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引用次数: 0
摘要
机器学习(ML)用于建立包括冰过程在内的体微观物理参数化。拉格朗日超粒子模型 McSnow 的模拟结果被用作训练数据。ML 对粒子分辨微观物理进行粗粒化处理,并将其转换为多类两时刻体方程。除质量和数量外,基于 ML 的体积模型还能预测颗粒的预报属性 (P3),如熔融水、熔屑质量和熔屑体积。基于 ML 的方案通过复杂程度不断增加的模拟进行了测试。作为一个箱体模型,基于 ML 的体模型方案可以相当准确地再现 McSnow 的模拟结果。在 3d 理想化斜线模拟中,与 ICON 中的标准两时刻体型方案相比,基于 ML 的类 P3 方案提供了更真实的扩展层状区域。在实际案例研究中,基于 ML 的方案运行稳定,但不能显著改善结果。这表明 ML 可用来将超粒子模拟粗粒度化为任意复杂度的体方案。
An ML-Based P3-Like Multimodal Two-Moment Ice Microphysics in the ICON Model
Machine learning (ML) is used to build a bulk microphysical parameterization including ice processes. Simulations of the Lagrangian super-particle model McSnow are used as training data. The ML performs a coarse-graining of the particle-resolved microphysics to multi-category two-moment bulk equations. Besides mass and number, prognostic particle properties (P3) like melt water, rime mass, and rime volume are predicted by the ML-based bulk model. The ML-based scheme is tested with simulations of increasing complexity. As a box model, the ML-based bulk scheme can reproduce the simulations of McSnow quite accurately. In 3d idealized squall line simulations, the ML-based P3-like scheme provides a more realistic extended stratiform region when compared to the standard two-moment bulk scheme in ICON. In a realistic case study, the ML-based scheme runs stably, but can not significantly improve the results. This shows that ML can be used to coarse-grain super-particle simulations to a bulk scheme of arbitrary complexity.
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