Sebastian Maier, Miriam Brosi, Akira Mochihashi, Michael J. Nasse, Markus Schwarz, Anke-Susanne Müller
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引用次数: 0
摘要
在束长为个位数皮秒的情况下,同步辐射光源会产生高达太赫兹范围的强相干辐射。通过降低动量压实因子(低$\alpha$)来减小束长会引起微束不稳定性,这一方面会导致有效束长的延长,从而成为 X 射线范围内的关键障碍,但另一方面,如果能够对其进行适当控制,也会为产生强烈的太赫兹辐射提供机会。在 KIT 的 KARA(卡尔斯鲁厄研究加速器)储存器中,计划在电子储存器中安装两块带有周期性矩形波纹的平行板。这两块板的几何形状会产生额外的纵向阻抗,从而影响电子束的动力学特性。由此产生的阻抗操纵将用于研究和控制纵向电子束动力学和发射的相干同步辐射(CSR)。本文以 KARA 储存环为例,介绍了模拟附加波纹板阻抗对纵向电子束动力学影响的系统研究结果。如果波纹板唤醒函数的周期性与纵向波束剖面中的子结构大小相匹配,就可以有效地控制不稳定阈值。这就将强太赫兹辐射扩展到了不同的束流状态。
Simulation of the impact of an additional corrugated structure impedance on the bursting dynamics in an electron storage ring
In the case of single-digit picosecond bunch length, synchrotron light
sources produce intense coherent radiation up to the THz range. The reduction
of the bunch length by lowering the momentum compaction factor (low-$\alpha$)
gives rise to the micro-bunching instability, which is on one hand a crucial
roadblock in the X-ray range during to the resulting effective bunch
lengthening but on the other hand also an opportunity for the generation of
intense THz radiation if it can be controlled appropriately. In the KIT storage
ring KARA (Karlsruhe Research Accelerator), two parallel plates with periodic
rectangular corrugations are planned to be installed in an electron storage
ring. These plates create an additional longitudinal impedance based on their
geometry, which can affect the beam dynamics. The resulting impedance
manipulation will be used to study and control the longitudinal electron beam
dynamics and the emitted coherent synchrotron radiation (CSR). This paper
presents the results of systematic studies in simulation of the impact of
additional corrugated plate impedances on the longitudinal beam dynamics using
the example of the KARA storage ring. If the periodicity of the wake function
of the corrugated plates matches the size of the substructures in the
longitudinal bunch profile, the instability threshold can be effectively
manipulated. This extends intense THz radiation to different beam current
regimes.