使用平滑边界法模拟受阻晶界扩散

Erik Hanson, W Beck Andrews, Max Powers, Kaila Jenkins, Katsuyo Thornton
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摘要

晶界会极大地影响多晶材料的传输特性,尤其是当晶粒尺寸接近纳米级时。晶界通常通过为化学传输提供快速通道来增强扩散,但某些材料系统,如固体氧化物燃料电池和电池阴极颗粒,则表现出相反的行为,即晶界阻碍扩散。为了便于研究晶界扩散受阻的系统,我们提出了一种利用平滑边界法(SBM)模拟多晶体系统中动态浓度演变的模型。该模型采用具有扩散界面的域参数来描述晶粒,从而能够在求解时明确考虑晶粒的复杂几何形状。通过将各种参数集的结果与尖锐界面模型进行比较,探讨了我们提出的模型中采用的扩散界面方法所产生的内在误差。最后,我们考虑了两个案例研究,以展示该模型的潜在应用。首先,研究了纳米晶钇稳定氧化锆固体氧化物燃料电池系统,从模拟结果中提取了有效扩散系数,并与通过平均场近似获得的值进行了比较。其次,模拟了多晶电池阴极粒子锂化过程中的浓度演变,以证明该方法的能力。
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Simulating hindered grain boundary diffusion using the smoothed boundary method
Grain boundaries can greatly affect the transport properties of polycrystalline materials, particularly when the grain size approaches the nanoscale. While grain boundaries often enhance diffusion by providing a fast pathway for chemical transport, some material systems, such as those of solid oxide fuel cells and battery cathode particles, exhibit the opposite behavior, where grain boundaries act to hinder diffusion. To facilitate the study of systems with hindered grain boundary diffusion, we propose a model that utilizes the Smoothed Boundary Method (SBM) to simulate the dynamic concentration evolution in polycrystalline systems. The model employs domain parameters with diffuse interfaces to describe the grains, thereby enabling solutions with explicit consideration of their complex geometries. The intrinsic error arising from the diffuse interface approach employed in our proposed model is explored by comparing the results against a sharp interface model for a variety of parameter sets. Finally, two case studies are considered to demonstrate potential applications of the model. First, a nanocrystalline yttria-stabilized zirconia solid oxide fuel cell system is investigated, and the effective diffusivities are extracted from the simulation results and are compared to the values obtained through mean-field approximations. Second, the concentration evolution during lithiation of a polycrystalline battery cathode particle is simulated to demonstrate the method’s capability.
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