In situ measurement of slow solar wind emerging from a pseudostreamer: a conjunction study with Parker Solar Probe and Solar Orbiter

We seek to identify the source regions of the slow solar wind (SSW) through combining models with in situ observations. We leverage an opportune conjunction between Solar Orbiter and Parker Solar Probe (PSP) during PSP Encounter 11 to include compositional diagnostics from the Solar Orbiter heavy ion sensor (HIS) as these variations provide crucial insights into the origin and nature of the solar wind. We use Potential Field Source Surface (PFSS) and Magnetohydrodynamic (MHD) models to connect the observed plasma at PSP and Solar Orbiter to its origin footpoint in the photosphere, and compare these results with the in situ measurements. A very clear signature of a heliospheric current sheet (HCS) crossing as evidenced by enhancements in low FIP elements, ion charge state ratios, proton density, low-Alfvenicity, and polarity estimates validates the combination of modeling, data, and mapping. Fast wind from a small equatorial coronal hole (CH) with low ion charge state ratios, low FIP bias, high-Alfvenicity, and low footpoint brightness mostly fits together, yet includes anomalously low alpha particle abundance. We identify slow wind from many different sources, with broad variation in composition and Alfvenicity. We distinguish between classical non-Alfvenic and high-Alfvenicity SSW and make the association of low-Alfvenicity, decreased alpha-to-proton abundance, high charge state ratios, and FIP bias with streamer wind while intermediate alpha abundance, high-Alfvenicity, and dips in ion charge state ratios correspond to CH boundaries. Through this comprehensive analysis, we highlight the power of multi-instrument conjunction studies in assessing the sources of the solar wind.