/RCS

Dual harmonic systems have been widely used in high intensity proton synchrotrons to suppress the space charge effect,as well as reduce the beam loss.To investigate the longitudinal beam dynamics in a dual rf system,the potential well,the sub-buckets in the bunch and the multi-solutions of the phase equation are studied theoretically in this paper.Based on these theoretical studies,optimization of bunching factor and rf voltage waveform are made for the dual harmonic rf system in the upgrade phase of the China Spallation Neutron Source Rapid Cycling Synchrotron(CSNS/RCS).In the optimization process,the simulation with space charge effect is done using a newly developed code,C-SCSIM.     

Introduction to the overall physics design of CSNS accelerators

The China Spallation Neutron Source (CSNS) is an accelerator-based facility. The     

An overview of design for CSNS/RCS and beam transport

The China Spallation Neutron Source (CSNS) is the first accelerator-based pulsed neutron source in China. Its accelerators are made up of an 80 MeV H⁻ linac, a Rapid Cycling Synchrotron (RCS) and two beam transport lines. RCS accumulates and accelerates protons to the design energy of 1.6 GeV, and extracts high energy beam to strike the target. The overview of RCS is presented, and the key problems of the physics design are discussed. The two beam transport lines, from linac to RCS and from RCS to the target, are also introduced.

     

六极磁铁的三级Lie映射

用Lie代数方法分析了相对论带电粒子在六极磁铁中的运动,得到在六维相空间中粒子的三级近似轨迹.