The infant bow shock: a new frontier at a weak activity comet

The bow shock is the first boundary the solar wind encounters as it approaches planets or comets. The Rosetta spacecraft was able to observe the formation of a bow shock by following comet 67P/Churyumov–Gerasimenko toward the Sun, through perihelion, and back outward again. The spacecraft crossed the newly formed bow shock several times during two periods a few months before and after perihelion; it observed an increase in magnetic field magnitude and oscillation amplitude, electron and proton heating at the shock, and the diminution of the solar wind further downstream. Rosetta observed a cometary bow shock in its infancy, a stage in its development not previously accessible to in situ measurements at comets and planets.

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The Global Interaction of Comets with the Solar Wind

International Astronomical Union Colloquium ◽

10.1017/s0252921100012859 ◽

1991 ◽

Vol 116 (2) ◽

pp. 1125-1144 ◽

Cited By ~ 6

Author(s):

K. R. Flammer

Keyword(s):

Solar Wind ◽

Heliocentric Distance ◽

Theoretical Models ◽

Bow Shock ◽

Flow Transition ◽

The Sun ◽

In Situ Observations ◽

Comet Halley

AbstractThe global interaction of the solar wind with a comet as it orbits the Sun is reviewed. After a brief survey of the flow transition regions observed at comet Halley is presented, theoretical models are given for the cometocentric distance of the bow shock, the cometopause, and the ionopause. In addition, predictions are made as to what heliocentric distance these boundaries should form at. The results of these models are compared with the in situ observations at comet Halley.

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Plasma processes at comet Churyumov–Gerasimenko: Expectations for Rosetta

Journal of Plasma Physics ◽

10.1017/s0022377813001116 ◽

2013 ◽

Vol 79 (6) ◽

pp. 1067-1070 ◽

Cited By ~ 1

Author(s):

D. A. MENDIS ◽

M. HORÁNYI

Keyword(s):

Solar Wind ◽

Solar Radiation ◽

Bow Shock ◽

Short Paper ◽

Wind Flow ◽

The Sun ◽

Cometary Plasma ◽

Variable Nature ◽

Solar Wind Flow ◽

Comet 67P

AbstractThe Rosetta–Philae mission to comet 67P/Churyumov–Gerasimenko in 2014 will provide a unique opportunity to observe the variable nature of the interaction of a comet with the solar radiation and the solar wind, as the comet approaches the Sun. In this short paper we will focus on the varying global structure of the cometary plasma environment. Specifically we make predictions on the varying locations of the two basic transitions in the global, contaminated solar wind flow toward the comet: the outer bow shock and the ionopause.

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Ion energy and momentum flux near the cometopause of Comet 67P/Churyumov-Gerasimenko

10.5194/egusphere-egu21-14280 ◽

2021 ◽

Author(s):

Hayley Williamson ◽

Hans Nilsson ◽

Anja Moslinger ◽

Sofia Bergman ◽

Gabriella Stenberg-Wieser

Keyword(s):

Solar Wind ◽

Complex Dynamics ◽

Distribution Functions ◽

Transitional Period ◽

Ion Energy ◽

Rosetta Mission ◽

Before And After ◽

Composition Analyzer ◽

Energy And Momentum ◽

Comet 67P

Defined as the region where the plasma interaction region of a comet goes from being solar wind-dominated to cometary ion-dominated, the cometopause is a region of comingling plasmas and complex dynamics. The Rosetta mission orbited comet 67P/Churyumov-Gerasimenko for roughly two years. During this time, the cometopause was observed by the Ion Composition Analyzer (ICA), part of the Rosetta Plasma Consortium (RPC), before and after the spacecraft was in the solar wind ion cavity, defined as the region where no solar wind ions were measured. Data from ICA shows that solar wind and cometary ions have similar momentum and energy flux moments during this transitional period, indicating mass loading and deflection of the solar wind. We examine higher order moments and distribution functions for the solar wind and cometary species between December 2015 and March 2016. The behavior of the solar wind protons indicates that in many cases these protons are deflected in a sunward direction, while the cometary ions continue to move predominately antisunward. By studying the distribution functions of the protons during these time periods, it is possible to see a non-Maxwellian energy distribution. This can inform on the nature of the cometopause boundary and the energy transfer mechanisms at play in this region.

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Large-scale electron solar wind parameters of the inner heliosphere with Parker Solar Probe/FIELDS

10.5194/egusphere-egu2020-18573 ◽

2020 ◽

Author(s):

Karine Issautier ◽

Mingzhe Liu ◽

Michel Moncuquet ◽

Nicole Meyer-Vernet ◽

Milan Maksimovic ◽

...

Keyword(s):

Solar Wind ◽

Large Scale ◽

Statistical Study ◽

Solar Wind Speed ◽

The Sun ◽

Solar Wind Parameters ◽

Power Law Index ◽

Probe Mission ◽

Inner Heliosphere

We present in situ properties of electron density and temperature in the inner heliosphere obtained during the three first solar encounters at 35 solar radii of the Parker Solar Probe mission. These preliminary results, recently shown by Moncuquet et al., ApJS, 2020, are obtained from the analysis of the plasma quasi-thermal noise (QTN) spectrum measured by the radio RFS/FIELDS instrument along the trajectories extending between 0.5 and 0.17 UA from the Sun, revealing different states of the emerging solar wind, five months apart. The temperature of the weakly collisional core population varies radially with a power law index of about -0.8, much slower than adiabatic, whereas the temperature of the supra-thermal population exhibits a much flatter radial variation, as expected from its nearly collisionless state. These measured temperatures are close to extrapolations towards the Sun of Helios measurements.We also present a statistical study from these in situ electron solar wind parameters, deduced by QTN spectroscopy, and compare the data to other onboard measurements. In addition, we focus on the large-scale solar wind properties. In particular, from the invariance of the energy flux, a direct relation between the solar wind speed and its density can be deduced, as we have already obtained based on Wind continuous in situ measurements (Le Chat et al., Solar Phys., 2012). We study this anti-correlation during the three first solar encounters of PSP.

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The RPW Low Frequency Receiver (LFR) on Solar Orbiter: in-situ LF electric and magnetic field measurements of the solar wind expansion

10.5194/egusphere-egu2020-10050 ◽

2020 ◽

Author(s):

Thomas Chust ◽

Olivier Le Contel ◽

Matthieu Berthomier ◽

Alessandro Retinò ◽

Fouad Sahraoui ◽

...

Keyword(s):

Solar Wind ◽

Low Frequency ◽

Field Measurements ◽

Solar Wind Plasma ◽

Wind Condition ◽

The Sun ◽

Nasa Mission ◽

Magnetic Field Measurements ◽

Electric And Magnetic Field

Solar Orbiter (SO) is an ESA/NASA mission for exploring the Sun-Heliosphere connection which has been launched in February 2020. The Low Frequency Receiver (LFR) is one of the main subsystems of the Radio and Plasma Wave (RPW) experiment on SO. It is designed for characterizing the low frequency (~0.1Hz&#8211;10kHz) electromagnetic fields & waves which develop, propagate, interact, and dissipate in the solar wind plasma. In correlation with particle observations it will help to understand the heating and acceleration processes at work during its expansion. We will present the first LFR data gathered during the Near Earth Commissioning Phase, and will compare them with MMS data recorded in similar solar wind condition.

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On the Bow-Shock dynamics in response to a Quasi-Perpendicular interaction with different Solar Wind conditions

10.5194/egusphere-egu21-10648 ◽

2021 ◽

Author(s):

Emanuele Cazzola ◽

Dominique Fontaine ◽

Philippe Savoini

Keyword(s):

Solar Wind ◽

Computer Simulations ◽

Cross Sections ◽

Ad Hoc ◽

Three Dimensional ◽

Bow Shock ◽

Hybrid Code ◽

Mach Numbers ◽

The Imf

This work will be giving new insights into the global Quasi-Perpendicular interaction effects of the Solar Wind with a realistic three-dimensional terrestrial-like curved Bow Shock (BS) by means of hybrid computer simulations. The Bow-Shock profoundly changes its behavior for different incoming Solar Wind conditions. For Alfv&#233;nic Mach numbers greater than a specific threshold, the Bow-Shock shows an intense rippling phenomenon propagating along its surface, as well as the formation of a set of waves in the near-Earth flanks. A similar rippling has been observed from different independent in-situ satellite crossings, as well as studied with ad-hoc computer simulations configured with 2D-planar shocks, conclusively confirming the highly kinetic nature of this phenomenon. Yet, the possible effects of a global three-dimensional curved interaction are still poorly described. As such, we have performed a series of 3D simulations at different Alfv&#233;nic Mach numbers, different plasma beta - ratio between the thermal to the magnetic pressures - and different incoming Interplanetary Magnetic Field (IMF) configurations with the hybrid code LatHyS, which was already successfully used for similar past analyses. Particularly, we have found that the ripples follow a pattern not directly driven by the IMF direction as initially expected, but rather a Nose-to-Flanks propagation with the rippling onset region &#160;being significantly displaced from the nose position. Additionally, this phenomenon seems to be mainly confined to the plane on where the IMF direction lies, with the perpendicular cross-sections showing only a slight oscillation. Finally, we have observes a significant ions acceleration in the local perpendicular directions along the flanks modulations, which is most likely related to the local IMF-BS normal fluctuations occurring in the ripples boundary.

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Understanding Solar Wind Formation by Identifying the Origins of In Situ Observations

10.5194/egusphere-egu21-6200 ◽

2021 ◽

Author(s):

Samantha Wallace ◽

Nicholeen M. Viall ◽

Charles N. Arge

Keyword(s):

Solar Wind ◽

Solar Wind Speed ◽

Source Region ◽

Heliospheric Current Sheet ◽

Slow Solar Wind ◽

The Sun ◽

Flux Transport ◽

Model Driven ◽

In Situ Observations

Solar wind formation can be separated into three physical steps &#8211; source, release, and acceleration &#8211; that each leave distinct observational signatures on plasma parcels.&#160; The Wang-Sheeley-Arge (WSA) model driven by Air Force Data Assimilative Photospheric Flux Transport (ADAPT) time-dependent photospheric field maps now has the ability to connect in situ observations more rigorously to their precise source at the Sun, allowing us to investigate the physical processes involved in solar wind formation. &#160;&#160;In this talk, I will highlight my PhD dissertation research in which we use the ADAPT-WSA model to either characterize the solar wind emerging from specific sources, or investigate the formation process of various solar wind populations. &#160;In the first study, we test the well-known inverse relationship between expansion factor (fs) and observed solar wind speed (vobs) for solar wind that emerges from a large sampling of pseudostreamers, to investigate if field line expansion plays a physical role in accelerating the solar wind from this source region.&#160; We find that there is no correlation between fs and vobs at pseudostreamer cusps. In the second study, we determine the source locations of the first identified quasiperiodic density structures (PDSs) inside 0.6 au. Our modeling provides confirmation of these events forming via magnetic reconnection both near to and far from the heliospheric current sheet (HCS) &#8211; a direct test of the Separatrix-web (S-web) theory of slow solar wind formation.&#160; In the final study, we use our methodology to identify the source regions of the first observations from the Parker Solar Probe (PSP) mission.&#160; Our modeling enabled us to characterize the closest to the Sun observed coronal mass ejection (CME) to date as a streamer blowout.&#160; We close with future ways that ADAPT-WSA can be used to test outstanding questions of solar wind formation.

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The SMILE mission: A novel way to explore solar-terrestrial interactions

10.5194/egusphere-egu2020-10783 ◽

2020 ◽

Author(s):

Graziella Branduardi-Raymont ◽

Chi Wang ◽

C. Philippe Escoubet ◽

Steve Sembay ◽

Eric Donovan ◽

...

Keyword(s):

Solar Wind ◽

Spatial Scales ◽

Current Status ◽

The Sun ◽

Earth’S Magnetosphere ◽

X Ray ◽

Uv Imaging ◽

X Ray Imaging ◽

Earth's Magnetosphere

The coupling between the solar wind and the Earth's magnetosphere-ionosphere system, and the geospace dynamics that result, comprise some of the key questions in space plasma physics. In situ measurements by a fleet of solar wind and magnetospheric missions, current and planned, can provide the most detailed observations of the Sun-Earth connections. However, we are still unable to quantify the global effects of the drivers of such connections, and to monitor their evolution with time. This information is the key missing link for developing a comprehensive understanding of how the Sun gives rise to and controls the Earth's plasma environment and space weather.SMILE (Solar wind Magnetosphere Ionosphere Link Explorer) is a novel self-standing mission dedicated to observing the solar wind - magnetosphere coupling via simultaneous X-ray imaging of the magnetosheath and polar cusps (large spatial scales at the magnetopause), UV imaging of global auroral distributions (mesoscale structures in the ionosphere) and in situ solar wind/magnetosheath plasma and magnetic field measurements. X-ray imaging of the magnetosheath and cusps is made possible by the X-ray emission produced in the process of solar wind charge exchange, first observed at comets, and subsequently found to occur in the vicinity of the Earth's magnetosphere. One of the science aims of SMILE is to track the substorm cycle, via X-ray imaging on the dayside and by following its consequences on the nightside with UV imaging.&#160;SMILE is a collaborative mission between ESA and the Chinese Academy of Sciences (CAS) that was selected in November 2015, adopted into ESA&#8217;s Cosmic Vision Programme in March 2019, and is due for launch at the end of 2023. The science that SMILE will deliver, as well as the ongoing technical developments and scientific preparations, and the current status of the mission, will be presented.&#160;

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Solar Orbiter’s first Venus flyby: observations from the Radio andPlasma Wave instrument

10.5194/epsc2021-300 ◽

2021 ◽

Author(s):

Lina Hadid ◽

Keyword(s):

Plasma Waves ◽

Bow Shock ◽

The Sun ◽

Gravity Assist ◽

Tail Region ◽

Plasma Properties ◽

In Situ Observations ◽

Orbit Geometry ◽

High Cadence

On December 27, 2020, Solar Orbiter completed its first gravity assist manoeuvre of Venus. While this flyby was performed to provide the spacecraft with sufficient velocity to get closer to the Sun and observe its poles from progressively higher inclinations, the Radio and Plasma Wave (RPW) consortium, along with other operational in-situ instruments, had the opportunity to perform high cadence measurements and study the plasma properties in the induced magnetosphere of Venus. In this work we present an overview of the in situ observations performed by RPW, inside the induced magnetosphere of Venus, during this first encounter of Solar Orbiter. These data allowed conclusive identification of various waves at low and higher frequencies than previously observed and detailed investigation regarding the structure of the induced magnetosphere of Venus. Furthermore, noting that prior studies were mainly focused on the magnetosheath region and could only reach 10-12 Venus radii (RV) down the tail, the particular orbit geometry of Solar Orbiter&#8217;s VGAM1, allowed the first investigation of the nature of the plasma waves continuously from the bow-shock to the magnetosheath, extending to &#8764; 70 R V in the far distant tail region.

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The Science of Space Weather: From Bit Flips to Exoplanets

10.5194/egusphere-egu21-6488 ◽

2021 ◽

Author(s):

Janet G Luhmann

Keyword(s):

Solar Wind ◽

Solar Activity ◽

Space Weather ◽

Interplanetary Space ◽

Planetary Science ◽

In Situ Measurements ◽

Space Environment ◽

The Sun ◽

Multiple Imaging

While the term &#8216;space weather&#8217; remains to some synonymous with operational anomalies on spacecraft, communications interruptions, and other practical matters, its broader implications extend across the EGU and beyond. Much of the science underlying space weather has to do with how our star, the Sun, affects the space environment at Earth&#8217;s orbit. We are lucky to be living at a time where information from both remote sensing (especially imaging at visible, x-ray and EUV wavelengths) and in-situ measurements (of plasmas, magnetic fields, and energetic particles) have provided unprecedented pictures of the Sun and knowledge of its extended atmosphere, the solar wind. Building on early forays into interplanetary space and deployments of coronagraphs with the Helios and SMM missions in the 70s and 80s, the Ulysses mission reconnaissance far above the ecliptic and the launch of Yohkoh&#8217;s and SOHO&#8217;s imagers in the 90s, and the long-term &#8216;monitoring&#8217; of both the Sun and the conditions upstream of the Earth on SOHO, WIND and ACE, the STEREO mission opened a floodgate to research focused on solar activity and its heliospheric and terrestrial consequences. Physics-based, often semi-empirical 3D models increasingly came into widespread use for reconstructing and interpreting the multiple imaging perspectives and multipoint in-situ measurements that the twin STEREO spacecraft, combined with Earth-viewpoint assets (including the GONG ground-based network, and as of 2010, SDO magnetographs), provided on a regular basis. These observations and models together transformed perceptions of phenomena ranging from coronal structure to solar wind sources to eruptive phenomena and consequences, and the tools used to study and forecast them. Now Parker Solar Probe and Solar Orbiter are probing details of the still unexplored regions closer to the Sun than Mercury&#8217;s orbit, with the goal of completing that part of the solar/solar wind connection puzzle. And the overall science results from these observations and analysis efforts have not been confined to heliophysics, having especially influenced planetary science and astrophysics. They are seen in recreations of long-past scenarios when our Sun and solar system were evolving, in investigations of solar activity impacts including auroral emissions at the planets, &#160;and in applications to distant planetary systems around other &#8216;Suns&#8217;. That these lofty implications are related to the bit flips and static &#8216;noise&#8217; first identified with &#8216;space weather&#8217;, provides one of the interesting connections, and still ongoing journeys/stories, within EGU&#8217;s research universe.

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