369 research outputs found
Statistical analysis of orientation, shape, and size of solar wind switchbacks
One of the main discoveries from the first two orbits of Parker Solar Probe (PSP) was the presence of magnetic switchbacks, whose deflections dominated the magnetic field measurements. Determining their shape and size could provide evidence of their origin, which is still unclear. Previous work with a single solar wind stream has indicated that these are long, thin structures although the direction of their major axis could not be determined. We investigate if this long, thin nature extends to other solar wind streams, while determining the direction along which the switchbacks within a stream were aligned. We try to understand how the size and orientation of the switchbacks, along with the flow velocity and spacecraft trajectory, combine to produce the observed structure durations for past and future orbits. We searched for the alignment direction that produced a combination of a spacecraft cutting direction and switchback duration that was most consistent with long, thin structures. The expected form of a long, thin structure was fitted to the results of the best alignment direction, which determined the width and aspect ratio of the switchbacks for that stream. The switchbacks had a mean width of , with an aspect ratio of the order of . We find that switchbacks are not aligned along the background flow direction, but instead aligned along the local Parker spiral, perhaps suggesting that they propagate along the magnetic field. Since the observed switchback duration depends on how the spacecraft cuts through the structure, the duration alone cannot be used to determine the size or influence of an individual event. For future PSP orbits, a larger spacecraft transverse component combined with more radially aligned switchbacks will lead to long duration switchbacks becoming less common
Structure on Interplanetary Shock Fronts: Type II Radio Burst Source Regions
We present \emph{in situ} observations of the source regions of
interplanetary (IP) type II radio bursts, using data from the Wind spacecraft
during the period 1996-2002. We show the results of this survey as well as
in-depth analysis of several individual events. Each event analyzed in detail
is associated with an interplanetary coronal mass ejection (ICME) and an IP
shock driven by the ICME. Immediately prior to the arrival of each shock,
electron beams along the interplanetary magnetic field (IMF) and associated
Langmuir waves are detected, implying magnetic connection to a
quasiperpendicular shock front acceleration site. These observations are
analogous to those made in the terrestrial foreshock region, indicating that a
similar foreshock region exists on IP shock fronts. The analogy suggests that
the electron acceleration process is a fast Fermi process, and this suggestion
is borne out by loss cone features in the electron distribution functions. The
presence of a foreshock region requires nonplanar structure on the shock front.
Using Wind burst mode data, the foreshock electrons are analyzed to estimate
the dimensions of the curved region. We present the first measurement of the
lateral, shock-parallel scale size of IP foreshock regions. The presence of
these regions on IP shock fronts can explain the fine structure often seen in
the spectra of type II bursts.Comment: 19 pages, 5 figures. To be published in The Astrophysical Journa
Total Electron Temperature Derived from Quasi-Thermal Noise Spectroscopy In the Pristine Solar Wind: Parker Solar Probe Observations
The Quasi-thermal noise (QTN) technique is a reliable tool to yield accurate
measurements of the electron parameters in the solar wind. We apply this method
on Parker Solar Probe (PSP) observations to derive the total electron
temperature () from the linear fit of the high-frequency part of the QTN
spectra acquired by the RFS/FIELDS instrument, and present a combination of
12-day period of observations around each perihelion from Encounter One (E01)
to Ten (E10) (with E08 not included) with the heliocentric distance varying
from about 13 to 60 solar radii (). We find that the total electron
temperature decreases with the distance as , which is much
slower than adiabatic. The extrapolated based on PSP observations is
consistent with the exospheric solar wind model prediction at 10
, Helios observations at 0.3 AU and Wind observations at 1 AU.
Also, , extrapolated back to 10 , is almost the same as the
strahl electron temperature (measured by SPAN-E) which is considered to
be closely related to or even almost equal to the coronal electron temperature.
Furthermore, the radial profiles in the slower solar wind (or flux tube
with larger mass flux) are steeper than those in the faster solar wind (or flux
tube with smaller mass flux). More pronounced anticorrelated - is
observed when the solar wind is slower and closer to the Sun.Comment: 10 pages, 7 figures, and Astronomy & Astrophysics Accepte
The active region source of a type III radio storm observed by Parker Solar Probe during Encounter 2
Context. To investigate the source of a type III radio burst storm during
encounter 2 of NASA's Parker Solar Probe (PSP) mission.
Aims. It was observed that in encounter 2 of NASA's Parker Solar Probe
mission there was a large amount of radio activity, and in particular a noise
storm of frequent, small type III bursts from 31st March to 6th April 2019. Our
aim is to investigate the source of these small and frequent bursts.
Methods. In order to do this, we analysed data from the Hinode EUV Imaging
Spectrometer (EIS), PSP FIELDS, and the Solar Dynamics Observatory (SDO)
Atmospheric Imaging Assembly (AIA). We studied the behaviour of active region
12737, whose emergence and evolution coincides with the timing of the radio
noise storm and determined the possible origins of the electron beams within
the active region. To do this, we probe the dynamics, Doppler velocity,
non-thermal velocity, FIP bias, densities, and carry out magnetic modelling.
Results. We demonstrate that although the active region on the disk produces
no significant flares, its evolution indicates it is a source of the electron
beams causing the radio storm. They most likely originate from the area at the
edge of the active region that shows strong blue-shifted plasma. We demonstrate
that as the active region grows and expands, the area of the blue-shifted
region at the edge increases, which is also consistent with the increasing area
where large-scale or expanding magnetic field lines from our modelling are
anchored. This expansion is most significant between 1 and 4 April 2019,
coinciding with the onset of the type III storm and the decrease of the
individual burst's peak frequency, indicating the height at which the peak
radiation is emitted increases as the active region evolves
Observations of Energetic-particle Population Enhancements along Intermittent Structures near the Sun from the Parker Solar Probe
Observations at 1 au have confirmed that enhancements in measured energetic-particle (EP) fluxes are statistically associated with "rough" magnetic fields, i.e., fields with atypically large spatial derivatives or increments, as measured by the Partial Variance of Increments (PVI) method. One way to interpret this observation is as an association of the EPs with trapping or channeling within magnetic flux tubes, possibly near their boundaries. However, it remains unclear whether this association is a transport or local effect; i.e., the particles might have been energized at a distant location, perhaps by shocks or reconnection, or they might experience local energization or re-acceleration. The Parker Solar Probe (PSP), even in its first two orbits, offers a unique opportunity to study this statistical correlation closer to the corona. As a first step, we analyze the separate correlation properties of the EPs measured by the Integrated Science Investigation of the Sun (ISâIS) instruments during the first solar encounter. The distribution of time intervals between a specific type of event, i.e., the waiting time, can indicate the nature of the underlying process. We find that the ISâIS observations show a power-law distribution of waiting times, indicating a correlated (non-Poisson) distribution. Analysis of low-energy (~15 â 200 keV/nuc) ISâIS data suggests that the results are consistent with the 1 au studies, although we find hints of some unexpected behavior. A more complete understanding of these statistical distributions will provide valuable insights into the origin and propagation of solar EPs, a picture that should become clear with future PSP orbits
Observations of the 2019 April 4 Solar Energetic Particle Event at the Parker Solar Probe
A solar energetic particle event was detected by the Integrated Science Investigation of the Sun (ISâIS) instrument suite on Parker Solar Probe (PSP) on 2019 April 4 when the spacecraft was inside of 0.17 au and less than 1 day before its second perihelion, providing an opportunity to study solar particle acceleration and transport unprecedentedly close to the source. The event was very small, with peak 1 MeV proton intensities of ~0.3 particles (cmÂČ sr s MeV)â»Âč, and was undetectable above background levels at energies above 10 MeV or in particle detectors at 1 au. It was strongly anisotropic, with intensities flowing outward from the Sun up to 30 times greater than those flowing inward persisting throughout the event. Temporal association between particle increases and small brightness surges in the extreme-ultraviolet observed by the Solar TErrestrial RElations Observatory, which were also accompanied by type III radio emission seen by the Electromagnetic Fields Investigation on PSP, indicates that the source of this event was an active region nearly 80° east of the nominal PSP magnetic footpoint. This suggests that the field lines expanded over a wide longitudinal range between the active region in the photosphere and the corona
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Solar Energetic Particles Produced by a Slow Coronal Mass Ejection at âŒ0.25 au
We present an analysis of Parker Solar Probe (PSP) ISâIS observations of ~30â300 keV nâ»Âč ions on 2018 November 11 when PSP was about 0.25 au from the Sun. Five hours before the onset of a solar energetic particle (SEP) event, a coronal mass ejection (CME) was observed by STEREO-A/COR2, which crossed PSP about a day later. No shock was observed locally at PSP, but the CME may have driven a weak shock earlier. The SEP event was dispersive, with higher energy ions arriving before the lower energy ones. Timing suggests the particles originated at the CME when it was at ~7.4R_â. SEP intensities increased gradually from their onset over a few hours, reaching a peak, and then decreased gradually before the CME arrived at PSP. The event was weak, having a very soft energy spectrum (â4 to â5 spectral index). The earliest arriving particles were anisotropic, moving outward from the Sun, but later, the distribution was observed to be more isotropic. We present numerical solutions of the Parker transport equation for the transport of 30â300 keV nâ»Âč ions assuming a source comoving with the CME. Our model agrees well with the observations. The SEP event is consistent with ion acceleration at a weak shock driven briefly by the CME close to the Sun, which later dissipated before arriving at PSP, followed by the transport of ions in the interplanetary magnetic field
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