Bayesian optimization scheme for the design of a nanofibrous high power target

arXiv - PHYS - Accelerator Physics Pub Date : 2024-05-29 DOI:arxiv-2405.19490

W. AsztalosIllinois Institute of Technology, Y. TorunIllinois Institute of Technology, S. BidharFermi National Accelerator Laboratory, F. PellemoineFermi National Accelerator Laboratory, P. RathIndian Institute of Technology Bhubaneswar

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Abstract

High Power Targetry (HPT) R&D is critical in the context of increasing beam intensity and energy for next generation accelerators. Many target concepts and novel materials are being developed and tested for their ability to withstand extreme beam environments; the HPT R&D Group at Fermilab is developing an electrospun nanofiber material for this purpose. The performance of these nanofiber targets is sensitive to their construction parameters, such as the packing density of the fibers. Lowering the density improves the survival of the target, but reduces the secondary particle yield. Optimizing the lifetime and production efficiency of the target poses an interesting design problem, and in this paper we study the applicability of Bayesian optimization to its solution. We first describe how to encode the nanofiber target design problem as the optimization of an objective function, and how to evaluate that function with computer simulations. We then explain the optimization loop setup. Thereafter, we present the optimal design parameters suggested by the algorithm, and close with discussions of limitations and future refinements.

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设计纳米纤维高功率靶的贝叶斯优化方案

高功率靶材（HPT）研发对于提高下一代加速器的光束强度和能量至关重要。目前正在开发许多靶概念和新型材料，并对其承受极端光束环境的能力进行测试；费米实验室的 HPT 研发小组正在为此开发一种电纺纳米纤维材料。纳米纤维靶的性能对其结构参数非常敏感，例如纤维的包装密度。降低密度可以提高靶的存活率，但会降低二次粒子的产量。优化靶材的寿命和生产效率提出了一个有趣的设计问题，在本文中，我们研究了贝叶斯优化法在解决这一问题中的适用性。我们首先介绍了如何将纳米纤维靶设计问题编码为目标函数的优化，以及如何通过计算机模拟来评估该函数。然后，我们解释了优化循环的设置。之后，我们提出了该算法建议的最佳设计参数，最后讨论了局限性和未来的改进。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Accelerator Physics

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