Geometry Optimization of Muon Production Graphite Target by 600 MeV Proton Beam

2020 IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC) Pub Date : 2020-10-31 DOI:10.1109/NSS/MIC42677.2020.9508097

J. Jeong, Jae Chang Kim, J. Son, K. Pak, Yong Kyun Kim, Ju Hahn Lee

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Abstract

The Rare Isotope Science Project was launched in December 2011, and a heavy-ion accelerator complex in Korea, named RAON, has been designed, including a muon facility for muon spin rotation, relaxation, and resonance (μSR). In this study, the graphite target in RAON was designed to have a rotating ring shape and was cooled by radiative heat transfer, which presents advantages in the cool-down process such as a low-temperature gradient in the target and no necessity of a liquid coolant-cooling system. Monte-Carlo simulations and ANSYS calculations were performed to optimize the proton beam size and the dimensions of the target to produce a sufficient number of surface muons in a thermally stable condition. A comparison between the simulation and the experimental data was also included in this paper in order to obtain a reliable result. The expected number of surface muons was 6.942×108 with a 100 kW proton beam and Δp/p~5%. The maximum temperature was 2012 °K and the maximum stress in the target was 8.1598 kPa with the 400 kW proton beam, which guarantees safety during the replacement cycle of the target.

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600 MeV质子束产生μ子石墨靶的几何优化

2011年12月启动了“稀有同位素科学事业”，在韩国设计了重离子加速器“RAON”，其中包括μ子自旋、弛豫、共振(μSR)的μ子设施。在本研究中，RAON中的石墨靶被设计成一个旋转的环形，并通过辐射传热进行冷却，这在冷却过程中具有靶内温度梯度低，不需要液冷冷却系统的优点。通过Monte-Carlo模拟和ANSYS计算，优化了质子束的尺寸和靶体的尺寸，以在热稳定的条件下产生足够数量的表面μ子。为了得到可靠的结果，本文还将仿真数据与实验数据进行了比较。在100 kW质子束和Δp/p~5%的条件下，表面介子的期望数为6.942×108。最高温度为2012°K，靶内最大应力为8.1598 kPa，质子束功率为400 kW，保证了靶在更换周期内的安全性。

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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2020 IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC)

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