Solar wind charge exchange in cometary atmospheres

Wedlund, Cyril Simon; Béhar, Etienne; Kallio, Esa; Nilsson, Hans; Alho, Markku; Gunell, H.; Bodewits, Dennis; Beth, Arnaud; Gronoff, Guillaume; Hoekstra, Ronnie

doi:10.1051/0004-6361/201834874

Cited by 16 publications

(23 citation statements)

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“…The observation of the change in solar wind composition is a proof of charge exchange, for example, at comets (Simon Wedlund, Behar, Kallio, et al. 2019; Simon Wedlund, Bodewits, et al., 2019; Simon Wedlund, Behar, et al., 2019). At Mars, the charge exchange of solar wind protons at the bow shock leads to precipitation of H that can be observed by the effects on the chemistry and by the backscatter (Halekas, 2017), even if the H chemistry at Mars is complex (Chaffin et al., 2017) One more striking example of charge‐exchange processes at Mars is the observation of heavier ions, such as O + , that later lead to sputtering (Leblanc et al., 2015, 2018).…”

Section: The Escape Processesmentioning

confidence: 98%

“…The latter charge‐exchanged ions, originating from solar wind He 2+ ions (composing about 4% of the bulk of the undisturbed solar wind), were present throughout the mission from a heliocentric distance ranging from 3.4 to 2 AU (Simon Wedlund et al., 2016; Simon Wedlund, Behar, Kallio, et al. 2019; Simon Wedlund, Bodewits, et al., 2019; Simon Wedlund, Behar, et al., 2019). The net effect of the charge transfer of He 2+ solar wind ions with the neutral atmosphere of the comet (composed of molecules M) is the production of ENAs following the typical sequence of electron capture reactions (double charge transfer, and stripping reactions are ignored here for simplicity):

{He}^{2 +} + normalM \to {He}^{+} + {normalM}^{+}

{He}^{+} + normalM \to He + {normalM}^{+} .

…”

Section: The Escape Processesmentioning

confidence: 99%

“…This total conversion depends on many parameters: outgassing rate, heliocentric distance, solar wind density, and speed (Simon Wedlund, Behar, Kallio, et al. 2019; Simon Wedlund, Bodewits, et al., 2019; Simon Wedlund, Behar, et al., 2019). The effect of minor solar wind species (multiply‐charged heavy ions) can be seen in the production of X‐rays through charge exchange emission with the cometary atmosphere (Cravens, 1997).…”

Section: The Escape Processesmentioning

confidence: 99%

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Atmospheric Escape Processes and Planetary Atmospheric Evolution

et al. 2020

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The habitability of the surface of any planet is determined by a complex evolution of its interior, surface, and atmosphere. The electromagnetic and particle radiation of stars drive thermal, chemical, and physical alteration of planetary atmospheres, including escape. Many known extrasolar planets experience vastly different stellar environments than those in our solar system: It is crucial to understand the broad range of processes that lead to atmospheric escape and evolution under a wide range of conditions if we are to assess the habitability of worlds around other stars. One problem encountered between the planetary and the astrophysics communities is a lack of common language for describing escape processes. Each community has customary approximations that may be questioned by the other, such as the hypothesis of H‐dominated thermosphere for astrophysicists or the Sun‐like nature of the stars for planetary scientists. Since exoplanets are becoming one of the main targets for the detection of life, a common set of definitions and hypotheses are required. We review the different escape mechanisms proposed for the evolution of planetary and exoplanetary atmospheres. We propose a common definition for the different escape mechanisms, and we show the important parameters to take into account when evaluating the escape at a planet in time. We show that the paradigm of the magnetic field as an atmospheric shield should be changed and that recent work on the history of Xenon in Earth's atmosphere gives an elegant explanation to its enrichment in heavier isotopes: the so‐called Xenon paradox.

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Section: The Escape Processesmentioning

confidence: 98%

{He}^{2 +} + normalM \to {He}^{+} + {normalM}^{+}

{He}^{+} + normalM \to He + {normalM}^{+} .

…”

Section: The Escape Processesmentioning

confidence: 99%

Section: The Escape Processesmentioning

confidence: 99%

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Atmospheric Escape Processes and Planetary Atmospheric Evolution

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“…Burch et al (2015) detected H − negative ions in the early phase of the mission for the first time. They were confirmed to be arising from two consecutive singleelectron captures from the initial solar wind protons (Burch et al 2015;Simon Wedlund et al 2019b).…”

Section: Introductionmentioning

confidence: 91%

“…As solar wind H + and He 2+ ions impinge upon an atmosphere, charge-changing reactions start fractionating the initial charge state distribution into a mixture of H + , H 0 , and H − on the one hand, and of He 2+ , He + , and He 0 species on the other (Simon Wedlund et al 2019b). This effectively results in the production of fast energetic neutral atoms (ENAs), which are not bound to the plasma, but may interact further with the atmosphere downstream of the SWCX collision (see Fig.…”

Section: Introductionmentioning

confidence: 99%

Solar wind charge exchange in cometary atmospheres

Wedlund

Béhar

Nilsson

et al. 2019

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Context. Solar wind charge-changing reactions are of paramount importance to the physico-chemistry of the atmosphere of a comet. The ESA/Rosetta mission to comet 67P/Churyumov-Gerasimenko (67P) provides a unique opportunity to study charge-changing processes in situ. Aims. To understand the role of these reactions in the evolution of the solar wind plasma and interpret the complex in situ measurements made by Rosetta, numerical or analytical models are necessary. Methods. We used an extended analytical formalism describing solar wind charge-changing processes at comets along solar wind streamlines. The model is driven by solar wind ion measurements from the Rosetta Plasma Consortium-Ion Composition Analyser (RPC-ICA) and neutral density observations from the Rosetta Spectrometer for Ion and Neutral Analysis-Comet Pressure Sensor (ROSINA-COPS), as well as by charge-changing cross sections of hydrogen and helium particles in a water gas. Results. A mission-wide overview of charge-changing efficiencies at comet 67P is presented. Electron capture cross sections dominate and favor the production of He and H energetic neutral atoms (ENAs), with fluxes expected to rival those of H + and He 2+ ions. Conclusions. Neutral outgassing rates are retrieved from local RPC-ICA flux measurements and match ROSINA estimates very well throughout the mission. From the model, we find that solar wind charge exchange is unable to fully explain the magnitude of the sharp drop in solar wind ion fluxes observed by Rosetta for heliocentric distances below 2.5 AU. This is likely because the model does not take the relative ion dynamics into account and to a lesser extent because it ignores the formation of bow-shock-like structures upstream of the nucleus. This work also shows that the ionization by solar extreme-ultraviolet radiation and energetic electrons dominates the source of cometary ions, although solar wind contributions may be significant during isolated events.

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The Plasma Environment of Comet 67P/Churyumov-Gerasimenko

et al. 2022

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The environment of a comet is a fascinating and unique laboratory to study plasma processes and the formation of structures such as shocks and discontinuities from electron scales to ion scales and above. The European Space Agency’s Rosetta mission collected data for more than two years, from the rendezvous with comet 67P/Churyumov-Gerasimenko in August 2014 until the final touch-down of the spacecraft end of September 2016. This escort phase spanned a large arc of the comet’s orbit around the Sun, including its perihelion and corresponding to heliocentric distances between 3.8 AU and 1.24 AU. The length of the active mission together with this span in heliocentric and cometocentric distances make the Rosetta data set unique and much richer than sets obtained with previous cometary probes. Here, we review the results from the Rosetta mission that pertain to the plasma environment. We detail all known sources and losses of the plasma and typical processes within it. The findings from in-situ plasma measurements are complemented by remote observations of emissions from the plasma. Overviews of the methods and instruments used in the study are given as well as a short review of the Rosetta mission. The long duration of the Rosetta mission provides the opportunity to better understand how the importance of these processes changes depending on parameters like the outgassing rate and the solar wind conditions. We discuss how the shape and existence of large scale structures depend on these parameters and how the plasma within different regions of the plasma environment can be characterised. We end with a non-exhaustive list of still open questions, as well as suggestions on how to answer them in the future.

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Solar wind charge exchange in cometary atmospheres

Cited by 16 publications

References 60 publications

Atmospheric Escape Processes and Planetary Atmospheric Evolution

Atmospheric Escape Processes and Planetary Atmospheric Evolution

Solar wind charge exchange in cometary atmospheres

The Plasma Environment of Comet 67P/Churyumov-Gerasimenko

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