Bootstrapping the Coronal Magnetic Field with STEREO: I. Unipolar Potential Field Modeling

Abstract

We investigate the recently quantified misalignment of αmis ≈ 20-40 between the 3-D geometry of stereoscopically triangulated coronal loops observed with STEREO/EUVI (in four active regions) and theoretical (potential or nonlinear force-free) magnetic field models extrapolated from photospheric magnetograms. We develop an efficient method of bootstrapping the coronal magnetic field by forward-fitting a parameterized potential field model to the STEREO-observed loops. The potential field model consists of a number of unipolar magnetic charges that are parameterized by decomposing a photospheric magnetogram from MDI. The forward-fitting method yields a best-fit magnetic field model with a reduced misalignment of αPF ≈ 13-20. We evaluate also stereoscopic measurement errors and find a contribution of αSE≈ 7-12, which constrains the residual misalignment to αNP=αPF-αSE≈ 5 -9, which is likely due to the nonpotentiality of the active regions. The residual misalignment angle αNP of the potential field due to nonpotentiality is found to correlate with the soft X-ray flux of the active region, which implies a relationship between electric currents and plasma heating.