Search

Your search keyword '"Sunshine, Jessica M."' showing total 11 results
Start Over Author "Sunshine, Jessica M." Publisher wiley
11 results on '"Sunshine, Jessica M."'

1. Parent body histories recorded in Rumuruti chondrite sulfides: Implications for the onset of oxidized, sulfur-rich core formation

Author

Crossley, Samuel D., Crossley, Samuel D., Ash, Richard D., Sunshine, Jessica M., Corrigan, Catherine M., McCoy, Timothy J., Crossley, Samuel D., Crossley, Samuel D., Ash, Richard D., Sunshine, Jessica M., Corrigan, Catherine M., and McCoy, Timothy J.

Abstract

Models of planetary core formation beginning with melting of Fe,Ni metal and troilite are not readily applicable to oxidized and sulfur-rich chondrites containing only trace quantities of metal. Cores formed in these bodies must be dominated by sulfides. Siderophile trace elements used to model metallic core formation could be used to model oxidized, sulfide-dominated core formation and identify related meteorites if their trace element systematics can be quantified. Insufficient information exists regarding the behavior of these core-forming elements among sulfides during metamorphism prior to anatexis. Major, minor, and trace element concentrations of sulfides are reported in this study for petrologic type 3–6 R chondrite materials. Sulfide-dominated core-forming components in such oxidized chondrites (ƒO2 ≥ iron-wüstite) follow metamorphic evolutionary pathways that are distinct from reduced, metal-bearing counterparts. Most siderophile trace elements partition into pentlandite at approximately 10× chondritic abundances, but Pt, W, Mo, Ga, and Ge are depleted by 1–2 orders of magnitude relative to siderophile elements with similar volatilities. The distribution of siderophile elements is further altered during hydrothermal alteration as pyrrhotite oxidizes to form magnetite. Oxidized, sulfide-dominated core formation differs from metallic core formation models both physically and geochemically. Incongruent melting of pentlandite at 865°C generates melts capable of migrating along solid silicate grains, which can segregate to form a Ni,S-rich core at lower temperatures compared to reduced differentiated parent bodies and with distinct siderophile interelement proportions.

Published
2023

4. Global variations in regolith properties on asteroid Vesta from Dawn's low‐altitude mapping orbit

Author

Denevi, Brett W., primary, Beck, Andrew W., additional, Coman, Ecaterina I., additional, Thomson, Bradley J., additional, Ammannito, Eleonora, additional, Blewett, David T., additional, Sunshine, Jessica M., additional, De Sanctis, Maria Cristina, additional, Li, Jian‐Yang, additional, Marchi, Simone, additional, Mittlefehldt, David W., additional, Petro, Noah E., additional, Raymond, Carol A., additional, and Russell, Christopher T., additional

Published
2016
Full Text
View/download PDF

5. Vestan lithologies mapped by the visual and infrared spectrometer on Dawn

Author

Ammannito, Eleonora, primary, De Sanctis, M. Cristina, additional, Capaccioni, Fabrizio, additional, Teresa Capria, M., additional, Carraro, F., additional, Combe, Jean‐Philippe, additional, Fonte, Sergio, additional, Frigeri, Alessandro, additional, Joy, Steven P., additional, Longobardo, Andrea, additional, Magni, Gianfranco, additional, Marchi, Simone, additional, McCord, Thomas B., additional, McFadden, Lucy A., additional, McSween, Harry Y., additional, Palomba, Ernesto, additional, Pieters, Carle M., additional, Polanskey, Carol A., additional, Raymond, Carol A., additional, Sunshine, Jessica M., additional, Tosi, Federico, additional, Zambon, Francesca, additional, and Russell, Christopher T., additional

Published
2013
Full Text
View/download PDF

11. Evidence for geologic processes on comets

Author

Sunshine, Jessica M., Thomas, Nicolas, Elmaarry, Mohamed Ramy, and Farnham, Tony L.

Subjects
13. Climate action, 520 Astronomy, 620 Engineering
Abstract

Spacecraft missions have resolved the nuclei of six periodic comets and revealed a set of geologically intriguing and active small bodies. The shapes of these cometary nuclei are dominantly bilobate reflecting their formation from smaller cometesimals. Cometary surfaces include a diverse set of morphologies formed from a variety of mechanisms. Sublimation of ices, driven by the variable insolation over the time since each nucleus was perturbed into the inner Solar System, is a major process on comets and is likely responsible for quasi-circular depressions and ubiquitous layering. Sublimation from near-vertical walls is also seen to lead to undercutting and mass wasting. Fracturing has only been resolved on one comet but likely exists on all comets. There is also evidence for mass redistribution, where material lifted off the nucleus by subliming gases is deposited onto other surfaces. It is surprising that such sedimentary processes are significant in the microgravity environment of comets. There are many enigmatic features on cometary surfaces including tall spires, kilometer-scale flows, and various forms of depressions and pits. Furthermore, even after accounting for the differences in resolution and coverage, significant diversity in landforms among cometary surfaces clearly exists. Yet why certain landforms occur on some comets and not on others remains poorly understood. The exploration and understanding of geologic processes on comets is only beginning. These fascinating bodies will continue to provide a unique laboratory for examining common geologic processes under the uncommon conditions of very high porosity, very low strength, small particle sizes, and near-zero gravity.

Catalog

Books, media, physical & digital resources
See catalog results