Your search keyword '"D. Kent Ross"' showing total 15 results

1. The first samples from Almahata Sitta showing contacts between ureilitic and chondritic lithologies: Implications for the structure and composition of asteroid 2008 TC3

Author

Cyrena Anne Goodrich, Michael E. Zolensky, Anna Maria Fioretti, Muawia H. Shaddad, Hilary Downes, Takahiro Hiroi, Issaku Kohl, Edward D. Young, Noriko T. Kita, Victoria E. Hamilton, My E. I. Riebe, Henner Busemann, Robert J. Macke, M. Fries, D. Kent Ross, and Peter Jenniskens

Published

2019

2. Constraints on the Abundances of Carbon and Silicon in Mercury's Core From Experiments in the Fe‐Si‐C System

Author

Kathleen E. Vander Kaaden, Francis M. Mccubbin, Amber A. Turner, and D. Kent Ross

Subjects

Lunar And Planetary Science And Exploration

Abstract

The composition of a planet’s core has important implications for the thermal and magmatic evolution of that planet. Here, we conducted carbon (C)solubility experiments on iron-silicon (Fe-Si)metal mixtures (up to 35 wt%(~52 atom%)Si) at 1 GPa and 800–1800°C to determine the carbon concentration at graphite saturation (CCGS) in metallic melt and crystalline metal with varying proportions of Fe and Si to constrain the C content of Mercury’s core. Our results, combined with those in the literature, show that composition is the major controlling factor for carbon solubility in Fe-rich metal with minimal effects from temperature and pressure. Moreover, there is a strong anti-correlation between the abundances of carbon and silicon in iron-rich metallic systems. Based on the previous estimates of <1–25 wt% Si in Mercury’s core, our results indicate that a carbon-saturated mercurian core has 0.5–6.4wt% C, with 6.4wt% C corresponding to an Si-free, Fe core and 0.5wt% C corresponding to an Fe-rich core with 25 wt% Si. The upper end of estimated FeO abundances in the mantle(up to 2.2 wt%)are consistent with a core that has <1 wt% Siand up to 6.4 wt% C, which would imply that bulk Mercury has a superchondritic Fe/Si ratio. However,the lower end of estimated FeO (≤ 0.05 wt%) support CB-chondrite like bulk compositions of Mercury with core Si abundances in the range of 5–18.5 wt% 33 and C abundances in the range of 0.8–4.0 wt%.

Published

2020

3. Molecular Cloud Origin for Oxygen Isotopic Heterogeneity Recorded by a Primordial Spinel-rich Refractory Inclusion

Author

Justin I. Simon, D. Kent Ross, Ann N. Nguyen, Steven B. Simon, and Scott Messenger

Published

2019

4. The first samples from Almahata Sitta showing contacts between ureilitic and chondritic lithologies: Implications for the structure and composition of asteroid 2008 <scp>TC</scp> 3

Author

Marc Fries, Robert J. Macke, Victoria E. Hamilton, Muawia H. Shaddad, D. Kent Ross, Michael E. Zolensky, Edward D. Young, Henner Busemann, I. E. Kohl, Peter Jenniskens, Noriko T. Kita, A. M. Fioretti, M. E. I. Riebe, Hilary Downes, C. A. Goodrich, and Takahiro Hiroi

Subjects

Almahata Sitta, Olivine, Materials science, Mineralogy, Chondrule, Ureilite, engineering.material, ureilite, 010502 geochemistry & geophysics, 01 natural sciences, Article, Geophysics, Meteorite, Space and Planetary Science, Chondrite, 0103 physical sciences, Pigeonite, engineering, asteroid 2008 TC3, Plagioclase, structure, chondrite, 010303 astronomy & astrophysics, Achondrite, 0105 earth and related environmental sciences

Abstract

Almahata Sitta (AhS), an anomalous polymict ureilite, is the first meteorite observed to originate from a spectrally classified asteroid (2008 TC(3)). However, correlating properties of the meteorite with those of the asteroid is not straightforward because the AhS stones are diverse types. Of those studied prior to this work, 70–80% are ureilites (achondrites) and 20–30% are various types of chondrites. Asteroid 2008 TC(3) was a heterogeneous breccia that disintegrated in the atmosphere, with its clasts landing on Earth as individual stones and most of its mass lost. We describe AhS 91A and AhS 671, which are the first AhS stones to show contacts between ureilitic and chondritic materials and provide direct information about the structure and composition of asteroid 2008 TC(3). AhS 91A and AhS 671 are friable breccias, consisting of a C1 lithology that encloses rounded to angular clasts (

Published

2019

5. U, Th, and K partitioning between metal, silicate, and sulfide and implications for Mercury's structure, volatile content, and radioactive heat production

Author

K. Pando, B. Chidester, Kevin Righter, Lisa R. Danielson, A. Boujibar, D. Kent Ross, Mya Habermann, and M. Righter

Subjects

chemistry.chemical_classification, 010504 meteorology & atmospheric sciences, Sulfide, chemistry.chemical_element, 010502 geochemistry & geophysics, 01 natural sciences, Silicate, Mercury (element), Metal, chemistry.chemical_compound, Geophysics, chemistry, Geochemistry and Petrology, Mineral redox buffer, visual_art, Core formation, Environmental chemistry, visual_art.visual_art_medium, 0105 earth and related environmental sciences

Abstract

The distribution of heat-producing elements (HPE) potassium (K), uranium (U), and thorium (Th) within planetary interiors has major implications for the thermal evolution of the terrestrial planets and for the inventory of volatile elements in the inner solar system. To investigate the abundances of HPE in Mercury’s interior, we conducted experiments at high pressure and temperature (up to 5 GPa and 1900 °C) and reduced conditions (IW-1.8 to IW-6.5) to determine U, Th, and K partitioning between metal, silicate, and sulfide (Dmet/sil and Dsulf/sil). Our experimental data combined with those from the literature show that partitioning into sulfide is more efficient than into metal and that partitioning is enhanced with decreasing FeO and increasing O contents of the silicate and sulfide melts, respectively. Also, at low oxygen fugacity (log fO2 < IW-5), U and Th are more efficiently partitioned into liquid iron metal and sulfide than K. Dmet/sil for U, Th, and K increases with decreasing oxygen fugacity, while DUmet/sil and DKmet/sil increase when the metal is enriched and depleted in O or Si, respectively. We also used available data from the literature to constrain the concentrations of light elements (Si, S, O, and C) in Fe metal and sulfide. We calculated chemical compositions of Mercury’s core after core segregation, for a range of fO2 conditions during its differentiation. For example, if Mercury differentiated at IW-5.5, its core would contain 49 wt% Si, 0.02 wt% S, and negligible C. Also if core-mantle separation happened at a fO2 lower than IW-4, the bulk Mercury Fe/Si ratio is likely to be chondritic. We calculated concentrations of U, Th, and K in the Fe-rich core and possible sulfide layer of Mercury. Bulk Mercury K/U and K/Th were calculated taking all U, Th, and K reservoirs into account. Without any sulfide layer, or if Mercury’s core segregated at a higher fO2 than IW-4, bulk K/U and K/Th would be similar to those measured on the surface, confirming more elevated volatile K concentration than previously expected for Mercury. However, Mercury could fall on an overall volatile depletion trend where K/U increases with the heliocentric distance if core segregation occurred near IW-5.5 or more reduced conditions, and with a sulfide layer of at least 130 km thickness. At these conditions, the bulk Mercury K/Th ratio is close to Venus’s and Earth’s values. Since U and Th become more chalcophile with decreasing oxygen fugacity, to a higher extent than K, it is likely that at an fO2 close to, or lower than, IW-6 both K/U and K/Th become lower than values of the other terrestrial planets. Therefore, our results suggest that the elevated K/U and K/Th ratios of Mercury’s surface should not be exclusively interpreted as the result of a volatile enrichment in Mercury, but could also indicate a sequestration of more U and Th than K in a hidden iron sulfide reservoir, possibly a layer present between the mantle and core. Hence, Mercury could be more depleted in volatiles than Mars with a K concentration similar to or lower than the Earth’s and Venus’s, suggesting volatile depletion in the inner solar system. In addition, we show that the presence of a sulfide layer formed between IW-4 and IW-5.5 decreases the total radioactive heat production of Mercury by up to 30%.

Published

2019

6. Eucrite‐type achondrites: Petrology and oxygen isotope compositions

Author

David W. Mittlefehldt, Richard C. Greenwood, Eve L. Berger, Loan Le, Zhan X. Peng, D. Kent Ross, and Cyrena Goodrich

Subjects

Basalt, Eucrite, Gabbro, Chemistry, engineering.material, Anorthite, Isotopes of oxygen, Parent body, Geophysics, Space and Planetary Science, engineering, Plagioclase, Petrology, Achondrite

Abstract

We report petrologic studies and oxygen isotope analyses of normal and anomalous eucrites, termed eucrite-type achondrites. Petrologically anomalous eucrite-type achondrites can have normal oxygen isotope compositions, and vice versa. Two basaltic eucrites with normal oxygen isotope compositions contain pyroxenes with anomalous Fe/Mn engendered by parent body processes acting on normal eucrites: solid-state reduction by S gas in EET 87542, and reduction during crystallization by magmatic S in QUE 94484. Cataclastic basaltic breccias PCA 82502 and PCA 91007 are paired (petrology, anomalous oxygen). Although isotopically like Pasamonte, they are petrologically distinct. We confirm the petrological and isotopic anomalies of cumulate gabbro EET 92023; likely formed by impact melting of mixed cumulate and basaltic materials. Many main group eucrites include plagioclases that retain near-liquidus compositions despite metamorphic overprinting. Stannern group eucrites contain more sodic plagioclase, which is consistent with the melt hybridization hypothesis for Stannern group magma formation. The lack of more calcic plagioclase suggests reactive exchange of the anorthite component of the primary melt with the albitic component of the crust. Asteroids that are modestly different in composition can produce virtually indistinguishable basalts, providing a ready explanation for the eucrite-type achondrite suite. Small stochastic variations in petrologic evolution can cause substantial differences in rocks produced on an asteroid.

Published

2021

7. Constraints on the Abundances of Carbon and Silicon in Mercury's Core From Experiments in the Fe‐Si‐C System

Author

Amber Turner, Francis M. McCubbin, D. Kent Ross, and Kathleen E. Vander Kaaden

Subjects

Geophysics, Materials science, Silicon, chemistry, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Analytical chemistry, chemistry.chemical_element, Mercury (element)

Published

2020

8. Molecular Cloud Origin for Oxygen Isotopic Heterogeneity Recorded by a Primordial Spinel-rich Refractory Inclusion

Author

Ann N. Nguyen, Scott Messenger, Justin I. Simon, D. Kent Ross, and Steven B. Simon

Subjects

Physics, Molecular cloud, Spinel, chemistry.chemical_element, Astronomy and Astrophysics, engineering.material, Oxygen, Astrobiology, chemistry, Meteorite, Space and Planetary Science, Chondrite, engineering, Inclusion (mineral), Formation and evolution of the Solar System, Refractory (planetary science)

Published

2019

9. Direct Detection of Projectile Relics from the End of the Lunar Basin–Forming Epoch

Author

David A. Kring, Gary R. Huss, David S. McKay, Michael E. Zolensky, Kazuhide Nagashima, D. Kent Ross, and Katherine H. Joy

Subjects

Multidisciplinary, Meteorite, Asteroid, Lithology, Breccia, Chondrule, Early Earth, Billion years, Regolith, Geology, Astrobiology

Abstract

The Rocks That Hit the Moon The cratered surface of the Moon bears witness to the numerous impacts it has suffered. Chemical signatures of these impacts have been detected indirectly. Now, Joy et al. (p. 1426 , published online 17 May; see the Perspective by Rubin ) report the detection and characterization of meteorite fragments preserved in ancient lunar regolith breccias from the Apollo 16 landing site. These meteoritic fragments represent direct samples of the population of small bodies traversing the inner solar system at around 3.4 billion years ago—the same time or just after the basin-forming epoch on the Moon.

Published

2012

10. Northwest Africa 1500: Plagioclase-bearing monomict ureilite or ungrouped achondrite?

Author

D. Kent Ross, Frank Wlotzka, Rainer Bartoschewitz, and Cyrena Anne Goodrich

Subjects

Olivine, Geochemistry, Mineralogy, Ureilite, engineering.material, Poikilitic, Parent body, Geophysics, Augite, Space and Planetary Science, engineering, Plagioclase, Chromite, Achondrite, Geology

Abstract

Northwest Africa (NWA) 1500 is an ultramafic meteorite dominated by coarse (∼100- 500 μm) olivine (95-96%), augite (2-3%), and chromite (0.6-1.6%) in an equilibrated texture. Plagioclase (0.7-1.8%) occurs as poikilitic grains (up to ∼3 mm) in vein-like areas that have concentrations of augite and minor orthopyroxene. Other phases are Cl-apatite, metal, sulfide, and graphite. Olivine ranges from Fo 65-73, with a strong peak at Fo 68-69. Most grains are reverse- zoned, and also have ∼10-30 μm reduction rims. In terms of its dominant mineralogy and texture, NWA 1500 resembles the majority of monomict ureilites. However, it is more ferroan than known ureilites (Fo ≥75) and other mineral compositional parameters are out of the ureilite range as well. Furthermore, neither apatite nor plagioclase have ever been observed, and chromite is rare in monomict ureilites. Nevertheless, this meteorite may be petrologically related to the rare augite-bearing ureilites and represent a previously unsampled part of the ureilite parent body (UPB). The Mn/Mg ratio of its olivine and textural features of its pyroxenes are consistent with this interpretation. However, its petrogenesis differs from that of known augite- bearing ureilites in that: 1) it formed under more oxidized conditions; 2) plagioclase appeared before orthopyroxene in its crystallization sequence; and 3) it equilibrated to significantly lower temperatures (800-1000 °C, from two-pyroxene and olivine-chromite thermometry). Formation under more oxidized conditions and the appearance of plagioclase before orthopyroxene could be explained if it formed at a greater depth on the UPB than previously sampled. However, its significantly different thermal history (compared to ureilites) may more plausibly be explained if it formed on a different parent body. This conclusion is consistent with its oxygen isotopic composition, which suggests that it is an ungrouped achondrite. Nevertheless, the parent body of NWA 1500 may have been compositionally and petrologically similar to the UPB, and may have had a similar differentiation history.

Published

2006

11. Geology of the Atlantis Massif (Mid-Atlantic Ridge, 30° N): Implications for the evolution of an ultramafic oceanic core complex

Author

Elizabeth A. Williams, Deborah S. Kelley, Donna K. Blackman, Timothy Schroeder, Barbara E. John, Gretchen L. Früh-Green, Stephen D. Hurst, Jeffrey S. Gee, Jennifer Morgan, Scott L. Nooner, Johnson R. Cann, Jeffrey A. Karson, and D. Kent Ross

Subjects

Peridotite, geography, geography.geographical_feature_category, Outcrop, Geochemistry, Transform fault, Mid-Atlantic Ridge, Massif, Oceanography, Detachment fault, Oceanic core complex, Dome (geology), Geophysics, Geochemistry and Petrology, Geomorphology, Geology

Abstract

The oceanic core complex comprising Atlantis Massif was formed within the past 1.5–2 Myr at the intersection of the Mid-Atlantic Ridge, 30° N, and the Atlantis Transform Fault. The corrugated, striated central dome prominently displays morphologic and geophysical characteristics representative of an ultramafic core complex exposed via long-lived detachment faulting. Sparse volcanic features on the massif's central dome indicate that minor volcanics have penetrated the inferred footwall, which geophysical data indicates is composed predominantly of variably serpentinized peridotite. In contrast, the hanging wall to the east of the central dome is comprised of volcanic rock. The southern part of the massif has experienced the greatest uplift, shoaling to less than 700 m below sea level, and the coarsely striated surface there extends eastward to the top of the median valley wall. Steep landslide embayments along the south face of the massif expose cross sections through the core complex. Almost all of the submersible and dredge samples from this area are deformed, altered peridotite and lesser gabbro. Intense serpentinization within the south wall has likely contributed to the uplift of the southern ridge and promoted the development of the Lost City Hydrothermal Field near the summit. Differences in the distribution with depth of brittle deformation observed in microstructural analyses of outcrop samples suggest that low-temperature strain, such as would be associated with a major detachment fault, is concentrated within several tens of meters of the domal surface. However, submersible and camera imagery show that deformation is widespread along the southern face of the massif, indicating that a series of faults, rather than a single detachment, accommodated the uplift and evolution of this oceanic core complex.

Published

2002

12. Compositional variations of basaltic glasses from the Mid-Cayman Rise spreading center

Author

James K. Meen, D. Kent Ross, and Don Elthon

Subjects

Atmospheric Science, Soil Science, Mineralogy, Aquatic Science, engineering.material, Oceanography, Mantle (geology), law.invention, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Plagioclase, Crystallization, Earth-Surface Processes, Water Science and Technology, Basalt, Olivine, Ecology, Gabbro, Trace element, Paleontology, Forestry, Igneous rock, Geophysics, Space and Planetary Science, engineering, Geology

Abstract

Basaltic glasses from the Mid-Cayman Rise (MCR) spreading center have a significant range of compositions, from 7.7% to 5.4% MgO. Well-defined trends in the major element and trace element contents of these glasses are consistent with their development by up to 50% crystallization of parental magmas with only a small range of compositional variability. Calculated liquid lines of descent and 1 atm phase equilibria studies of primitive MCR glasses, as well as petrographic relations, indicate that olivine and plagioclase (±spinel) crystallize from MCR liquids at low pressures until the residual liquid has

Published

1995

13. Correction [to 'Compositional variations of basaltic glasses from the Mid-Cayman Rise spreading center' by Don Elthon, D. Kent Ross, and James K. Meen]

Author

Don Elthon, James K. Meen, and D. Kent Ross

Subjects

Basalt, Atmospheric Science, Ecology, Geochemistry, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Center (algebra and category theory), Geology, Earth-Surface Processes, Water Science and Technology

Published

1996

14. Compositional trends of minerals in oceanic cumulates

Author

D. Kent Ross, Matthew Stewart, and Don Elthon

Subjects

Atmospheric Science, Geochemistry, Soil Science, Pyroxene, Aquatic Science, engineering.material, Oceanography, Deep sea, Geochemistry and Petrology, Pigeonite, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology, Petrogenesis, Basalt, geography, geography.geographical_feature_category, Olivine, Ecology, Paleontology, Forestry, Mid-ocean ridge, Geophysics, Space and Planetary Science, engineering, Phenocryst, Geology

Abstract

Five differences are noted between the compositions of minerals in oceanic cumulates and minerals that crystallize from mid-ocean ridge basalts (MORBs) at 1 atm. These differences are (1) Mg numbers of clinopyroxene (CPX) in oceanic cumulates are often higher (>88) than found in experimental studies of MORBs at 1 atm; (2) Mg numbers of orthopyroxene (OPX) in oceanic cumulates are often higher (>81) than found in experimental studies of MORBs at 1 atm; (3) the low-Ca pyroxene in oceanic cumulates (with some notable exceptions) is OPX rather than (inverted) pigeonite; (4) Na2O contents of CPX in oceanic cumulates are often higher (0.3 to 0.8% Na2O) than in 1-atm experiments or phenocrysts in MORBs (typically 0.15 to 0.35% Na2O); and (5) TiO2 contents of CPX in oceanic cumulates are often higher than in 1-atm experiments. These characteristics are consistent with crystallization of many oceanic gabbros at moderate pressures (3–10 kbar). The Na2O and TiO2 contents of liquids calculated to be in equilibrium with CPXs from oceanic cumulates generally are comparable to the abundances of these oxides in MORBs. The notable exception is the suite of cumulates from Deep Sea Drilling Project site 334, which appears to have crystallized at low pressures from strongly depleted Na2O-poor, TiO2-poor, SiO2-rich basalts. We suggest that such strongly depleted basaltic liquids are a widespread, but minor, component in mid-ocean ridge petrogenesis even though such liquids have never been directly sampled.

Published

1992

15. Oxygen isotopic variations in the outer margins and Wark–Lovering rims of refractory inclusions

Author

Peter K. Weber, Steven B. Simon, Lawrence Grossman, J. E. P. Matzel, Ian D. Hutcheon, D. Kent Ross, and Justin I. Simon

Subjects

CAIs, Olivine, 010504 meteorology & atmospheric sciences, Geochemistry, Melilite, Pyroxene, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Parent body, Isotopes of oxygen, Protoplanetary disk, Chondrite, Geochemistry and Petrology, Oxygen isotopes, engineering, NanoSIMS, Wark-Lovering rims, Inclusion (mineral), Geology, Refractory (planetary science), 0105 earth and related environmental sciences

Abstract

Oxygen isotopic variations across the outer margins and Wark–Lovering (WL) rims of a diverse suite of six coarse-grained Types A and B refractory inclusions from both oxidized and reduced CV3 chondrites suggest that CAIs originated from a 16 O-rich protosolar gas reservoir and were later exposed to both relatively 17,18 O-rich and 16 O-rich reservoirs. The O-isotope profiles of CAIs can be explained by changes in the composition of gas near the protoSun or the migration of CAIs through a heterogeneous nebula. Variability within the inclusion interiors appears to have been set prior to WL rim growth. Modeling the isotopic zoning profiles as diffusion gradients between inclusion interiors and edges establishes a range of permissible time–temperature combinations for their exposure in the nebula. At mean temperatures of 1400 K, models that match the isotope gradients in the inclusions yield timescales ranging from 5 × 10 3 to 3 × 10 5 years. Assuming CAIs originated with a relatively 16 O-rich (protosolar) isotopic composition, differences among the melilite interiors and the isotopic gradients in their margins imply the existence of a number of isotopically distinct reservoirs. Evidence at the edges of some CAIs for subsequent isotopic exchange may relate to the beginning of rim formation. In the WL rim layers surrounding the interiors, spinel is relatively 16 O-rich but subtly distinct among different CAIs. Melilite is often relatively 16 O-poor, but rare relatively 16 O-rich grains also exist. Pyroxene generally exhibits intermediate O-isotope compositions and isotopic zoning. Olivine in both WL and accretionary rims, when present, is isotopically heterogeneous. The extreme isotopic heterogeneity among and within individual WL rim layers and in particular, the observed trends of outward 16 O-enrichments, suggest that rims surrounding CAIs contained in CV3 chondrites, like the inclusions themselves, formed from a number of isotopically distinct gas reservoirs. Collectively, these results support numerical protoplanetary disk models in which CAIs were transported between several distinct nebular reservoirs multiple times prior to accretion onto a parent body.