Your search keyword '"Mittlefehldt, David W"' showing total 20 results

1. The Fall, Recovery, Orbit, and Composition of the Tagish Lake Meteorite: A New Type of Carbonaceous Chondrite

Author

Brown, Peter G., Hildebrand, Alan R., Zolensky, Michael E., Grady, Monica, Clayton, Robert N., Mayeda, Toshiko K., Tagliaferri, Edward, Spalding, Richard, MacRae, Neil D., Hoffman, Eric L., Mittlefehldt, David W., Wacker, John F., Bird, J. Andrew, Campbell, Margaret D., Carpenter, Robert, Gingerich, Heather, Glatiotis, Michael, Greiner, Erika, Mazur, Michael J., Plotkin, Howard, and Mazur, Tina Rubak

Published

2000

2. Iridium Metal in Chicxulub Impact Melt: Forensic Chemistry on the K-T Smoking Gun

Author

Schuraytz, Benjamin C., Lindstrom, David J., Marín, Luis E., Martinez, René R., Mittlefehldt, David W., Sharpton, Virgil L., and Wentworth, Susan J.

Published

1996

3. HED Meteorites and Their Relationship to the Geology of Vesta and the Dawn Mission

Author

McSween, Harry Y., Jr., Mittlefehldt, David W., Beck, Andrew W., Mayne, Rhiannon G., McCoy, Timothy J., Russell, Christopher, editor, and Raymond, Carol, editor

Published

2012

4. Missing Martian Meteorites

Author

Mittlefehldt, David W.

Published

2000

5. Extra-terrestrial mantle samples: Rare Earth Element variations and evidence for melt metasomatism in ureilite meteorites.

Author

Downes, Hilary, Mittlefehldt, David W., Ross, Aidan J., and Lee, Cin-Ty

Subjects

*SILICATE minerals, *RARE earth metals, *ACHONDRITES, *ORTHOPYROXENE, *METEORITES, *MARTIAN meteorites, *ASTEROIDS

Abstract

Ureilites are meteorites derived from the mantle of a reduced differentiated asteroid, the "Ureilite Parent Body" (UPB), which was later disrupted by impact with another Solar System body. They have ultramafic compositions dominated mostly by olivine and pigeonite with rare orthopyroxene and augite; aluminous phases are generally absent. Ureilites vary from abundant peridotites to much rarer pyroxenites, and their core olivine compositions range from Fo 74 to Fo 97 across different samples. The UPB experienced sufficiently high temperatures to undergo silicate partial melting, as shown by depletion in the Light Rare Earth Elements (LREE) in bulk restitic ureilites. Plagioclase and merrillite were probably present in the UPB mantle but have been completely removed during silicate partial melting. Partial melts of the UPB mantle are represented by glassy melt inclusions, igneous clasts in ureilite breccias, cumulus augite in some ureilites, and rare trachyandesitic fragments. These melts are generally intermediate and sub-alkaline in composition, although a few are alkaline. They have more enriched and flatter bulk REE patterns than the restitic ureilites and often show positive Eu anomalies. Glasses (representing melts) in ureilites from this study range from 57 to 79 wt% SiO 2. One sample (AhS 22) shows petrographic and geochemical evidence for interaction between magma and the solid UPB mantle by forming metasomatic augite. Silicate minerals in ureilites analysed by LA-ICP-MS are generally LREE-depleted, with negative Eu anomalies. Ureilitic olivines have the lowest REE contents and the smallest negative Eu anomalies. Low-Ca pyroxenes have similar patterns with slightly stronger Eu anomalies. Augites have the highest REE contents and the most negative Eu anomalies. Augites show REE disequilibrium with olivine and low-Ca pyroxene, suggesting that they were not part of the restitic assemblage but were added by silicate melts passing through the UPB mantle, i.e. they are metasomatic in origin. We also discuss the size of the original UPB, using silicate minerals as evidence for it being a typical asteroid rather than a planet-sized object. • High-quality trace element data in ureilite minerals. • REE disequilibrium between augite and other minerals. • New compositional data for glass inclusions in ureilites. • Mantle metasomatism on an asteroidal body. [ABSTRACT FROM AUTHOR]

Published

2024

6. Mesosiderite Clasts with the Most Extreme Positive Europium Anomalies Among Solar System Rocks

Author

Mittlefehldt, David W., Rubin, Alan E., and Davis, Andrew M.

Published

1992

7. HED Meteorites and Their Relationship to the Geology of Vesta and the Dawn Mission

Author

McSween, Jr., Harry Y., Mittlefehldt, David W., Beck, Andrew W., Mayne, Rhiannon G., and McCoy, Timothy J.

Published

2011

8. The Latest News from Mars

Author

Mittlefehldt, David W.

Published

2000

9. Asteroid (4) Vesta II: Exploring a geologically and geochemically complex world with the Dawn Mission.

Author

McCoy, Timothy J., Beck, Andrew W., Prettyman, Thomas H., and Mittlefehldt, David W.

Subjects

ASTEROIDS, MINERALOGY, IR spectrometers, METEORITES

Abstract

More than 200 years after its discovery, asteroid (4) Vesta is thought to be the parent body for the howardite, eucrite and diogenite (HED) meteorites. The Dawn spacecraft spent ∼14 months in orbit around this largest, intact differentiated asteroid to study its internal structure, geology, mineralogy and chemistry. Carrying a suite of instruments that included two framing cameras, a visible-near infrared spectrometer, and a gamma-ray and neutron detector, coupled with radio tracking for gravity, Dawn revealed a geologically and geochemically complex world. A constrained core size of ∼110–130 km radius is consistent with predictions based on differentiation models for the HED meteorite parent body. Hubble Space Telescope observations had already shown that Vesta is scarred by a south polar basin comparable in diameter to that of the asteroid itself. Dawn showed that the south polar Rheasilvia basin dominates the asteroid, with a central uplift that rivals the large shield volcanoes of the Solar System in height. An older basin, Veneneia, partially underlies Rheasilvia. A series of graben-like equatorial and northern troughs were created during these massive impact events 1–2 Ga ago. These events also resurfaced much of the southern hemisphere and exposed deeper-seated diogenitic lithologies. Although the mineralogy and geochemistry vary across the surface for rock-forming elements and minerals, the range is small, suggesting that impact processes have efficiently homogenized the surface of Vesta at scales observed by the instruments on the Dawn spacecraft. The distribution of hydrogen is correlated with surface age, which likely results from the admixture of exogenic carbonaceous chondrites with Vesta's basaltic surface. Clasts of such material are observed within the surficial howardite meteorites in our collections. Dawn significantly strengthened the link between (4) Vesta and the HED meteorites, but the pervasive mixing, lack of a convincing and widespread detection of olivine, and poorly-constrained lateral and vertical extents of units leaves unanswered the central question of whether Vesta once had a magma ocean. Dawn is continuing its mission to the presumed ice-rich asteroid (1) Ceres. [ABSTRACT FROM AUTHOR]

Published

2015

10. Asteroid (4) Vesta: I. The howardite-eucrite-diogenite (HED) clan of meteorites.

Author

Mittlefehldt, David W.

Subjects

ASTEROIDS, METEORITES, IGNEOUS rocks, DATA analysis, SOLAR system, METAMORPHISM (Geology)

Abstract

The howardite, eucrite and diogenite (HED) clan of meteorites are ultramafic and mafic igneous rocks and impact-engendered fragmental debris derived from a thoroughly differentiated asteroid. Earth-based telescopic observation and data returned from vestan orbit by the Dawn spacecraft make a compelling case that the asteroid (4) Vesta is the parent asteroid of HEDs, although this is not universally accepted. Diogenites are petrologically diverse and include dunitic, harzburgitic and noritic lithologic types in addition to the traditional orthopyroxenites. Diogenites form the lower crust of Vesta. Cumulate eucrites are gabbroic rocks formed by accumulation of pigeonite and plagioclase from a mafic magma at depth within the crust, while basaltic eucrites are melt compositions that likely represent shallow-level dikes and sills, and flows. Some basaltic eucrites are richer in incompatible trace elements compared to most eucrites, and these may represent mixed melts contaminated by partial melts of the mafic crust. Differentiation occurred within a few Myr of formation of the earliest solids in the Solar System. Evidence from oxygen isotope compositions and siderophile element contents favor a model of extensive melting of Vesta forming a global magma ocean that rapidly (period of a few Myr) segregated and crystallized to yield a metallic core, olivine-rich mantle, orthopyroxene-rich lower crust and basaltic upper crust. The igneous lithologies were subjected to post-crystallization thermal processing, and most eucrites show textural and mineral-compositional evidence for metamorphism. The cause of this common metamorphism is unclear, but may have resulted from rapid burial of early basalts by later flows caused by high effusion rates on Vesta. The observed surface of Vesta is covered by fragmental debris resulting from impacts, and most HEDs are brecciated. Many eucrites and diogenites are monomict breccias indicating a lack of mixing. However, many HEDs are polymict breccias. Howardites are the most thoroughly mixed polymict breccias, yet only some of them contain evidence for residence in the true regolith. Based on the numbers of meteorites, compositions of howardites, and models of magma ocean solidification, cumulate eucrites and their residual ferroan mafic melts are minor components of the vestan crust. [ABSTRACT FROM AUTHOR]

Published

2015

11. Composition and petrology of HED polymict breccias: The regolith of (4) Vesta.

Author

Mittlefehldt, David W., Herrin, Jason S., Quinn, Julie E., Mertzman, Stanley A., Cartwright, Julia A., Mertzman, Karen R., and Peng, Zhan X.

Subjects

*PETROLOGY, *REGOLITH, *NOBLE gases, *METEORITES, *PYROXENE, *VESTA (Asteroid)

Abstract

We have done petrologic and compositional studies on a suite of polymict eucrites and howardites to better understand regolith processes on their parent asteroid, which we accept is (4) Vesta. Taking into account noble gas results from companion studies, we interpret five howardites to represent breccias assembled from the true regolith: Elephant Moraine ( EET) 87513, Grosvenor Mountains ( GRO) 95535, GRO 95602, Lewis Cliff ( LEW) 85313, and Meteorite Hills ( MET) 00423. We suggest that EET 87503 is paired with EET 87513, and thus is also regolithic. Pecora Escarpment ( PCA) 02066 is dominated by melt-matrix clasts, which may have been formed from true regolith by impact melting. These meteorites display a range in eucrite:diogenite mixing ratio from 55:45 to 76:24. There is no correlation between degree of regolith character and Ni content. The Ni contents of howardite, eucrite, and diogenites ( HEDs) are mostly controlled by the distribution of coarse chondritic clasts and metal grains, which in some cases resulted from individual, low-velocity accretion events, rather than extensive regolith gardening. Trace element compositions indicate that the mafic component of HED polymict breccias is mostly basalt similar to main-group eucrites; Stannern-trend basaltic debris is less common. Pyroxene compositions show that some trace element-rich howardites contain abundant debris from evolved basalts, and that cumulate gabbro debris is present in some breccias. The scale of heterogeneity varies considerably; regolithic howardite EET 87513 is more homogeneous than fragmental howardite Queen Alexandra Range ( QUE) 97001. Individual samples of a given howardite can have different compositions even at roughly 5 g masses, indicating that obtaining representative meteorite compositions requires multiple or large samples. [ABSTRACT FROM AUTHOR]

Published

2013

12. Compositional constraints on the genesis of diogenites.

Author

MITTLEFEHLDT, David W., BECK, Andrew W., LEE, Cin-Ty A., McSWEEN, Harry Y., and BUCHANAN, Paul C.

Subjects

*PETROLOGY, *METEORITES, *TRACE elements, *PHOSPHATES, *PLAGIOCLASE, *BASALT, *SIDEROPHILE elements

Abstract

- We have done bulk rock compositional analyses (INAA, ICP-MS) and petrologic study of a suite of diogenite meteorites. Most contain orthopyroxenes with mg#s of 70.6-79.0. Meteorite Hills (MET) 00425 is magnesian (mg# of 83.9). Lewis Cliff (LEW) 88011 contains orthopyroxene grains of varying mg# (76.3-68.6). Queen Alexandra Range (QUE) 93009 (orthopyroxene mg# 70.6) contains coarse-grained noritic clasts (plagioclase An84.7-88.3), and is rich in incompatible trace elements. It has Eu/Eu* < 1, indicating that cumulate norites do not dominate its trace element inventory. Queen Alexandra Range 93009 may be transitional between diogenites and magnesian cumulate eucrites. Lewis Cliff 88679, a dimict breccia of harzburgite and orthopyroxenite, has anomalously low concentrations of highly incompatible elements (e.g., Nb, La, Ta, U) compared to other diogenites, but is similar to them in less highly incompatible elements (e.g., Y, Zr, Yb, Hf). It is unlikely that this characteristic reflects a low proportion of a trapped melt component. The highly incompatible elements were likely mobilized after impact mixing of the two parent lithologies. Graves Nunataks 98108 shows an extreme range in Eu/Eu* attributable to the heterogeneous distribution of plagioclase; one sample has the lowest Eu/Eu* among diogenites. We find no compelling evidence to support the hypothesis that diogenite parent magmas were contaminated by partial melts of the eucritic crust. We posit that subsolidus equilibration between orthopyroxene and minor/trace phases (including phosphates) resulted in preferential redistribution of Eu2+ relative to Eu3+ and other rare earth elements, and results in anomalously low Eu/Eu* in samples leached in acids that dissolve phosphates. [ABSTRACT FROM AUTHOR]

Published

2012

13. MIL 03443, a dunite from asteroid 4 Vesta: Evidence for its classification and cumulate origin.

Author

BECK, Andrew W., MITTLEFEHLDT, David W., McSWEEN Jr, Harry Y., RUMBLE III, Douglas, LEE, Cin-Ty A., and BODNAR, Robert J.

Subjects

*ASTEROIDS, *DUNITE, *OLIVINE, *METEORITES, *PETROLOGY, *VESTA (Asteroid)

Abstract

- The absence of dunite (>90 vol% olivine) in the howardite, eucrite, and diogenite (HED) meteorite suite, when viewed with respect to spectroscopic and petrologic evidence for olivine on Vesta, is problematic. Herein, we present petrologic, geochemical, and isotopic evidence confirming that Miller Range (MIL) 03443, containing 91 vol% olivine, should be classified with the HED clan rather than with mesosiderites. Similarities in olivine and pyroxene FeO/MnO ratios, mineral compositions, and unusual mineral inclusions between MIL 03443 and the diogenites support their formation on a common parent body. This hypothesis is bolstered by oxygen isotopic and bulk geochemical data. Beyond evidence for its reclassification, we present observations and interpretations that MIL 03443 is probably a crustal cumulate rock like the diogenites, rather than a sample of the Vestan mantle. [ABSTRACT FROM AUTHOR]

Published

2011

14. Thermal and fragmentation history of ureilitic asteroids: Insights from the Almahata Sitta fall.

Author

HERRIN, Jason S., ZOLENSKY, Michael E., ITO, Motoo, LE, Loan, MITTLEFEHLDT, David W., JENNISKENS, Peter, ROSS, Aidan J., and SHADDAD, Muawia H.

Subjects

METEORITES, ASTEROIDS, OLIVINE, AUGITE, SCANNING electron microscopy, ELECTRON probe microanalysis

Abstract

- The Almahata Sitta fall event provides a unique opportunity to gain insight into the nature of ureilitic objects in space and the delivery of ureilite meteorites to Earth. From thermal events recorded in the mineralogy, petrology, and chemistry of ureilites recovered from the fall area, we reconstruct a timeline of events that led to their genesis. This history is similar to that of other known ureilites and supportive of a disrupted ureilite parent body hypothesis. Temperatures of final mantle equilibrium were 1200-1300 °C, but this high-temperature history was abruptly terminated by rapid cooling and reduction associated with pressure loss. The onset of late reduction reactions and onset of rapid cooling must have been essentially simultaneous, most likely engendered by the same event. Cooling rates of 0.05-2 °C h−1 determined from reversely zoned olivines and pyroxenes in Almahata Sitta imply rapid disassembly into fragments tens meters in size or smaller. This phenomenon seems to have affected all known portions of the ureilite parent body mantle, implying an event of global significance rather than localized unroofing. Reaccretion of one or more daughter asteroids occurred only after significant heat loss at minimum time scales of weeks to months, during which time the debris cloud surrounding the disrupted parent was inefficient at retaining heat. Fragments initially dislodged from the ureilite parent body mantle underwent subsequent size reduction and mixed with various chondritic bodies, giving rise to polylithologic aggregate objects such as asteroid 2008 TC3. [ABSTRACT FROM AUTHOR]

Published

2010

15. The Kaidun chondrite breccia: Petrology, oxygen isotopes, and trace element abundances

Author

MacPherson, Glenn J., Mittlefehldt, David W., Lipschutz, Michael E., Clayton, Robert N., Bullock, Emma S., Ivanov, Andrei V., Mayeda, Toshiko K., and Wang, Ming-Sheng

Subjects

*CHONDRITES, *PETROLOGY, *OXYGEN isotopes, *COSMIC abundances, *TRACE elements, *BRECCIA, *METEORITES, *PHYLLOSILICATES

Abstract

Abstract: Oxygen isotope and trace element data for 13 samples of the Kaidun chondritic breccia reaffirm the complex polymict nature of this unique meteorite. Bulk Kaidun samples most closely resemble CR chondrites, but the matrix is CI-like. Two separated clasts are CR-like but have some properties that resemble CM, two clasts are enstatite chondrites (one EL and one EH), one clast is an aubrite-like metal-rich impact melt, and one clast is a unique layered olivine-bearing pyroxenite with the isotopic composition of an aubrite. Yet, although each clast resembles a known meteorite group, all deviate in some respect from the norms for those groups. Collectively, Kaidun has sampled materials not yet represented in the world meteorite collections and which greatly extend the definitions of known meteorite groups. Phyllosilicates in Kaidun span a very wide range in composition and vary from clast to clast, suggesting that the aqueous alteration experienced by the clasts predated assembly of the Kaidun parent body. [Copyright &y& Elsevier]

Published

2009

16. Evidence from polymict ureilite meteorites for a disrupted and re-accreted single ureilite parent asteroid gardened by several distinct impactors

Author

Downes, Hilary, Mittlefehldt, David W., Kita, Noriko T., and Valley, John W.

Subjects

*METEORITES, *OXYGEN isotopes, *ECOLOGICAL heterogeneity, *MICROPROBE analysis, *ASTEROIDS, *SILICATE minerals, *PYROXENE, *SECONDARY ion mass spectrometry

Abstract

Abstract: Ureilites are ultramafic achondrites that exhibit heterogeneity in mg# and oxygen isotope ratios between different meteorites. Polymict ureilites represent near-surface material of the ureilite parent asteroid(s). Electron microprobe analyses of >500 olivine and pyroxene clasts in several polymict ureilites reveal a statistically identical range of compositions to that shown by unbrecciated ureilites, suggesting derivation from a single parent asteroid. Many ureilitic clasts have identical compositions to the anomalously high Mn/Mg olivines and pyroxenes from the Hughes 009 unbrecciated ureilite (here termed the “Hughes cluster”). Some polymict samples also contain lithic clasts derived from oxidized impactors. The presence of several common distinctive lithologies within polymict ureilites is additional evidence that ureilites were derived from a single parent asteroid. In situ oxygen three isotope analyses were made on individual ureilite minerals and lithic clasts, using a secondary ion mass spectrometer (SIMS) with precision typically better than 0.2–0.4‰ (2SD) for δ18O and δ17O. Oxygen isotope ratios of ureilitic clasts fall on a narrow trend along the CCAM line, covering the range for unbrecciated ureilites, and show a good anti-correlation with mineral mg#. SIMS analysis identifies one ferroan lithic clast as an R-chondrite, while a second ferroan clast is unlike any known meteorite. An exotic enstatite grain is derived from an enstatite chondrite or aubrite, and another pyroxene grain with Δ17O of −0.4±0.2‰ is unrelated to any known meteorite type. Ureilitic olivine clasts with mg#s<85 are much more common than those with mg#>85 which include the melt-inclusion-bearing “Hughes cluster” ureilites. Thus melt was present in regions of the parent ureilite asteroid with a bulk mg#>85 when the asteroid was disrupted by impact, giving rise to two types of ureilites: common ferroan ones that were residual after melting and less common magnesian ones that were still partially molten when disruption occurred. One or more daughter asteroids re-accreted from the remnants of the mantle of the proto-ureilite asteroid. Polymict ureilite meteorites represent regolith that subsequently formed on the surface of a daughter asteroid, including impact-derived material from at least six different meteoritic sources. [Copyright &y& Elsevier]

Published

2008

17. The origin of iron silicides in ureilite meteorites.

Author

Ross, Aidan J., Downes, Hilary, Herrin, Jason S., Mittlefehldt, David W., Humayun, Munir, and Smith, Caroline

Subjects

METEORITES, IRON meteorites, SILICIDES, LUNAR soil, SIDEROPHILE elements, ACHONDRITES, SPACE environment

Abstract

Ureilite meteorites contain iron silicide minerals including suessite (Fe,Ni) 3 Si, hapkeite (Fe 2 Si) and xifengite (Fe 5 Si 3). Despite occurring mostly in brecciated varieties presumed to be derived from the regolith of the ureilite parent asteroid, suessite has also been confirmed in one lithology of a dimict ureilite (NWA 1241). In contrast, Si-bearing Fe-metals occur in both brecciated and unbrecciated ureilites, implying that they were formed throughout the ureilite parent asteroid. We examined major, minor and trace element data of Fe-metals in seven brecciated ureilites (DaG 319, DaG 999, DaG 1000, DaG 1023, DaG 1047, EET 83309, and EET 87720) in addition to the dimict ureilite NWA 1241. In this study we show that the silicides and Si-bearing metals in ureilites have similar siderophile trace element patterns; therefore, the precursors to the silicides were indigenous to the ureilite parent body. Si-free kamacite grains in brecciated ureilites show flatter, more chondritic siderophile element patterns. They may also be derived from the interior of the ureilite parent body, but some may be of exogenous origin (impactor debris), as are rare taenite grains. On Earth, iron silicides are often formed under high-temperature and strongly reducing conditions (e.g. blast furnaces, lightning strikes). On the Moon, hapkeite (Fe 2 Si) and other silicides have been found in the regolith where they were formed by impact-induced space weathering. In the Stardust aerogel, iron silicides derived from comet Wild2 were also formed by an impact-related reduction process. Silicides in ureilite regolith breccias may have formed by similar processes but ureilites additionally contain abundant elemental carbon which probably acted as a reducing agent, thus larger and more abundant silicide grains were formed than in the lunar regolith or cometary material. The origin of suessite in NWA 1241 may be analogous to that of reduced lithologies in the terrestrial mantle, although a regolith origin may also be possible since this sample is shown here to be a dimict breccia. [ABSTRACT FROM AUTHOR]

Published

2019

18. Differentiation and magmatic history of Vesta: Constraints from HED meteorites and Dawn spacecraft data.

Author

McSween, Harry Y., Raymond, Carol A., Stolper, Edward M., Mittlefehldt, David W., Baker, Michael B., Lunning, Nicole G., Beck, Andrew W., and Hahn, Timothy M.

Subjects

SPACE vehicles, METEORITES, MAGMAS, MARTIAN meteorites, IGNEOUS intrusions, GRAVITY, ASTEROIDS, CRYSTALLIZATION

Abstract

Quantifying the amounts of various igneous lithologies in Vesta's crust allows the estimation of petrologic ratios that describe the asteroid's global differentiation and subsequent magmatic history. The eucrite:diogenite (Euc:Diog) ratio measures the relative proportions of mafic and ultramafic components. The intrusive:extrusive (I:E) ratio assesses the effectiveness of magma ascent and eruption. We estimate these ratios by counting numbers and masses of eucrites, cumulate eucrites, and diogenites in the world's meteorite collections, and by calculating their proportions as components of crustal polymict breccias (howardites) using chemical mixing diagrams and petrologic mapping of multiple thin sections. The latter two methods yield a Euc:Diog ratio of ∼2:1, although meteorite numbers and masses give slightly higher ratios. Surface lithologic maps compiled from spectra of Dawn spacecraft instruments (VIR and GRaND) yield Euc:Diog ratios that bracket estimates of Euc:Diog from the meteorites. The I:E ratios from HEDs lie between 0.5–2.1:1, due to uncertainties in identifying cumulate eucrite. Gravity mapping of Vesta by the Dawn spacecraft supports the existence of diogenite plutons in the crust. Quantifying the proportion of high-density diogenitic crust in the gravity map yields I:E ratios of 0.8-1:2:1, values which are bracketed by calculations based on HEDs. The I:E ratio for Vesta is lower than for Earth and Mars, consistent with physical modeling of asteroid-size bodies. Nevertheless, it indicates a significant role for pluton emplacement during the formation of Vesta's crust. These results are inconsistent with simple differentiation models that produce the crust by crystallization of a global magma ocean, unless residual melts are extracted into crustal magma chambers. [ABSTRACT FROM AUTHOR]

Published

2019

19. Martian meteorites: What are they telling us about Mars?

Author

Mittlefehldt, David W.

Subjects

*METEORITES, *MARS (Planet)

Abstract

Describes various meteorites from the planet Mars. Focus on the basalt EETA79001, which was found in Antarctica in 1979; Geologic history of Mars; Chemical and mineralogical characteristics of the Martian meteorites; Mars as one of the more plausible future habitats for humanity.

Published

1996

20. Spectral analysis of the bright materials on the asteroid Vesta.

Author

Zambon, F., De Sanctis, Maria Cristina, Schröder, Stefan, Tosi, Federico, Longobardo, Andrea, Ammannito, Eleonora, Blewett, David T., Mittlefehldt, David W., Li, Jian-Yang, Palomba, E., Capaccioni, Fabrizio, Frigeri, Alessandro, Capria, Maria Teresa, Fonte, Sergio, Nathues, Andreas, Pieters, Carle M., Russell, Christofer T., and Raymond, Carol A.

Subjects

*SPECTRUM analysis, *INFRARED absorption, *PYROXENE, *METEORITES, *PETROLOGY, *MINERALOGY, *VESTA (Asteroid)

Abstract

Vesta spectra have prominent near-infrared absorption bands characteristic of pyroxenes, indicating a direct link to the howardite, eucrite and diogenite meteorites. Many localized dark and bright materials are present on Vesta’s surface. Here we focus on the bright material (BM) units to determine their spectral properties, their origin, the presence of mineralogical phases different from pyroxenes, and whether different bright units share a common lithology. VIR, the Visible and Infrared spectrometer onboard Dawn, allows us to first do a detailed analysis of the spectral properties of a large number of bright material units on Vesta including examples of the different morphological classes. The spectral parameters used are band centers, band depths, and Band Area Ratio (BAR) for the pyroxene bands at ∼0.9 and ∼1.9 μm. The mineralogies of most bright regions are consistent with those of the howardite, eucrite and diogenite meteorites typical of Vesta’s surface. We find that bright material units exhibit the full range of HED pyroxene composition, from eucrites to diogenites. Large part of the bright materials are eucrite-rich, according with the Vesta’s mineralogy. In most cases, the bright materials have the same mineralogy of the surrounding terrain, but have larger band depth values. The band depths can be related to the abundance of the absorbing minerals, the abundance of Fe 2+ , grain size, and/or to the abundance of opaque materials. We found a positive correlation between albedo and band depth, which suggests that the grain size is not the main factor responsible for the higher albedo. The analysis of the band parameters indicates that most of the bright materials, excluding the few olivine-rich units, represent fresh uncontaminated Vestan pyroxenes from a variety of lithologies exposed from beneath the surface by impacts. [ABSTRACT FROM AUTHOR]

Published

2014