X波段失谐加速结构的计算

采用Mafia程序设计X波段失谐加速结构,同时利用Largrange插值的方法计算了加速结构的尺寸,得到了加速结构的特性参数和尾场特性。结果表明,失谐加速结构的品质因子（7 926.0~8 012.2）和分路阻抗（89.7~125.1MΩ/m）比较高,与等阻抗加速结构相比,可以使尾场明显下降,从而降低束流崩溃发生的可能性。     

介质壁加速器尾场阻抗的模拟计算

为了研究尾场效应引起的束流不稳定性,建立了由非对称Blumlein脉冲形成线、导体层和微堆层构成的介质壁加速器单元模块模型,用有限积分法对强流电子束在此结构中产生的尾场进行了计算,分别计算单组元和2组单元加速模块中的尾场势和尾场阻抗。从模拟的结果来看,x, y方向的尾场势和尾场阻抗都很小,束流尾场对横向的影响比较小。z方向的尾场势和尾场阻抗影响较大,尾场阻抗达到100 Ω量级。证明了由于介质壁加速器结构在加速腔长度和束流通过路径的连续性方面都具有很大的优势,横向阻抗小,束流尾场效应在束流不稳定性方面的影响相对较小,束流传输时的要求也会降低。     

介质壁加速器尾场阻抗的模拟计算

为了研究尾场效应引起的束流不稳定性,建立了由非对称Blumlein脉冲形成线、导体层和微堆层构成的介质壁加速器单元模块模型,用有限积分法对强流电子束在此结构中产生的尾场进行了计算,分别计算单组元和2组单元加速模块中的尾场势和尾场阻抗。从模拟的结果来看,x,y方向的尾场势和尾场阻抗都很小,束流尾场对横向的影响比较小。z方向的尾场势和尾场阻抗影响较大,尾场阻抗达到100Ω量级。证明了由于介质壁加速器结构在加速腔长度和束流通过路径的连续性方面都具有很大的优势,横向阻抗小,束流尾场效应在束流不稳定性方面的影响相对较小,束流传输时的要求也会降低。     

附加克尔介质Jaynes－Cummings模型的场熵演化

研究了附加克尔（Ｋｅｒｒ）介质Ｊａｙｎｅｓ－Ｃｕｍｍｉｎｇｓ（Ｊ－Ｃ）模型场熵演化的动力学特性，讨论了克尔介质非线性相互作用以及失谐量对场熵演化的影响．     

附加克尔介质Jaynes—Cummings模型的场熵演化

研究了附加克尔（Ｋｅｒｒ）介质Ｊａｙｎｅｓ－Ｃｕｍｍｉｎｇｓ（Ｊ－Ｃ）模型场熵演化的动力学特性，讨论了克尔介质非线性相互作用以及失谐量对场熵演化的影响。     

三能级电磁感应透明中辐射场的量子统计特性

对Λ型三能级原子电磁感应透明（EIT）过程中辐射场的二阶相干度进行了研究。理论分析表明，在电磁感应透明系统中，由于原子的相干效应导致其上能级共振荧光场的二阶相干度将呈现单光子场的量子统计特性。并对其随耦合场强度和探测光失谐的变化进行了详细的分析和讨论，结果发现：在｜Ω｜〉（Γ2＋Γ3）／2情况下．采用较弱的耦合光功率（由托比频率Ω表征）及较大的探测光失谐，在较长时间延迟范围内，二阶相十度保持小于1，更利于实现非经典场的量子统计行为；相反，在｜Ω｜≤（Γ2＋Γ3）／2情况下，探测光的失谐量越小，越利于获得二阶相干度小于1的量子统计光场。南此可见选取合适的参量可优化电磁感应透明过程中单光子场的量子统计特性。     

优化脉冲间距的多脉冲尾流加速PIC模拟

多脉冲激光尾波场加速电子方法中限制尾波场振幅的主要机理是“相位失谐”,起源于非线 性效应导致尾波波长随振幅的增长而变大,从而后续脉冲逐渐偏离加速相位. 借助2D3V PIC 模拟方法优化各脉冲之间的间距,使之等于前面脉冲激发的尾波波长,模拟结果表明激发了 更大振幅的尾波场,同时激发了更强的“前向Raman散射”,它在限制尾波场进一步增长的 过程发挥了重要作用. 关键词： 多脉冲激光尾波加速 有质动力 相位失谐 前向Raman散射     

等梯度加速结构中的尾场计算研究

带电粒子束在穿过加速结构时激起的尾场, 会导致束流能散和发射度的增大. 准确计算尾场对正确估计尾场效应对束流性能的影响具有重要意义. 本文对等梯度加速结构中短程尾场、中长程尾场和超长程尾场的计算方法进行了较系统的研究, 并首次给出了超长程尾场的计算公式. 此外, 本文还给出了BEPCⅡ直线加速器等梯度加速结构中短程尾场、中长程尾场以及超长程尾场的计算结果, 并对多种方法计算结果的一致性和在某些范围内的差别做了分析说明.     

下一代直线对撞机失谐结构尾场的精确计算：—盘荷波导电磁 …

利用变分法研究了周期性盘荷波导中零极模、二极模及更高极模式的电磁场特性。该方法考虑了栏片的圆弧，对真实结构没有做任何近似，是一种高精度方法，计算表明该方法的结果与实验测量值基本符合，与其它程序相比有很高的计算精度，这为下一步精确研究下一代直线对机失谐结构的尾场提供了一个很好的方法与工具。     

200 MHz质子带窗四翼型射频四极场加速器结构模拟研究

根据束流动力学设计方案,使用电磁场计算软件CST Microwave Studio对带窗四翼型射频四极场（RFQ）结构进行了模拟研究,分析了加速腔结构参数对其物理特性的影响,得到了200 MHz质子带窗四翼型RFQ优化结构方案。该结构的比分路阻抗为79.5 km,模式间隔达25.802 MHz。与传统的四翼型RFQ比较结果表明：带窗四翼型RFQ具有较低的工作频率范围、良好的电稳定性以及较高的比分路阻抗。     

Plasma-density-gradient injection of low absolute-momentum-spread electron bunches

Plasma density gradients in a gas jet were used to control the wake phase velocity and trapping threshold in a laser wakefield accelerator, producing stable electron bunches with longitudinal and transverse momentum spreads more than 10 times lower than in previous experiments (0.17 and 0.02 MeV/c FWHM, respectively) and with central momenta of 0.76+/-0.02 MeV/c. Transition radiation measurements combined with simulations indicated that the bunches can be used as a wakefield accelerator injector to produce stable beams with 0.2 MeV/c-class momentum spread at high energies.     

激光-等离子体加速器研究综述

综述了有关激光尾场加速器、等离子体拍频波加速器、多束激光脉冲驱动的尾场加速器以及自调制激光尾场加速器的概念及其基本特性,概述了近期的实验结果。介绍了等离子体波的产生机理及等离子体波中电子的俘获和加速,并讨论了存在于激光等离子体加速器中的一些限制和今后发展前景。     

激光等离子体加速器研究综述

综述了有关激光尾场加速器、等离子体拍频波加速器、多束激光脉冲驱动的尾场加速器以及自调制激光尾场加速器的概念及其基本特性,概述了近期的实验结果。介绍了等离子体波的产生机理及等离子体波中电子的俘获和加速,并讨论了存在于激光等离子体加速器中的一些限制和今后发展前景。     

激光等离子体加速器研究综述

 综述了有关激光尾场加速器、等离子体拍频波加速器、多束激光脉冲驱动的尾场加速器以及自调制激光尾场加速器的概念及其基本特性,概述了近期的实验结果。介绍了等离子体波的产生机理及等离子体波中电子的俘获和加速,并讨论了存在于激光等离子体加速器中的一些限制和今后发展前景。     

Overview of plasma-based accelerator concepts

An overview is given of the physics issues relevant to the plasma wakefield accelerator, the plasma beat-wave accelerator, the laser wakefield accelerator, including the self-modulated regime, and wakefield accelerators driven by multiple electron or laser pulses. Basic properties of linear and nonlinear plasma waves are discussed, as well as the trapping and acceleration of electrons in the plasma wave. Formulas are presented for the accelerating field and the energy gain in the various accelerator configurations. The propagation of the drive electron or laser beams is discussed, including limitations imposed by key instabilities and methods for optically guiding laser pulses. Recent experimental results are summarized     

Experimental Test of 7.8GHz Power Extractor Using Dielectric Loaded Rectangular Waveguide Structures

We report on experimental test of a 7.8 GHz power extractor using a dielectric loaded rectangular waveguide structure. This work is conducted at the Argonne wakefield accelerator （AWA） facility. The wakefield is excited by an electron beam travelling through a dielectric loaded rectangular waveguide, and the generated rf power is then subsequently extracted with a properly designed rf coupler. In the experiment, 30 MW of output power is excited by a 66nC single electron bunch, and wakefield superposition by a train consisting of four bunches is also demonstrated. Both the results agree well with theoretical predictions.     

Transverse modulation of an electron beam generated in self-modulated laser wakefield accelerator experiments

Low energy electron beams (E approximately 300 keV) generated in a self-modulated laser wakefield accelerator experiment were observed to filament and be deflected away from the laser axis forming radial jets in the electron beam profile. At higher energies (E>900 keV), the filamentation and jets were suppressed and smooth electron beams copropagating with the laser were observed. The observed electron beam filamentation likely results from laser beam filamentation in the plasma due to relativistic self-focusing effects. The radial jets of low energy electrons are likely caused by transverse ejection of the electrons due to the radial structure of the wakefield and space charge deflection of electrons as they exit the laser focus.     

Tunable wakefield dielectric-filled accelerating structure

The feasibility of the frequency spectrum of Vavilov-Cherenkov radiation being controlled in a wakefield dielectric-filled accelerating structure via an outer ferroelectric layer is studied. The spectrum and amplitude of the field excited in the structure versus the permittivity of the ferroelectric are found. Dielectric losses in the ferroelectric are estimated. It is shown that these losses impose limitations on the ferroelectric layer thickness and the range within which the frequency spectrum of the waveguide can be controlled. The structure under consideration is optimized for the AWA wakefield accelerator. The multilayer construction of the waveguide, in combination with specially shaped ferroelectric-permittivity-controlling electrodes, allows designers to tune the spectrum of the waveguide and suppress electron-bunch-deflecting waveguide modes. Thereby, there appears the possibility of controlling the transverse stability of the beam.     

Ion Plasma Wave Wakefield Accelerators

The possibility of using space-charge waves on an ion beam or column as a wakefield accelerator is discussed. The primary advantages of using ion plasma waves over electron plasma waves are that the kinetic energy and fall-time requirements on the driving beam are reduced. One disadvantage in using a lower plasma frequency is that a larger current is required to achieve the same accelerating gradient. The basic aspects of wakefield accelerators are reviewed and this concept is analyzed in this context. Particle-in-cell simulations show that wakefields utilizing ion waves, although more complicated than plasma wakefields, can produce acceleration.