国际直线对撞机升级用行波超导射频腔的优化设计

V. Shemelin, H. Padamsee, V. Yakovlev
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引用次数: 2

摘要

驻波(SW) TESLA铌基超导射频结构受临界射频磁场的限制,加速梯度约为50 MV/m。为了突破这一障碍,我们探索了铌基行波结构的选择。考虑实验已知的极限电场和极限磁场,对TW结构进行了优化。结果表明,在临界磁场相同的情况下,TW结构的加速梯度可以达到70mev /m以上,是当代驻波结构的1.5倍左右。TW结构的另一个好处是R/Q比TESLA结构高约2倍,将动态热负荷降低了2倍。提出了一种使TW结构无多因子的方法。提出了一些便于制作的设计方案。由于更高的群速度和细胞间耦合,通过增加加速结构的长度也可以进一步增加面积梯度(相当于80 MV/m的有源梯度)。这项工作的实现为与CLIC竞争的ILC能量从1 TeV升级到3 TeV开辟了道路。本文将讨论相应的机遇和挑战。
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OPTIMIZATION OF A TRAVELING WAVE SUPERCONDUCTING RADIOFREQUENCY CAVITY FOR UPGRADING THE INTERNATIONAL LINEAR COLLIDER
The Standing Wave (SW) TESLA niobium-based superconducting radio frequency structure is limited to an accelerating gradient of about 50 MV/m by the critical RF magnetic field. To break through this barrier, we explore the option of niobium-based traveling wave (TW) structures. Optimization of TW structures was done considering experimentally known limiting electric and magnetic fields. It is shown that a TW structure can have an accelerating gradient above 70 MeV/m that is about 1.5 times higher than contemporary standing wave structures with the same critical magnetic field. The other benefit of TW structures shown is R/Q about 2 times higher than TESLA structure that reduces the dynamic heat load by a factor of 2. A method is proposed how to make TW structures multipactor-free. Some design proposals are offered to facilitate fabrication. Further increase of the real-estate gradient (equivalent to 80 MV/m active gradient) is also possible by increasing the length of the accelerating structure because of higher group velocity and cell-to-cell coupling. Realization of this work opens paths to ILC energy upgrades beyond 1 TeV to 3 TeV in competition with CLIC. The paper will discuss corresponding opportunities and challenges.
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