Your search keyword '"Mesosiderite"' showing total 17 results

1. The most primitive mesosiderite Northwest Africa 1878, subgroup 0

Author

Makoto Kimura, K. Ichimura, Akira Yamaguchi, and Naoji Sugiura

Subjects

Mesosiderite, Geophysics, Geography, Space and Planetary Science, Archaeology

Published

2020

2. Cosmogenic noble gas nuclides in zircons from the Estherville mesosiderite

Author

Keisuke Nagao and Makiko K. Haba

Subjects

Mesosiderite, Geophysics, Space and Planetary Science, Geochemistry, Nuclide, Noble gas (data page), Geology

Published

2021

3. 81Kr-Kr age and multiple cosmic-ray exposure history of the Vaca Muerta mesosiderite

Author

Keisuke Nagao and Ken ichi Bajo

Subjects

Radiochemistry, Geochemistry, Noble gas, Pyroxene, engineering.material, Silicate, Parent body, chemistry.chemical_compound, Mesosiderite, Geophysics, chemistry, Meteorite, Space and Planetary Science, engineering, Plagioclase, Pebble, Geology

Abstract

– Noble gas isotopic compositions were measured for a eucritic pebble and bulk material of a silicate–metal mixture from the Vaca Muerta mesosiderite as well as pyroxene and plagioclase separated from the eucritic pebble by total melting and stepwise heating methods. Trapped noble gases were degassed completely by a high-temperature thermal event, probably at the formation of the Vaca Muerta parent body (VMPB). The presence of fissiogenic Xe isotopes from extinct 244Pu in the bulk samples might be a result of rapid cooling from an early high-temperature metamorphism. High concentrations of cosmogenic noble gases enabled us to determine precise isotopic ratios of cosmogenic Kr and Xe. Spallogenic Ne from Na and unique Ar isotopic compositions were observed. The 81Kr-Kr exposure age of 168 ± 8 Myr for the silicate pebble is distinctly longer than the age of 139 ± 8 Myr for the bulk samples. The precursor of the pebble had been irradiated on the surface of the VMPB for more than 60 Myr (first stage irradiation), with subsequent incorporation into bulk materials approximately 4 Gyr ago. The Vaca Muerta meteorite was excavated from the VMPB 140 Myr ago (second stage irradiation). Relative diffusion rates among the cosmogenic Ar, Kr, and Xe based on data obtained by stepwise heating indicate that Kr and Xe can be partially retained in pyroxene and plagioclase under the condition that resets the K-Ar system. This result supports the presence of fission Xe and of excess concentration of cosmogenic Kr, which could have survived the thermal event approximately 3.8 Gyr ago.

Published

2011

4. Geochemistry and origin of metal, olivine clasts, and matrix in the Dong Ujimqin Qi mesosiderite

Author

Kejie Tao, Bernhard Spettel, Ping Kong, Wen Su, Herbert Palme, and Xian-Hua Li

Subjects

Stony-iron meteorite, Olivine, Fractional crystallization (geology), Geochemistry, Mineralogy, engineering.material, Parent body, Silicate, Mesosiderite, chemistry.chemical_compound, Geophysics, Meteorite, chemistry, Space and Planetary Science, Chondrite, engineering, Geology

Abstract

The Dong Ujimqin Qi mesosiderite is the first recorded fall of a stony-iron meteorite in China. According to silicate textures and metal composition, this meteorite is classified as a member of subgroup IB. Instrumental neutron activation analyses (INAA) of metals show that the matrix metal has lower concentrations of Os, Ir, Re, and Pt, but higher concentrations of Ni and Au than the 7.5 cm metal nodule present in the meteorite. We attribute these compositional differences to fractional crystallization of molten metal. Studies of olivine clasts show that FeO contents are uniform in individual olivine crystals but are variable for different olivine clasts. Although concentrations of rare earth elements (REEs) change within olivine clasts, they all exhibit a vee-shaped pattern relative to CI chondrites. The relatively high concentrations of REEs in olivine and the shape of REE patterns require a liquid high in REEs and especially in light REEs. As such a liquid was absent from the region where basaltic and gabbroic clasts formed, mesosiderite olivine must have formed in a part of the differentiated asteroid that is different from the location where other mesosiderite silicate clasts formed.

Published

2008

5. Petrology and geochemistry of a silicate clast from the Mount Padbury mesosiderite: Implications for metal-silicate mixing events of mesosiderite

Author

Mitsuru Ebihara, Akira Yamaguchi, Keiji Misawa, Minako Tamaki, and Hiroshi Takeda

Subjects

Mineral, Partial melting, Geochemistry, Pyroxene, engineering.material, Silicate, chemistry.chemical_compound, Mesosiderite, Geophysics, chemistry, Space and Planetary Science, Magma, engineering, Plagioclase, Petrology, Geology, Ilmenite

Abstract

Petrological and bulk geochemical studies were performed on a large silicate clast from the Mount Padbury mesosiderite. The silicate clast is composed mainly of pyroxene and plagioclase with minor amounts of ilmenite, spinel, and other accessory minerals, and it shows subophitic texture. Pyroxenes in the clast are similar to those in type 5 eucrites and could have experienced prolonged thermal metamorphism after rapid crystallization from a near-surface melt. Ilmenite and spinel vary chemically, indicating growth under disequilibrium conditions. The clast seems to have experienced an episode of rapid reheating and cooling, possibly as a result of metal-silicate mixing. Abundances of siderophile elements are obviously higher than in eucrites, although the clast is also extremely depleted in highly siderophile elements. The fractionated pattern can be explained by injection of Fe- FeS melts generated by partial melting of metallic portions during metal-silicate mixing. The silicate clast had a complex petrogenesis that could have included: 1) rapid crystallization from magma in a lava flow or a shallow intrusion; 2) prolonged thermal metamorphism to equilibrate the mineral compositions of pyroxene and plagioclase after primary crystallization; 3) metal-silicate mixing probably caused by the impact of solid metal bodies on the surface of the mesosiderite parent body; and 4) partial melting of metal and sulfide portions (and silicate in some cases) caused by the collisional heating, which produced Fe-FeS melts with highly fractionated siderophile elements that were injected into silicate portions along cracks and fractures.

Published

2006

6. An anomalous eucrite, Dhofar 007, and a possible genetic relationship with mesosiderites

Author

Mitsuru Ebihara, Akira Yamaguchi, and T. Setoyanagi

Subjects

Eucrite, Geochemistry, Pyroxene, engineering.material, Taenite, Mesosiderite, Geophysics, Augite, Space and Planetary Science, Breccia, Pigeonite, engineering, Achondrite, Geology

Abstract

We studied the texture, mineralogy, and bulk chemical composition of Dhofar 007, a basaltic achondrite. Dhofar 007 is a polymict breccia that is mostly composed of coarse-grained granular (CG) clasts with a minor amount of xenolithic components, such as a fragment of Mg-rich pyroxene. The coarse-grained, relict gabbroic texture, mineral chemistry, and bulk chemical data of the coarse-grained clast indicate that the CG clasts were originally a cumulate rock crystallized in a crust of the parent body. However, in contrast to monomict eucrites, the siderophile elements are highly enriched and could have been introduced by impact events. Dhofar 007 appears to have experienced a two-stage postcrystallization thermal history: rapid cooling at high temperatures and slow cooling at lower temperatures. The presence of pigeonite with closely spaced, fine augite lamellae suggests that this rock was cooled rapidly from higher temperatures (>0.5 °C/yr at ~1000 °C) than typical cumulate eucrites. However, the presence of the cloudy zone in taenite and the Ni profile across the kamacite-taenite boundaries indicates that the cooling rate was very slow at lower temperatures (~1-10 °C/Myr at

Published

2006

7. Ibitira: A basaltic achondrite from a distinct parent asteroid and implications for the Dawn mission

Author

David W. Mittlefehldt

Subjects

Eucrite, Basalt, Mesosiderite, Geophysics, Meteorite, Space and Planetary Science, Asteroid, Geochemistry, Crust, Achondrite, Isotopic composition, Geology, Astrobiology

Abstract

I have done a detailed petrologic study of Ibitira, a meteorite that has been classified as a basaltic eucrite since 1957. The mean Fe/Mn ratio of pyroxenes in Ibitira with

Published

2005

8. A 'mesosiderite' rock from northern Siberia, Russia: Not a meteorite

Author

Allan H. Treiman, Matthew L. Morgan, David J. Lindstrom, Ian A. Franchi, and Craig S. Schwandt

Subjects

Basalt, Mineral, Geochemistry, Taenite, Cohenite, Kamacite, Mesosiderite, chemistry.chemical_compound, Geophysics, chemistry, Meteorite, Space and Planetary Science, Cosmogenic nuclide, Geology

Abstract

A possible mesosiderite meteorite was found in the area of the Putorana Plateau, Noril'sk district, Siberia, Russia. Although this rock resembles a mesosiderite in its hand-sample aspect and in having Ni-bearing iron metal, it is not a meteorite. This inference is based on the lack of a fusion crust, the lack of cosmogenic nuclides, oxygen with terrestrial isotope ratios, and several mineral chemical criteria. Most likely, the rock is from the iron-metal-bearing basalts of the Siberian Trap basalt sequence, which are mined for their base and platinum-group metals. Mesosiderite imposters like this may be recognized by: (1) the presence of Cu metal in hand sample or as microscopic blebs in the low-Ni metal (kamacite), (2) the absence of high-Ni metal (taenite), and (3) the presence of iron carbide (cohenite) enclosing the kamacite. Even if these macroscopic tests are inconclusive, isotopic and mineral chemical tests will also distinguish rocks like this from mesosiderites.

Published

2002

9. The Meteoritical Bulletin, No. 86, 2002 July

Author

Jeffrey N. Grossman, Sara S. Russell, Jutta Zipfel, and Monica M. Grady

Subjects

Martian, Mesosiderite, Geophysics, Meteorite, Space and Planetary Science, Chondrite, Enstatite, engineering, Geochemistry, engineering.material, Achondrite, Geology

Abstract

— Meteoritical Bulletin No. 86 lists information for 1154 newly classified meteorites, comprising 661 from Antarctica, 218 from Africa, 207 from Asia (203 of which are from Oman), 62 from North America, 3 from South America, and 3 from Europe. Information is provided for 5 falls (El Idrissia, Undulung, Dashoguz, El Tigre, and Yafa). Noteworthy specimens include 7 martian meteorites (Dhofar 378, Grove Mountains 99027, Northwest Africa 856, 1068, and 1110, and Sayh al Uhaymir 060 and 090); 4 lunar meteorites (Dhofar 301, 302, 303, and 489); 9 new iron meteorites; a mesosiderite (Northwest Africa 1242); an ungrouped stony-iron meteorite (Dar al Gani 962); and a wide variety of other interesting stony meteorites, including CH, CK, CM, CR, CV, R, enstatite, unequilibrated ordinary, and ungrouped chondrites, primitive achondrites, howardite-eucrite-diogenite (HED) achondrites, and ureilites.

Published

2002

10. Formation of mesosiderites by fragmentation and reaccretion of a large differentiated asteroid

Author

Stanley G. Love, Henning Haack, and Edward Scott

Subjects

Olivine, Crust, engineering.material, Debris, Mantle (geology), Astrobiology, Mesosiderite, Geophysics, Meteorite, Space and Planetary Science, Asteroid, engineering, Ejecta, Geology

Abstract

— We propose that mesosiderites formed when a 200–400 km diameter asteroid with a molten core was disrupted by a 50–150 km diameter projectile. To test whether impacts can excavate core iron and mix it with crustal material, we used a low-resolution, smoothed-particle hydrodynamics computer simulation. For 50–300 km diameter differentiated targets, we found that significant proportions of scrambled core material (and hence potential mesosiderite metal material) could be generated. For near-catastrophic impacts that reduce the target to 80% of its original diameter and about half of its original mass, the proportion of scrambled core material would be about 5 vol%, equivalent to ∼10 vol% of mesosiderite-like material. The paucity of olivine in mesosiderites and the lack of metal-poor or troilite-rich meteorites from the mesosiderite body probably reflect biased sampling. Mesosiderites may be olivine-poor because mantle material was preferentially excluded from the metal-rich regions of the reaccreted body. Molten metal globules probably crystallized around small, cool fragments of crust hindering migration of metal to the core. If mantle fragments were much hotter and larger than crustal fragments, little metal would have crystallized around the mantle fragments allowing olivine and molten metal to separate gravitationally. The rapid cooling rates of mesosiderites above 850 °C can be attributed to local thermal equilibration between hot and cold ejecta. Very slow cooling below 400 °C probably reflects the large size of the body and the excellent thermal insulation provided by the reaccreted debris. We infer that our model is more plausible than an earlier model that invoked an impact at ∼1 km/s to mix projectile metal with target silicates. If large impacts cannot effectively strip mantles from asteroidal cores, as we infer, we should expect few large eroded asteroids to have surfaces composed purely of mantle or core material. This may help to explain why relatively few olivine-rich (A-type) and metal-rich asteroids (M-type) are known. Some S-type asteroids may be scrambled differentiated bodies.

Published

2001

11. Exposure age, terrestrial age and pre-atmospheric radius of the Chinguetti mesosiderite: Not part of a much larger mass

Author

Marc W. Caffee, A. J. T. Jull, Monica M. Grady, Ludolf Schultz, Jozef Masarik, Kees C. Welten, H. W. Weber, Philip A. Bland, and Sara S. Russell

Subjects

Mesosiderite, Radionuclide, Geophysics, Meteorite, Space and Planetary Science, Exposure age, Small fragment, Radius, Astrophysics, Parent body, Geology

Abstract

We measured the concentrations of the cosmogenic radionuclides 14C (half-life = 5.73 × 103 years) in the bulk and of 10Be (1.5 × 106 years), 26Al (7.05 × 105 years), 36Cl (3.01 × 105 years) and the light noble gases in metal and stone fractions of the Chinguetti meteorite to investigate the controversial claim that the 4.5 kg mesosiderite is part of a much larger mass in the Mauritanian desert. Based on the 36Cl-36Ar, 10Be-21Ne and 26Al-21Ne pairs in the metal fraction, we derive an average cosmic-ray exposure age of 66 ± 7 million years (Ma). Chinguetti is now the third out of 20 mesosiderites with an exposure age between 60 and 70 Ma. This may be the first hint of a major impact on the parent body of the mesosiderites, which show ages ranging from 10–300 Ma (Terribilini et al., 2000). From the 14C-10Be pair we derive a terrestrial age of 18 ± 1 ka, which seems too recent to be consistent with the original description of the main mass having a heavily wind eroded base, overhung by the upper part of the meteorite. Finally, from the radionuclide concentrations in combination with Monte Carlo based calculations, we conclude that our sample of Chinguetti was irradiated at a depth of ~15 cm in an object not larger than 80 cm in radius. This is the most compelling evidence against the reports that the Chinguetti mesosiderite is a small fragment of a mass 100 m long and 40 m high.

Published

2001

12. Relationship between cooling rate and cooling age of a mineral: Theory and applications to meteorites

Author

Jibamitra Ganguly and Massimiliano Tirone

Subjects

Isochron, Mineralogy, engineering.material, Grain size, Mesosiderite, Geophysics, Meteorite, Space and Planetary Science, Chondrite, engineering, Plagioclase, Diffusion (business), Closure temperature, Geology

Abstract

— We reviewed here the recent development on the mathematical formulation of closure temperature of a cooling geochronological system, which permits direct retrieval of cooling rate from cooling age when the diffusion parameters, grain size and initial temperature are known. This formulation is used to show how the cooling rate can be retrieved by comparing the core and bulk age of a mineral determined by a single decay system. The cooling rates of seven H chondrites of the metamorphic types H4, H5 and H6 were retrieved from the available data on the Pb-Pb model ages of the phosphates and the diffusion kinetic data of Pb in apatite. The results are in excellent agreement with the metallographic cooling rates and show an inverse relation with the metamorphic grade of these chondrites. We also addressed the problem of ∼90 Ma younger Sm-Nd mineral isochron age, defined by orthopyroxene, phosphate and plagioclase, of the Morristown mesosiderite compared to the Pb-Pb age of the Estherville mesosiderite. It is shown that this younger age could have been a consequence of resetting during cooling instead of an “impulsive heating” event, as suggested earlier.

Published

2001

13. Light noble gases and cosmogenic radionuclides in Estherville, Budulan, and other mesosiderites: Implications for exposure histories and production rates

Author

F. Begemann, A. Albrecht, Gregory F. Herzog, Christoph Schnabel, Jacob Klein, Roy Middleton, H. W. Weber, S. Vogt, David Fink, and S. Xue

Subjects

chemistry.chemical_compound, Mesosiderite, Radionuclide, Geophysics, chemistry, Meteorite, Space and Planetary Science, Chondrite, Flux, Mineralogy, Noble gas, Iron meteorite, Silicate

Abstract

We report measurements of 26A1, loBe, 41Ca, and 36Cl in the silicate and metal phases of 11 mesosiderites, including several specimens each of Budulan and Estherville, of the brecciated meteorite Bencubbin, and of the iron meteorite Udei Station. Average production rate ratios (atodatom) for metal phase samples from Estherville and Budulan are 26AVlOBe = 0.77 f 0.02; 36CYlOBe = 5.3 f 0.2. For a larger set of meteorites that includes iron meteorites and other mesosiderites, we find 26AVloBe = 0.72 f 0.01 and 36CVlOBe = 4.5 f 0.2. The average 41Ca/36Cl production rate ratio is 1.10 f 0.04 for metal separates from Estherville and four small iron falls. The 41Ca activities in dpm/(kg Ca) of various silicate separates from Budulan and Estherville span nearly a factor of 4, from 1600, indicating preatmospheric radii of >30 cm. After allowance for composition, the activities of 26A1 and loge (dpmkg silicate) are similar to values measured in most ordinary chondrites and appear to depend only weakly on bulk Fe content. Unless shielding effects are larger than suggested by the 36Cl and 41Ca activities of the metal phases, matrix effects are unimportant for loge and minor for 26A1. Noble gas concentrations and isotopic abundances are reported for samples of Barea, Emery, Mincy, Morristown, and Marjalahti. New estimates of 36C1/36Ar exposure ages for the metal phases agree well with published values. Neon-2 1 production rates for mesosiderite silicates calculated from these ages and from measured 2lNe contents are consistently higher than predicted for L chondrites despite the fact that the mesosiderite silicates have lower Mg contents than L chondrites. We suggest that the elevation of the 2lNe production rate in mesosiderite silicates reflects a "matrix effect," that is, the influence of the higher Fe content of mesosiderites, which acts to enhance the flux of low-energy secondary particles and hence the 2lNe production from Mg. As lOBe production is relatively insensitive to this matrix effect, 10BePlNe ages give erroneously low production rates and high exposure ages. By coincidence, standard 22NePlNe based "shielding" corrections give fairly reliable 2lNe production rates in the mesosiderite silicates.

Published

2000

14. The Meteoritical Bulletin, No. 82, 1998 July

Author

Jeffrey N. Grossman

Subjects

Diogenite, Mesosiderite, Geophysics, Meteorite, Space and Planetary Science, Chondrite, Geochemistry, Lodranite, Geology, Astrobiology, Winonaite

Abstract

— Meteoritical Bulletin No. 82 lists information for 974 new meteorites, including 521 finds from Antarctica, 401 finds from the Sahara, 21 finds from the Nullarbor region of Australia, and 7 falls (Ban Rong Du, Burnwell, Fermo, Jalanash, Juancheng, Monahans (1998), and Silao). Many rare types of meteorites are reported: counting pairing groups as one, these include one CR chondrite, two CK chondrites, two CO chondrites, four CV chondrites, one CH chondrite or Bencubbin-like, six C2 (unclassified) chondrites, two EH chondrites, two EL chondrites, three R chondrites, thirty unequilibrated ordinary chondrites, one un-grouped chondrite, three eucrites, six howardites, one diogenite, eleven ureilites, nine iron meteorites, one mesosiderite, two brachinites, one lodranite, one winonaite, and two lunar meteorites (Dar al Gani 400 and EET 96008). All italicized abbreviations refer to addresses tabulated at the end of this document.

Published

1998

15. The metamorphic history of eucrites and eucrite-related meteorites and the case for late metamorphism

Author

Paul H. Benoit, Steven J. K. Symes, D. Glen Akridge, J. David Batchelor, and Derek W. G. Sears

Subjects

Diogenite, Eucrite, Mesosiderite, Geophysics, Meteorite, Space and Planetary Science, Howardite, Geochemistry, Ejecta blanket, Metamorphism, Geology, Parent body

Abstract

— We report induced thermoluminescence (TL) data for separates from three howardite, eucrite and diogenite (HED) meteorites and the Vaca Muerta mesosiderite. The results of thermal modeling of the surface of their parent body are also described. The TL sensitivities for matrix samples from the LEW 85300, 302 and 303 paired eucrites and the Bholghati howardite are lower than the TL sensitivities for the clasts, which is consistent with regolith working of the matrix in fairly mature regoliths. Within an isochemical series of HED meteorites, TL sensitivity reflects metamorphic intensity, but clast-to-clast variations in the TL sensitivities of the Vaca Muerta mesosiderite and clasts in the EET 87509, 513 and 531 paired howardite primarily reflect differences in mineralogy and petrology. Thermoluminescence peak temperatures indicate that all the components from the LEW 85300, 302 and 303 paired eucrites experienced a reheating event involving temperatures >800 °C, which is thought to have been due to impact heating, and therefore that the event was concurrent with or postdated brecciation. The Vaca Muerta clasts are essentially unmetamorphosed, but the induced TL data indicate that the remaining howardite, eucrite, dioenite and mesosiderite (HEDM) meteorites experienced metamorphism to a variety of intensities but involving temperatures 800 °C cause a change in TL peak temperature. Feldspars from a variety of terrestrial and extraterrestrial sources show this behavior, and x-ray diffraction and kinetic studies suggest that it is indirectly related to Al, Si disordering. Cooling rates are not consistent with autometamorphism following the initial igneous event or with heating by subsequent eruptions of lava onto the surface of the HED parent body. Instead, our thermal models suggest that the metamorphism occurred within a regolith ejecta blanket of up to a few kilometers thick, with different levels of metamorphism corresponding to different thicknesses of blanket, between essentially 0 and ∼2 km, rather than different burial depths in a regolith of uniform thickness. We argue that metamorphism occurred 3.9 Ga ago and was associated with the resetting of the Ar-Ar system for the HED meteorites.

Published

1997

16. The search for exsolved ferromagnesian olivines: A meteoritic survey

Author

Michail I. Petaev

Subjects

Olivine, Geochemistry, Pallasite, Mineralogy, Forsterite, engineering.material, Mesosiderite, Geophysics, Meteorite, Space and Planetary Science, Chondrite, engineering, Fayalite, Brachinite, Geology

Abstract

— Olivine grains from selected meteorites (the Springwater pallasite, the Lowicz mesosiderite, the ALH 84025 brachinite, the Krymka LL3 chondrite, and the Calcalong Creek lunar meteorite) and terrestrial rocks (San Carlos forsterite and Rockport fayalite) were studied by optical microscopy and high-precision electron microprobe analysis. Detailed microprobe traverses revealed regular igneous zoning in the Krymka and Calcalong Creek olivines. Traverses across the San Carlos forsterite grain are flat and display no chemical variations larger than the 2σ range of counting error (±0.2 mol% Fa). Traverses across olivine grains in the ALH 84025, Lowicz, and Springwater meteorites show regular patterns of periodic or wavy chemical variations well exceeding the 2σ uncertainty range. However, no lamellar structure was seen in backscattered electron images. It is suggested that the periodic chemical variations may be due to spinodal decomposition of primary, more or less homogeneous grains. I conclude that the absence of earlier reports of such variations simply means that olivine grains in equilibrated meteorites have not been examined closely enough to detect them.

Published

1996

17. Meteorites on Mars

Author

G. Joseph H. Mccall

Subjects

Mesosiderite, Geophysics, Meteorite, Space and Planetary Science, Mars Exploration Program, Geology, Astrobiology

Abstract

– The article by Fairen et al. (2011) is very interesting to me, as not only have I published, albeit very cursorily, on the occurrence of meteorites on Mars (McCall 2005, 2011, 2012; McCall et al. 2006), but I was the author (McCall 1965) of the description of the Mount Padbury mesosiderite cited by Schroder et al. (2010) in their description of the four stony meteorites also found by the Opportunity rover. I have given my reasons elsewhere for thinking these are not mesosiderites (McCall 2012), but are likely differentiated stony meteorites of a hitherto unknown type.

Published

2012