Realizing higher operating temperatures to increase efficiency of future applications for energy conversion and storage while minimizing cost is a challenge for development of high-temperature materials. Simultaneous optimization of mechanical properties and corrosion resistance continues to be a difficult task but is essential due to the need to significantly accelerate the transition between technology readiness levels in the future. Oxidation-induced degradation will be a critical life-limiting mechanism at increased operating temperatures. Suitable high-temperature materials cannot be solely identified by time-consuming experiments and reliable computational methods incorporating the relevant physics of processes must be considered to complement the experimental efforts. In the present work, a review of the methods employed to model oxidation-induced material degradation described in literature will be discussed. Furthermore, their capability to predict lifetime and aid in material selection will be evaluated.

实现更高的工作温度以提高未来能源转换和存储应用的效率，同时将成本降至最低，这是开发高温材料所面临的挑战。机械性能和耐腐蚀性的同时优化仍然是一项艰巨的任务，但由于将来需要显着加快技术准备水平之间的过渡，因此至关重要。在升高的工作温度下，氧化诱导的降解将是关键的寿命限制机制。不能通过耗时的实验来单独确定合适的高温材料，必须考虑结合过程相关物理原理的可靠计算方法来补充实验工作。在目前的工作中，将讨论文献中描述的用于模拟氧化引起的材料降解的方法的综述。此外，将评估其预测寿命和辅助材料选择的能力。