平流层气溶胶源反演：噪声、可变性和不确定性量化

arXiv - STAT - Applications Pub Date : 2024-09-10 DOI:arxiv-2409.06846

J. Hart, I. Manickam, M. Gulian, L. Swiler, D. Bull, T. Ehrmann, H. Brown, B. Wagman, J. Watkins

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引用次数: 0

摘要

平流层气溶胶在地球系统中发挥着重要作用，可在数月至数年的时间尺度上影响气候。然而，估计部分观测到的气溶胶注入（如火山爆发产生的气溶胶）的特征充满了不确定性。本文提出了一个平流层气溶胶源反演框架，该框架通过贝叶斯近似误差方法考虑了气溶胶背景噪声和地球系统内部变异性。我们利用专门设计的地球系统模型，使用能源超大规模地球系统模型（ESM）进行模拟。我们提出了一个用于数据生成、数据处理、降维、算子学习和贝叶斯反演的综合框架，该框架的每个组成部分都是为应对全球尺度大气建模的特殊挑战而设计的。我们介绍了使用合成观测数据的数值结果，以严格评估我们的方法估计气溶胶源的能力以及与这些估计相关的不确定性。

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Stratospheric aerosol source inversion: Noise, variability, and uncertainty quantification

Stratospheric aerosols play an important role in the earth system and can affect the climate on timescales of months to years. However, estimating the characteristics of partially observed aerosol injections, such as those from volcanic eruptions, is fraught with uncertainties. This article presents a framework for stratospheric aerosol source inversion which accounts for background aerosol noise and earth system internal variability via a Bayesian approximation error approach. We leverage specially designed earth system model simulations using the Energy Exascale Earth System Model (E3SM). A comprehensive framework for data generation, data processing, dimension reduction, operator learning, and Bayesian inversion is presented where each component of the framework is designed to address particular challenges in stratospheric modeling on the global scale. We present numerical results using synthesized observational data to rigorously assess the ability of our approach to estimate aerosol sources and associate uncertainty with those estimates.

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arXiv - STAT - Applications

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