Your search keyword '"Corrigan, Catherine"' showing total 6 results

1. The Fate of Primary Iron Sulfides in the CM1 Carbonaceous Chondrites: Effects of Advanced Aqueous Alteration on Primary Components

Author

Singerling, Sheryl A., Corrigan, Catherine M., and Brearley, Adrian J.

Subjects

Astrophysics - Earth and Planetary Astrophysics, Physics - Geophysics

Abstract

We have carried out a SEM-EPMA-TEM study to determine the textures and compositions of relict primary iron sulfides and their alteration products in a suite of moderately to heavily-altered CM1 carbonaceous chondrites. We observed four textural groups of altered primary iron sulfides: 1) pentlandite+phyllosilicate (2P) grains, characterized by pentlandite with submicron lenses of phyllosilicates, 2) pyrrhotite+pentlandite+magnetite (PPM) grains, characterized by pyrrhotite-pentlandite exsolution textures with magnetite veining and secondary pentlandite, 3) pentlandite+serpentine (PS) grains, characterized by relict pentlandite exsolution, serpentine, and secondary pentlandite, and 4) pyrrhotite+pentlandite+magnetite+serpentine (PPMS) grains, characterized by features of both the PPM and PS grains. We have determined that all four groups were initially primary iron sulfides, which formed from crystallization of immiscible sulfide melts within silicate chondrules in the solar nebula. The fact that such different alteration products could result from the same precursor sulfides within even the same meteorite sample further underscores the complexity of the aqueous alteration environment for the CM chondrites. The different alteration reactions for each textural group place constraints on the mechanisms and conditions of alteration with evidence for acidic environments, oxidizing environments, and changing fluid compositions (Ni-bearing and Si-Mg-bearing)., Comment: 53 pages, 10 figures, 2 tables, appendix containing 3 additional figures and 5 additional tables

Published

2024

2. Novel halogenated flame retardants in Canadian human milk from the MIREC study (2008–2011)

Author

Rawn, Dorothea F.K., Corrigan, Catherine, Ménard, Cathie, Sun, Wing-Fung, Breton, François, and Arbuckle, Tye E.

Published

2024

3. The formation of volatile‐bearing djerfisherite in reduced meteorites

Author

Wilbur, Zoë E., primary, McCoy, Timothy J., additional, Corrigan, Catherine M., additional, Barnes, Jessica J., additional, Brown, Sierra V., additional, and Udry, Arya, additional

Published

2024

4. Leveraging Doctor of Nursing Practice Scholarship to Meet Organizational Leaders’ Expectations

Author

Kesten, Karen, primary, Beebe, Sarah, additional, Conrad, Dianne, additional, Corrigan, Catherine, additional, Moran, Katherine, additional, and Manderscheid, Amy, additional

Published

2024

5. Letter to the Editor

Author

Kesten, Karen S., Moran, Katherine, Beebe, Sarah L., Conrad, Dianne, Burson, Rosanne, Corrigan, Catherine, Manderscheid, Amy, and Pohl, Elizabeth

Published

2024

6. Finely layered CM2 carbonaceous chondrites may be analogs for layered boulders on asteroid (101955) Bennu.

Author

Jawin, Erica R., McCOY, Timothy J., Melendez, Lisette E., Corrigan, Catherine M., Righter, Kevin, and Connolly, Harold C. Jr

Subjects

*METEORITES, *CHONDRITES, *BOULDERS, *COLLECTIONS

Abstract

Orbital observations of Bennu revealed a surface covered in boulders that are most similar among meteorites in our collections to aqueously altered carbonaceous chondrites, and initial analyses of the returned Bennu sample have begun to reveal insights into Bennu's origins. We identified a suite of paired CM2 chondrite meteorites that have a finely layered texture and bear a striking similarity, although at a different scale, to rugged, layered boulders on Bennu. We investigated the nature and potential origin of this layered texture by performing a petrofabric analysis on samples MET 00431, 00434, and 00435. We developed a micro‐geospatial mapping framework that is more commonly used for landscape‐scale investigations. Our results reveal a pervasive fracture network that exhibits a similar orientation to flattened particles dominated by tochilinite–cronstedtite intergrowths (TCI). We propose that their petrofabrics originated from a low‐energy impact on the parent body that occurred after the main period of aqueous alteration halted. The impactdeformed TCI (which formed during earlier aqueous alteration) and generated the fractures. We propose that the sample from Bennu may contain particles with similar layered textures to these meteorites which, if present, would likewise indicate the dominant role of impacts and aqueous alteration on Bennu's parent body. [ABSTRACT FROM AUTHOR]

Published

2024