English

Estimating Electric Fields from Vector Magnetogram Sequences

Solar and Stellar Astrophysics 2014-11-20 v4

Abstract

Determining the electric field (E-field) distribution on the Sun's photosphere is essential for quantitative studies of how energy flows from the Sun's photosphere, through the corona, and into the heliosphere. This E-field also provides valuable input for data-driven models of the solar atmosphere and the Sun-Earth system. We show how Faraday's Law can be used with observed vector magnetogram time series to estimate the photospheric E-field, an ill-posed inversion problem. Our method uses a "poloidal-toroidal decomposition" (PTD) of the time derivative of the vector magnetic field. The PTD solutions are not unique; the gradient of a scalar potential can be added to the PTD E-field without affecting consistency with Faraday's Law. We present an iterative technique to determine a potential function consistent with ideal MHD evolution; but this E-field is also not a unique solution to Faraday's Law. Finally, we explore a variational approach that minimizes an energy functional to determine a unique E-field, similar to Longcope's "Minimum Energy Fit". The PTD technique, the iterative technique, and the variational technique are used to estimate E-fields from a pair of synthetic vector magnetograms taken from an MHD simulation; and these E-fields are compared with the simulation's known electric fields. These three techniques are then applied to a pair of vector magnetograms of solar active region NOAA AR8210, to demonstrate the methods with real data.

Keywords

Cite

@article{arxiv.0912.4916,
  title  = {Estimating Electric Fields from Vector Magnetogram Sequences},
  author = {G. H. Fisher and B. T. Welsch and W. P. Abbett and D. J. Bercik},
  journal= {arXiv preprint arXiv:0912.4916},
  year   = {2014}
}

Comments

41 pages, 10 figures

R2 v1 2026-06-21T14:28:19.231Z