Abstract
We use Solar Dynamics Observatory (SDO)/Atmospheric Imaging Assembly (AIA) data to reconstruct the plasma properties from differential emission measure (DEM) analysis for a previously studied long-lived, low-latitude coronal hole (CH) over its lifetime of ten solar rotations. We initially obtain a non-isothermal DEM distribution with a dominant component centered around 0.9 MK and a secondary smaller component at 1.5 – 2.0 MK. We find that deconvolving the data with the instrument point spread function (PSF) to account for long-range scattered light reduces the secondary hot component. Using the 2012 Venus transit and a 2013 lunar eclipse to test the efficiency of this deconvolution, significant amounts of residual stray light are found for the occulted areas. Accounting for this stray light in the error budget of the different AIA filters further reduces the secondary hot emission, yielding CH DEM distributions that are close to isothermal with the main contribution centered around 0.9 MK. Based on these DEMs, we analyze the evolution of the emission measure (EM), density, and averaged temperature during the CH’s lifetime. We find that once the CH is clearly observed in EUV images, the bulk of the CH plasma reveals a quite constant state, i.e. temperature and density reveal no major changes, whereas the total CH area and the photospheric magnetic fine structure inside the CH show a distinct evolutionary pattern. These findings suggest that CH plasma properties are mostly “set” at the CH formation or/and that all CHs have similar plasma properties.
Highlights
Coronal holes are regions of reduced plasma density and temperature in the solar corona
Over the ten solar rotations of the coronal hole (CH)’s lifetime, we derived the differential emission measure (DEM) of each 8 × 8 binned pixel of the Atmospheric Imaging Assembly (AIA) images, when the CH was close to the central meridian
The finding that coronal plasma outside CHs shows emission from a component centered around CH temperatures is consistent with the reasoning of Landi and Feldman (2008), who concluded that coronal plasma may be a superposition of CH, quiet Sun (QS), and active-region plasma, with CHs missing the hotter components
Summary
A larger fraction of the overall magnetic flux is concentrated in magnetic elements than in the growing and decaying phases, and the number of magnetic elements per area for elements with field strengths > 50 G increases nearly 100% compared to either the beginning or end of the CH’s life. This maximum phase further exhibits the strongest correlation between CH area and peak speed of the associated high-speed solar-wind stream. In this article we apply DEM diagnostics using the inversion code developed by Hannah and Kontar (2012) using SDO/Atmospheric Imaging Assembly (AIA) data to reconstruct the DEM distribution of a CH and infer the density and temperature evolution over its lifetime
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