Global Sensitivity Analysis and Uncertainty Quantification for Background Solar Wind Using the Alfvén Wave Solar Atmosphere Model

Author:

Jivani Aniket1ORCID,Sachdeva Nishtha2ORCID,Huang Zhenguang2,Chen Yang3ORCID,van der Holst Bart2,Manchester Ward2,Iong Daniel3ORCID,Chen Hongfan1,Zou Shasha2ORCID,Huan Xun1ORCID,Toth Gabor2ORCID

Affiliation:

1. Department of Mechanical Engineering University of Michigan Ann Arbor MI USA

2. Department of Climate and Space Sciences and Engineering University of Michigan Ann Arbor MI USA

3. Department of Statistics University of Michigan Ann Arbor MI USA

Abstract

AbstractModeling the impact of space weather events such as coronal mass ejections (CMEs) is crucial to protecting critical infrastructure. The Space Weather Modeling Framework is a state‐of‐the‐art framework that offers full Sun‐to‐Earth simulations by computing the background solar wind, CME propagation, and magnetospheric impact. However, reliable long‐term predictions of CME events require uncertainty quantification (UQ) and data assimilation. We take the first steps by performing global sensitivity analysis (GSA) and UQ for background solar wind simulations produced by the Alfvén Wave Solar atmosphere Model (AWSoM) for two Carrington rotations: CR2152 (solar maximum) and CR2208 (solar minimum). We conduct GSA by computing Sobol' indices that quantify contributions from model parameter uncertainty to the variance of solar wind speed and density at 1 au, both crucial quantities for CME propagation and strength. Sobol' indices also allow us to rank and retain only the most important parameters, which aids in the construction of smaller ensembles for the reduced‐dimension parameter space. We present an efficient procedure for computing the Sobol' indices using polynomial chaos expansion surrogates and space‐filling designs. The PCEs further enable inexpensive forward UQ. Overall, we identify three important model parameters: the multiplicative factor applied to the magnetogram, Poynting flux per magnetic field strength constant used at the inner boundary, and the coefficient of the perpendicular correlation length in the turbulent cascade model in AWSoM.

Funder

National Science Foundation

Publisher

American Geophysical Union (AGU)

Subject

Atmospheric Science

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