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Main Authors: Dash, Soumyaranjan, DeRosa, Marc L., Dikpati, Mausumi, Sun, Xudong, Mahajan, Sushant S., Liu, Yang, Hoeksema, J. Todd
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.15233
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author Dash, Soumyaranjan
DeRosa, Marc L.
Dikpati, Mausumi
Sun, Xudong
Mahajan, Sushant S.
Liu, Yang
Hoeksema, J. Todd
author_facet Dash, Soumyaranjan
DeRosa, Marc L.
Dikpati, Mausumi
Sun, Xudong
Mahajan, Sushant S.
Liu, Yang
Hoeksema, J. Todd
contents Knowledge of the global magnetic field distribution and its evolution on the Sun's surface is crucial for modeling the coronal magnetic field, understanding solar wind dynamics, computing the heliospheric open flux distribution and predicting solar cycle strength. As the far side of the Sun cannot be observed directly and high-latitude observations always suffer from projection effects, we often rely on surface flux transport simulations (SFT) to model long-term global magnetic field distribution. Meridional circulation, the large-scale north-south component of the surface flow profile, is one of the key components of the SFT simulation that requires further constraints near high latitudes. Prediction of the photospheric magnetic field distribution requires knowledge of the flow profile in the future, which demands reconstruction of that same flow at the current time so that it can be estimated at a later time. By performing Observing System Simulation Experiments, we demonstrate how the Ensemble Kalman Filter technique, when used with a SFT model, can be utilized to make ``posterior'' estimates of flow profiles into the future that can be used to drive the model forward to forecast photospheric magnetic field distribution.
format Preprint
id arxiv_https___arxiv_org_abs_2409_15233
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Ensemble Kalman Filter Data Assimilation Into Surface Flux Transport Model To Infer Surface Flows: An Observing System Simulation Experiment
Dash, Soumyaranjan
DeRosa, Marc L.
Dikpati, Mausumi
Sun, Xudong
Mahajan, Sushant S.
Liu, Yang
Hoeksema, J. Todd
Solar and Stellar Astrophysics
Space Physics
Knowledge of the global magnetic field distribution and its evolution on the Sun's surface is crucial for modeling the coronal magnetic field, understanding solar wind dynamics, computing the heliospheric open flux distribution and predicting solar cycle strength. As the far side of the Sun cannot be observed directly and high-latitude observations always suffer from projection effects, we often rely on surface flux transport simulations (SFT) to model long-term global magnetic field distribution. Meridional circulation, the large-scale north-south component of the surface flow profile, is one of the key components of the SFT simulation that requires further constraints near high latitudes. Prediction of the photospheric magnetic field distribution requires knowledge of the flow profile in the future, which demands reconstruction of that same flow at the current time so that it can be estimated at a later time. By performing Observing System Simulation Experiments, we demonstrate how the Ensemble Kalman Filter technique, when used with a SFT model, can be utilized to make ``posterior'' estimates of flow profiles into the future that can be used to drive the model forward to forecast photospheric magnetic field distribution.
title Ensemble Kalman Filter Data Assimilation Into Surface Flux Transport Model To Infer Surface Flows: An Observing System Simulation Experiment
topic Solar and Stellar Astrophysics
Space Physics
url https://arxiv.org/abs/2409.15233