用厚楔为缪子对撞机进行最终冷却

arXiv - PHYS - Accelerator Physics Pub Date : 2024-08-22 DOI:arxiv-2408.12696

D. FuUniversity of Chicago, A. Badea. K. Folan Di PetrilloUniversity of Chicago, D. NeufferFermilab, D. StratakisFermilab

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引用次数: 0

摘要

在μ介子对撞机的最后冷却阶段，横向幅射会减小，而纵向幅射会增大。在以前的研究中，最终冷却使用了极高磁场螺线管内的吸收器来冷却低动量μ介子。对系统的模拟没有达到预期的冷却设计目标。在这项研究中，我们开发并优化了基于密集楔形吸收器的最终 4D 冷却通道的不同概念设计。我们使用 G4Beamline 对通道进行模拟，并使用 Python 生成和分析粒子分布。我们优化了冷却通道的设计参数，并产生了概念设计（对应于输入光束的可能起始点），这些设计在 x 和 y 方向上都实现了 3.5 倍的横向冷却。这些通道的横向和纵向幅射均低于以前公布的最佳设计。

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Final Cooling With Thick Wedges for a Muon Collider

In the final cooling stages for a muon collider, the transverse emittances are reduced while the longitudinal emittance is allowed to increase. In previous studies, Final cooling used absorbers within very high field solenoids to cool low-momentum muons. Simulations of the systems did not reach the desired cooling design goals. In this study, we develop and optimize a different conceptual design for the final 4D cooling channel, which is based on using dense wedge absorbers. We used G4Beamline to simulate the channel and Python to generate and analyze particle distributions. We optimized the design parameters of the cooling channel and produced conceptual designs (corresponding to possible starting points for the input beam) which achieve transverse cooling in both x and y by a factor of $\approx$ 3.5. These channels achieve a lower transverse and longitudinal emittance than the best previously published design.

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arXiv - PHYS - Accelerator Physics

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