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Autores principales: Collard, Jack D., Ervin, Tamar, Dewey, Ryan M., Rivera, Yeimy J., Nakhleh, Aidan J., Dakeyo, Jean-Baptiste, Badman, Samuel T., Bowen, Trevor A., Bonnell, John W., Viall, Nicholeen M., Lepri, Susan T., Raines, Jim M., Bale, Stuart D.
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2511.14938
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author Collard, Jack D.
Ervin, Tamar
Dewey, Ryan M.
Rivera, Yeimy J.
Nakhleh, Aidan J.
Dakeyo, Jean-Baptiste
Badman, Samuel T.
Bowen, Trevor A.
Bonnell, John W.
Viall, Nicholeen M.
Lepri, Susan T.
Raines, Jim M.
Bale, Stuart D.
author_facet Collard, Jack D.
Ervin, Tamar
Dewey, Ryan M.
Rivera, Yeimy J.
Nakhleh, Aidan J.
Dakeyo, Jean-Baptiste
Badman, Samuel T.
Bowen, Trevor A.
Bonnell, John W.
Viall, Nicholeen M.
Lepri, Susan T.
Raines, Jim M.
Bale, Stuart D.
contents While the fast solar wind has well-established origins in coronal holes, the source of the slow solar wind remains uncertain. Compositional metrics, such as heavy ion charge state ratios are set in the lower corona, providing insights into solar wind source regions. However, prior to the launch of Solar Orbiter, in situ measurements of heavy ion charge state were limited to distances of 1 AU and beyond. We investigate proton specific entropy as a proxy for the oxygen charge state ratio ($O^{7+}/O^{6+}$),which generally becomes frozen-in below ~1.8 Rsun, leveraging observations from Solar Orbiter's Heavy Ion Sensor and Proton and Alphas Sensor covering 0.28 to 1 AU. Our analysis confirms a strong anti-correlation between specific entropy and the oxygen charge state ratio that persists over a broad range of distances in the inner heliosphere. We categorize observed solar wind into fast solar wind, slow Alfvenic solar wind, and slow solar wind, identifying clear distinctions in specific entropy values and charge state ratios across these types. The work demonstrates the potential to use proton specific entropy as a classifier of solar wind source regions throughout the heliosphere. By establishing the $S_p$-$O^{7+}/O^{6+}$ relationship and quantifying its radial dependence, the specific entropy can be used as a quantity to identify the solar wind source region in the absence of in-situ charge state measurements. This motivates future studies as to the applicability of this proxy to near-Sun observations (such as Parker Solar Probe) and throughout the inner heliosphere.
format Preprint
id arxiv_https___arxiv_org_abs_2511_14938
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Proton specific entropy as a proxy for the $O^{7+}/O^{6+}$ charge state ratio over heliocentric distance
Collard, Jack D.
Ervin, Tamar
Dewey, Ryan M.
Rivera, Yeimy J.
Nakhleh, Aidan J.
Dakeyo, Jean-Baptiste
Badman, Samuel T.
Bowen, Trevor A.
Bonnell, John W.
Viall, Nicholeen M.
Lepri, Susan T.
Raines, Jim M.
Bale, Stuart D.
Solar and Stellar Astrophysics
Plasma Physics
Space Physics
While the fast solar wind has well-established origins in coronal holes, the source of the slow solar wind remains uncertain. Compositional metrics, such as heavy ion charge state ratios are set in the lower corona, providing insights into solar wind source regions. However, prior to the launch of Solar Orbiter, in situ measurements of heavy ion charge state were limited to distances of 1 AU and beyond. We investigate proton specific entropy as a proxy for the oxygen charge state ratio ($O^{7+}/O^{6+}$),which generally becomes frozen-in below ~1.8 Rsun, leveraging observations from Solar Orbiter's Heavy Ion Sensor and Proton and Alphas Sensor covering 0.28 to 1 AU. Our analysis confirms a strong anti-correlation between specific entropy and the oxygen charge state ratio that persists over a broad range of distances in the inner heliosphere. We categorize observed solar wind into fast solar wind, slow Alfvenic solar wind, and slow solar wind, identifying clear distinctions in specific entropy values and charge state ratios across these types. The work demonstrates the potential to use proton specific entropy as a classifier of solar wind source regions throughout the heliosphere. By establishing the $S_p$-$O^{7+}/O^{6+}$ relationship and quantifying its radial dependence, the specific entropy can be used as a quantity to identify the solar wind source region in the absence of in-situ charge state measurements. This motivates future studies as to the applicability of this proxy to near-Sun observations (such as Parker Solar Probe) and throughout the inner heliosphere.
title Proton specific entropy as a proxy for the $O^{7+}/O^{6+}$ charge state ratio over heliocentric distance
topic Solar and Stellar Astrophysics
Plasma Physics
Space Physics
url https://arxiv.org/abs/2511.14938