Multiphysics Simulations of Thermal Shock Testing of Nanofibrous High Power Targets

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

Increase of primary beam power for neutrino beam-lines leads to a reduced lifespan for production targets. New concepts for robust targets are emerging from the field of High Power Targetry (HPT); one idea being investigated by the HPT R&D Group at Fermilab is an electrospun nanofiber target. As part of their evaluation, samples with different densities were sent to the HiRadMat facility at CERN for thermal shock tests. The samples with the higher density, irradiated under a high intensity beam pulse, exhibit major damage at the impact site whereas those with the lower density show no apparent damage. The exact cause of this failure was unclear at the time. In this paper, we present the results of multiphysics simulations of the thermal shock experienced by the nanofiber targets that suggest the failure originates from the reduced permeability of the high density sample to air flow. The air present in the porous target expands due to heating from the beam, but is unable to flow freely in the high density sample, resulting in a larger back pressure that blows apart the nanofiber mat. We close with a discussion on how to further validate this hypothesis.
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纳米纤维高功率靶材热冲击测试的多物理场模拟
中微子束线一次束功率的增加导致生产靶寿命的缩短。高功率靶材(HPT)领域正在出现新的坚固靶材概念;费米实验室高功率靶材研发小组正在研究的一个概念是电纺纳米纤维靶材。作为评估的一部分,不同密度的样品被送往欧洲核子研究中心的 HiRadMat 设施进行热冲击测试。密度较高的样品在高强度光束脉冲的照射下,在撞击部位出现了严重的损坏,而密度较低的样品则没有出现明显的损坏。当时还不清楚这种失效的确切原因。在本文中,我们介绍了对当时纤维靶所经历的热冲击进行多物理场模拟的结果,结果表明,失效的原因是高密度样品对气流的渗透性降低。多孔靶材中的空气因光束加热而膨胀,但无法在高密度样品中自由流动,从而产生较大的背压,将纳米纤维毡吹散。最后,我们将讨论如何进一步验证这一假设。
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