CAEP自由电子激光摇摆器的改进

摇摆器是自由电子激光研究中的重要组成部分，它的性能好坏将直接决定电子束与光场相互作用的效率。理论和实验表明，摇摆器的磁场强度、峰值误差和好场区宽度对束波作用效率有很大影响，据此对摇摆器做出如下修改：周期长度由30mm改为32mm，磁块与磁极宽度的比值由9：6改为11：5；永磁块、磁极的形状和固定方式改变。通过上述改变可以提高摇摆器磁场强度、提高增益，以提高整个摇摆器品质。     

强磁场混合型短周期摇摆器研究

对混合型短周期摇摆器磁场进行了解析求解,给出了与摇摆器周期、间隙、磁块性能、磁场尺寸以及磁极尺寸等相关的二维解析表达式。根据该公式,作者讨论了混合型短周期摇摆器产生强磁场的潜在能力,提出了一系列改进方法,并分别进行了模型实验,实验结果与理论分析相符合。目前,在1cm周期、5mm间隙的短周期摇摆器模型试验中,中心轴峰值磁感应强度已达到0.45T。另外,该短周期摇摆器可进行单磁场磁场调节,最大峰峰值磁场相对误差小于1％。     

100μmFIR-FEL摇摆器的改进

经过几年实验发现，摇摆器的磁场强度、峰值误差和好场区宽度对束波作用效率有很大影响。为了提高摇摆器性能对摇摆器如下改进：（1）提高磁场强度：永磁块材料采用北京钢研院的钕铁硼N39SH，其风达到11．6kOe（10e≈79．578A／m），B，达到12．3kGs（1Gs=10^-4T），（BH）max为36MGOe；摇摆器周期长度由30mm改为32mm，磁块与磁极宽度的比值由9：6改为11：5；（2）减小峰值误差和增加好场区宽度：改进永磁块、磁极的形状和固定方式，从机械上消除不规则磁块、磁极形状带来的负面影响。通过上述改进可以提高单电子小信号增益与理想增益的比率，即提高整个摇摆器品质。精密的磁场自动测量系统是摇摆器调试过程中所必须的装置，该系统经过改进，具有高精度、高稳定度、可同时监测x、y、z方向磁场值、操作方便等优点，为摇摆器的研制打下良好基础。     

双向聚焦电磁铁摇摆器磁场的数值模拟

 应用磁矢量势公式导出了螺线圈绕组的磁场计算公式，应用标量磁势并对电磁铁作局部均匀磁化近似，给出了电磁铁摇摆器磁场的积分方程式和相应的耦合系数。通过求解积分方程得到了摇摆器磁场的空间分布及摇摆器两端非均匀区的磁场分布。本方法可以为双向聚焦电磁铁摇摆器的设计提供参考数据。     

通道内空气热磁对流的协同分析

为研究通道内空气热磁对流的流动规律,用数值模拟方法,研究了磁场作用下二维模型水平通道内的流动换热过程,获得了通道内的磁通密度分布和空气温度轴向分布,在此基础上,建立了一维通道内空气热磁对流的数学模型,就温度场和磁场的相对关系对水通道内热磁对流过程的影响进行了数值计算,获得了通道内不同温度场、磁场以及其不同相对位置下的通道空气流量,并讨论了磁极形状对空气流量及其变化的影响。     

并行3维全电磁粒子模拟软件NEPTUNE的外加磁场模块设计

介绍了3维全电磁粒子模拟软件NEPTUNE中常用外加磁场加载模块的设计思路和方法,包括简单的磁场分布方程和离散数值加载、螺线管磁场加载、直线及螺旋线磁场分布加载、摇摆器磁场加载以及永磁体磁场加载等方式。每一类磁场加载模式都进行了实际算例的计算和验证,计算结果表明各类磁场加载模块设计的正确性和可靠性。最后针对具体应用,结合二极管电子束在不同外加引导磁场作用下的各种分布状态,间接验证了磁场模块设计的可行性。     

一种高性能小周期摇摆器

介绍一种高性能小周期摇摆器的设计。采用槽型定位的分离状磁块,实现了磁场的半周期调节,对该摇摆器模型进行的测量表明,当摇摆器的周期λ_w=10mm,磁极间隙δ为5mm时,峰值磁场B_w=0.35T,磁场最大偏差δB_w/B_w<1.25％。     

基于保角映射的磁像法的应用

将磁像法与保角映射相结合,求解边界形状复杂的二维静磁场的边值问题,得出磁场的分布规律,并通过MATLAB数据处理软件的数值计算功能进行数值模拟,绘制出其磁感线分布图,验证了所得结论的正确性.此方法拓展了磁像法的应用范围,为求解边界形状复杂的二维静磁场的边值问题提供了一种新的思路和途径.     

磁屏蔽式脉冲电磁铁摇摆器

通常的电磁铁摇摆器,由于相邻磁极间存在的边缘漏磁效应,很难在工作隙中提供足够高的磁感应强度,特别是在大间隙短周期的情况,其应用受到了严重的限制 。本文提出“磁屏蔽式脉冲电磁铁”的新概念,试图寻求一种既廉价又性能优良的摇摆器结构。目前的实验表明,这种磁屏蔽方法可使通常的脉冲电磁铁摇摆器的磁感应强度增大15％以上。     

感应式脉冲推力器中等离子体加速数值研究

为了分析感应式脉冲放电等离子体推力器中时变电磁场作用下等离子体的放电参数分布及其随着磁场强度变化的影响,引入了利用双曲型散度清除方法的二维轴对称瞬态等离子体流动的磁流体力学数值模型.计算结果表明,随着输入能量的增加,等离子体团出现速度峰值的时刻提前,等离子体中同时存在的异号电流环对其加速具有阻滞作用.等离子体的加速效率随着磁场强度非线性增大,磁场大于某一临界值时(几何构型下峰值磁场强度大于0.45 T),有限空间情况下等离子体的加速效率获得显著提高.     

混合型波荡器的3维优化

 以波荡器辐射波和共振电子能及混合型波荡器的解析计算为基础，通过3维磁场的有限元计算，在欧洲光源横向优化基础上，给出了同步辐射和自由电子激光用混合型波荡器纵向优化参数，进而给出了用于DUV FEL混合型波荡器的设计计算参数。加侧位和顶部永磁块后，峰值磁场分别提高到0.722T和0.773T，辅助以1μm量级分辨率的磁间隙调节机械系统，磁场分辨率好于10^-4T量级。     

An off-axis 50-period electromagnet wiggler for millimeter-wavefree-electron laser experiment

An off-axis 50-period planar, short-wavelength (~10 mm) electromagnet wiggler is developed and characterized for millimeter-wave generation using a sheet electron beam in a free-electron laser experiment. Three-dimensional (3-D) magnetic field measurements of the electromagnet wiggler have been carried out. The measured wiggler magnetic field is 0.16 G/A ±3% while the mean value of wiggler wavelength is 0.998±3% cm. Due to off-axis arrangement of poles, there is a magnetic mirror field in the X direction, to confine the sheet beam     

Mode-selective amplification in a waveguide free electron laserwith a two-sectioned wiggler

One important issue in waveguide free electron lasers (FELs) involves an interaction of the electron beam with one waveguide mode at two different resonant frequencies. Since the low-frequency mode often has a higher pain, the usually preferred high-frequency mode is suppressed as a result of mode competition. In this paper, possible control of this mode competition is considered using a nonstandard wiggler magnet consisting of two cascaded wiggler sections with different periods and field strengths. It is demonstrated that with an appropriate differentiation between the two wiggler sections the high-frequency mode may be amplified preferentially. This mode-selective amplification may be used to suppress the low-frequency mode. A small signal gain formulation is developed for a waveguide FEL with such a two-sectioned wiggler arrangement and numerical examples are used to demonstrate its applicability to mode control in waveguide FELs. Effects of wiggler field errors and electron energy spread are also considered. It is shown that the requirement for wiggler field errors and electron energy spread in the two-sectioned wiggler arrangement is similar to that in the usual straight wiggler configuration     

曙光一号自由电子激光器的理论计算

系统总结曙光一号自由电子激光器理论计算的主要结果:包括曙光一号装置主要参数的选取和理解;磁场失谐曲线的计算;常参数摇摆器和变参数摇摆器的主要结果;高阶波导模的贡献;电子束参数扰动对激光性能的影响;空间电荷效应等。计算结果表明,常参数摇摆器激光输出功率可达80MW,效率约50％;变参数摇摆器激光输出功率可达250MW左右,效率约16％。     

左右旋双双绕螺旋线线极化摇摆器的磁场分布及束流传输

给出了双双绕螺旋线线极化Wiggler轴线上磁场的积分表达式,以此公式数字模拟此装置端口区的磁场分布,并进行了实验测定,结果表明,端口区磁场峰值突变和对称性均比圆极化好。另一方面,用洛仑兹运动方程,考虑了电子束空间电荷效应,证明此装置对电子束传输有自聚焦能力,给出了电子运动方程,电子束流与Wiggler峰值磁场的关系,数字模拟电子束运动轨迹也表明,此装置能自聚焦传输电子束,有希望应用于线极化自由电子激光实验中。     

Experimental and numerical studies of sheet electron beampropagation through a planar wiggler magnet

Detailed experimental studies on sheet relativistic electron beam propagation through a long planar wiggler are reported and compared with numerical simulations. The planar wiggler has 56 periods with a period of 9.6 mm. Typically, the wiggler field peak amplitude is 5 kG. The experimental efforts are focused on controlling the deviation of the beam toward the side edge of the planar wiggler along the wide transverse direction. It is found that a suitably tapered magnetic field configuration at the wiggler entrance can considerably reduce the rate of deviation. The effects of the following techniques on beam transport efficiency are discussed: side focusing, beam transverse velocity tuning at the wiggler entrance, and beam spread limiting. High beam transport efficiency (almost 100%) of a 15-A beam is obtained in some cases     

多极超导扭摆器磁体磁场设计

上海光源二期工程建设计划研制一台多极超导扭摆器用于生物医学的X射线成像及治疗。该多极超导扭摆器由21对NbTi超导线圈组成,磁极气隙为22mm,在储存环束流电子能量为3.5GeV时其特征能量为33keV,覆盖的能量范围为20keV到120keV,可用于K边吸收成像、衍射增强成像、相衬成像、CT和微束放射治疗。文中的主要内容为一个具有21个磁极,周期长度为140mm,气隙中心磁感应强度为4.2T的多极超导扭摆器的磁场设计,包括磁极和线圈的参数设计、端部结构和周期磁场的积分场设计,以及简要的超导线圈应力应变分析。     

Permanent magnet wigglers for reducing the emittance of the Petra III synchrotron radiation source

The Petra III synchrotron radiation source was developed based on the Petra-II 6-GeV electron accelerator (DESY). After installing the system for radiation damping, the horizontal emittance of the electron beam of Petra III decreased from 5 nm rad to 1 nm rad, which is a record parameter for this class of installations. The system of radiation damping includes 20 permanent magnet wigglers installed in two straight sections, 50 m each. The total radiation power of the wigglers reaches 800 kW. The wigglers used in the radiation damping system of Petra III were developed in collaboration with DESY (Hamburg) and fabricated by the Budker Institute of Nuclear Physics. The wiggler length is 4.04 m, the gap between the poles is 24 mm, the maximum magnetic field is B = 1.52?1.56 T, and the period is λ = 20 cm. This paper describes the design features of the permanent magnet wigglers and the methods and results of adjustment of the wiggler operating parameters.     

Effect of the Electron‐Beam Self‐Fields on Gain in an Optical Wiggler Pumped Free‐Electron Laser

The effects of self fields on gain for a free‐electron lasers (FELs) with electromagnetic‐wave wiggler and an axial guide magnetic field is presented. The relativistic equation of motion for a single electron for all relevant fields, including wiggler, self‐fields and axial guide magnetic field has been solved. Two classes of possible single‐particle trajectories in this configuration are found. Result of the numerical calculation shown that the relativistic part of group I (group II) orbits decreases (increases) monotonically with the axial field. The gain equations for the FEL configuration by adding the effect of self‐fields have been derived. The numerical calculation has been employed to analysis the gain induced by the effects of the self‐fields. It is shown that, for group I orbits the gain decreases in the presence of self‐fields and the gain decrement increases with increasing axial guide magnetic field, while for group II orbits the self‐fields enhances the gain. The gain decrement and enhancement are due to diamagnetic and paramagnetic effects of the self‐magnetic field, respectively. The comparison of the gain for electromagnetic‐wave wiggler with the gain in helical wiggler has been done (© 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Planar electron beams in a wiggler magnet array

Transport of high current (～kA range with particle energy ～1 MeV) planar electron beams is a topic of increasing interest for applications in high-power (1–10 GW) and high-frequency (10–20 GHz) microwave devices such as backward wave oscillator (BWO), klystrons, gyro-BWOs, etc. In this paper, we give a simulated result for transport of electron beams with velocity $V_{\rm b} = 5.23 \times 10^{8}$  cm s^???1, relativistic factor γ?=?1.16, and beam voltage = ～80 kV in notched wiggler magnet array. The calculation includes self-consistent effects of beam-generated fields. Our results show that the notched wiggler configuration with ～6.97 kG magnetic field strength can provide vertical and horizontal confinements for a sheet electron beam with 0.3 cm thickness and 2 cm width. The feasibility calculation addresses to a system expected to drive for 13–20 GHz BWO with rippled waveguide parameters as width w?=?3.0 cm, thickness t?=?1.0 cm, corrugation depth h?=?0.225 cm, and spatial periodicity d?=?1.67 cm.