Radiolysis and Photolysis of Icy Satellite Surfaces: Experiments and Theory

Cassidy, Timothy A.; Coll, Patrice; Raulin, F.; Carlson, R. W.; Johnson, R. E.; Loeffler, M. J.; Hand, K. P.; Baragiola, R. A.

doi:10.1007/s11214-009-9625-3

Cited by 75 publications

(52 citation statements)

References 91 publications

(98 reference statements)

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“…Irradiation studies of sulfurbearing ices have found that among the stable irradiation products are long-chained sulfur molecules (e.g., Moore 1984;Cassidy et al 2010), which produce a dark residue and have been interpreted, for example, as the cause of the darkened, intensely red deposits found on Io (Carlson et al 2007). Within the framework of our hypothesis, we propose that the retention of H 2 S on the surface of objects in the outer primordial disk contributed to a significant additional reddening, leading to the VR colors.…”

Section: Surface Radiation Processingmentioning

confidence: 99%

A Hypothesis for the Color Bimodality of Jupiter Trojans

Wong

Brown

2016

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One of the most enigmatic and hitherto unexplained properties of Jupiter Trojans is their bimodal color distribution. This bimodality is indicative of two sub-populations within the Trojans, which have distinct size distributions. In this paper, we present a simple, plausible hypothesis for the origin and evolution of the two Trojan color sub-populations. In the framework of dynamical instability models of early solar system evolution, which suggest a common primordial progenitor population for both Trojans and Kuiper Belt objects, we use observational constraints to assert that the color bimodalities evident in both minor body populations developed within the primordial population prior to the onset of instability. We show that, beginning with an initial composition of rock and ices, location-dependent volatile loss through sublimation in this primordial population could have led to sharp changes in the surface composition with heliocentric distance. We propose that the depletion or retention of H 2 S ice on the surface of these objects was the key factor in creating an initial color bimodality. Objects that retained H 2 S on their surfaces developed characteristically redder colors upon irradiation than those that did not. After the bodies from the primordial population were scattered and emplaced into their current positions, they preserved this primordial color bimodality to the present day. We explore predictions of the volatile loss model-in particular, the effect of collisions within the Trojan population on the size distributions of the two sub-populations-and propose further experimental and observational tests of our hypothesis.

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Section: Surface Radiation Processingmentioning

confidence: 99%

A Hypothesis for the Color Bimodality of Jupiter Trojans

Wong

Brown

2016

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“…The resulting organics which are produced through high energy photon and electron chemistry, include low molecular organic species, several of which are of prebiotic interest, such as HCN and HC 3 N, and higher molecular compounds, tholin-like products (cf. Cassidy et al 2010, this issue). The later probably form the aerosol particles present in the lower parts of the atmosphere.…”

Section: Prebiotic Chemistry In the Atmosphere On The Surface In Thmentioning

confidence: 97%

“…Atmospheric chemistry in Titan allows the continuous transformation of methane and dinitrogen into complex organic compounds from the high atmosphere to the surface (see Coustenis et al 2010, this issue;Cassidy et al 2010, this issue).The recent Cassini data, especially from the INMS and CAPS instruments, indicates that the processes start in the ionosphere (Waite et al 2005(Waite et al , 2007. The resulting organics which are produced through high energy photon and electron chemistry, include low molecular organic species, several of which are of prebiotic interest, such as HCN and HC 3 N, and higher molecular compounds, tholin-like products (cf.…”

Section: Prebiotic Chemistry In the Atmosphere On The Surface In Thmentioning

confidence: 99%

Exobiology and Planetary Protection of icy moons

et al. 2010

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The outer solar system is an important area of investigation for exobiology, the study of life in the universe. Several moons of the outer planets involve processes and structures comparable to those thought to have played an important role in the emergence of life on Earth, such as the formation and exchange of organic materials between different reservoirs. The study of these prebiotic processes on, and in, outer solar system moons is a key goal for exobiology, together with the question of habitability and the search for evidence of past or even present life. This chapter reviews the aspects of prebiotic chemistry and potential presence of life on Europa, Enceladus and Titan, based on the most recent data obtained from space missions as well as theoretical and experimental laboratory models. The habitability of these extraterrestrial environments, which are likely to include large reservoirs of liquid water in their internal structure, is discussed as well as the particular case of Titan's hydrocarbon lakes. The question of planetary protection, especially in the case of Europa, is also presented. F. Raulin ( ) Exobiology and HabitabilitySince the emergence of exobiology in the 1960s, the definition of this new and continuously increasing field has evolved from the search for and study of life outside the Earth to the study of life in the whole universe. Exobiology (∼ astrobiology) thus includes today the search for extraterrestrial life, but also the study of the origin and limits of life on Earth, as well as the study of processes and structures related to life. Extraterrestrial organic chemistry, and all related processes, including the formation and exchange of organic materials between different reservoirs of planetary significance is an important part of exobiology. The later are present in many planetary objects of the solar system, especially in the outer solar system, on and in many of its moons.Several of these extraterrestrial organic processes may be similar to those which allowed the origin of life on Earth, about 4 billion years ago. They involve low molecular weight reactive compounds, such as nitriles, HCN and HC 3 CN, and hydrocarbons such as C 2 H 2 and C 2 H 4 , and their oligomers or polymers. The chemical evolution of these compounds in liquid water yielded macromolecules capable of self-replication on the primitive Earth, and the first living systems. Studying some of the chemical steps which are occurring today in these extraterrestrial environments and in particular the exchange processes involved can provide some insights into the chemical evolution which occurred on the early Earth. Studying these processes is of paramount importance since they are not present anymore on our planet and cannot be reproduced experimentally in the laboratory because of unrealistic time requirements. Those processes are also of great interest by themselves since they allow complexification of matter in extraterrestrial environments, providing a possible step toward the emergence of life, either for life a...

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“…The interactions between the Galilean satellites and the plasma of the Jovian magnetosphere lead to local changes in the charged particle populations through either additions of new ions or through changes of the momentum that produce plasma heating or cooling. Plasma-surface interactions at Europa and Ganymede have been shown to generate neutral environments around these moons through either direct ion sputtering or radiolysis, followed by sputtering of the recombined water-dissociation products (Shematovich & Johnson 2001;Shematovich et al 2005;Cassidy et al 2010Cassidy et al , 2013. These exospheres have been demonstrated to be spatially non-uniform (Plainaki et al 2012(Plainaki et al , 2013, depending both on the moons' illumination by the Sun and on Jupiter's magnetospheric plasma properties.…”

Section: Space Weather In the Jovian Systemmentioning

confidence: 99%

“…Indirectly: The impact of energetic ions on an icy satellite surface is followed by the release of surface material to the body's exosphere through direct sputtering and/or radiolysis (for an example of how these release mechanisms work see: Johnson et al 2004;Cassidy et al 2010;Teolis et al 2010;Plainaki et al 2012). The generated exospheres are furthermore subject to loss processes either due to gravity escape and particle sticking to the surface or due to photon or plasma-induced ionization/dissociation of their constituents.…”

Section: Energetic Particle Populationsmentioning

confidence: 99%

Planetary space weather: scientific aspects and future perspectives

Plainaki

Lilensten

Radioti

et al. 2016

J. Space Weather Space Clim.

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In this paper, we review the scientific aspects of planetary space weather at different regions of our Solar System, performing a comparative planetology analysis that includes a direct reference to the circum-terrestrial case. Through an interdisciplinary analysis of existing results based both on observational data and theoretical models, we review the nature of the interactions between the environment of a Solar System body other than the Earth and the impinging plasma/radiation, and we offer some considerations related to the planning of future space observations. We highlight the importance of such comparative studies for data interpretations in the context of future space missions (e.g. ESA JUICE; ESA/JAXA BEPI COLOMBO). Moreover, we discuss how the study of planetary space weather can provide feedback for better understanding the traditional circumterrestrial space weather. Finally, a strategy for future global investigations related to this thematic is proposed.

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Radiolysis and Photolysis of Icy Satellite Surfaces: Experiments and Theory

Cited by 75 publications

References 91 publications

A Hypothesis for the Color Bimodality of Jupiter Trojans

A Hypothesis for the Color Bimodality of Jupiter Trojans

Exobiology and Planetary Protection of icy moons

Planetary space weather: scientific aspects and future perspectives

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