Publication: Domains of Magnetic Pressure Balance in Parker Solar Probe Observations of the Solar Wind
Issued Date
2021-12-20
Resource Type
ISSN
15384357
0004637X
0004637X
Other identifier(s)
2-s2.0-85122900497
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Mahidol University
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SCOPUS
Bibliographic Citation
Astrophysical Journal. Vol.923, No.2 (2021)
Suggested Citation
David Ruffolo, Nawin Ngampoopun, Yash R. Bhora, Panisara Thepthong, Peera Pongkitiwanichakul, William H. Matthaeus, Rohit Chhiber Domains of Magnetic Pressure Balance in Parker Solar Probe Observations of the Solar Wind. Astrophysical Journal. Vol.923, No.2 (2021). doi:10.3847/1538-4357/ac2ee3 Retrieved from: https://repository.li.mahidol.ac.th/handle/20.500.14594/76838
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Title
Domains of Magnetic Pressure Balance in Parker Solar Probe Observations of the Solar Wind
Abstract
The Parker Solar Probe (PSP) spacecraft is performing the first in situ exploration of the solar wind within 0.2 au of the Sun. Initial observations confirmed the Alfvénic nature of aligned fluctuations of the magnetic field B and velocity V in solar wind plasma close to the Sun, in domains of nearly constant magnetic field magnitude ∣ B ∣, i.e., approximate magnetic pressure balance. Such domains are interrupted by particularly strong fluctuations, including but not limited to radial field (polarity) reversals, known as switchbacks. It has been proposed that nonlinear Kelvin–Helmholtz instabilities form near magnetic boundaries in the nascent solar wind leading to extensive shear-driven dynamics, strong turbulent fluctuations including switchbacks, and mixing layers that involve domains of approximate magnetic pressure balance. In this work we identify and analyze various aspects of such domains using data from the first five PSP solar encounters. The filling fraction of domains, a measure of Alfvénicity, varies from median values of 90% within 0.2 au to 38% outside 0.9 au, with strong fluctuations. We find an inverse association between the mean domain duration and plasma β. We examine whether the mean domain duration is also related to the crossing time of spatial structures frozen into the solar wind flow for extreme cases of the aspect ratio. Our results are inconsistent with long, thin domains aligned along the radial or Parker spiral direction, and compatible with isotropic domains, which is consistent with prior observations of isotropic density fluctuations or flocculae in the solar wind.