In this work, the surface response of a tungsten plasma-facing component was simulated by a cluster-dynamics code, Xolotl, with a focus on quantifying the impact of uncertainty in one of the input parameters to Xolotl, namely, the incident helium flux. The simulated conditions involve a tungsten surface exposed to 100 eV helium ion implantations with a flux of either 4 x 10(22) or 4 x 10(25) He m(-2) S-1. Two sources were used to describe the implanted helium depth distribution in tungsten, either molecular dynamics (MD) or a binary collision approximation code, the stopping and range of ions in matter (SRIM). The aim of this work is to evaluate and examine uncertain predictions on the helium retention based on these two different modeling methodologies that either neglect electronic energy loss or the crystalline structure of the solid, respectively. An embedded model-form error approach was pursued here in order to arrive at predictions that account for variability due to the two different data sources, and the impact of this model-form uncertainty in incident helium flux on Xolotl output was presented for the two implantation fluxes.
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机译:在这项工作中,通过集群动力学代码Xolotl模拟了一个面向钨等离子体组件的表面响应,重点是量化不确定性对Xolotl输入参数之一(即入射氦通量)的影响。模拟条件涉及暴露于100 eV氦离子注入的钨表面,其通量为4 x 10(22)或4 x 10(25)He m(-2)S-1。有两种来源用来描述钨中氦的注入深度分布,无论是分子动力学(MD)还是二进制碰撞逼近码,物质中离子的终止和范围(SRIM)。这项工作的目的是基于这两种不同的建模方法(分别忽略电子能量损失或固体的晶体结构)来评估和检查关于氦气保留的不确定性预测。此处采用嵌入式模型形式误差方法,以便得出可解释由于两个不同数据源而导致的可变性的预测,并针对两种注入方式介绍了入射氦气入射时这种模型形式不确定性对Xolotl输出的影响通量。
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