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Start Over Author "Brenker, Frank E" Publisher elsevier b.v.
12 results on '"Brenker, Frank E"'

5. Asteroidal processes recorded by polyphase deformation in a harzburgitic diogenite NWA 5480.

Author

Tkalcec, Beverley J. and Brenker, Frank E.

Subjects
*DEFORMATIONS (Mechanics), *MULTIPHASE flow, *METAMORPHISM (Geology), *STRUCTURAL geology, *METEORITES, *STRUCTURAL analysis (Engineering)
Abstract

Expectations regarding structural deformation of asteroidal meteorites have typically revolved around impact-induced shock metamorphism or the gravity-driven axial compression of cumulates at the base of magma chambers. Recent structural analyses, however, of several olivine-rich diogenites (harzburgites) reveal solid-state plastic deformation not attributable to either scenario and propose dynamic mantle movements in the parent body, assumed to be Vesta. In this study we examine the microstructures of pyroxene and olivine in the olivine-rich diogenite NWA 5480. Coarse-grained, poikilitic texture, exsolution lamellae and plastic deformation attest to polyphase deformation and a re-heating event, followed by relatively slow cooling. Observations suggest that impact events alone are insufficient to generate and sustain the thermal and deformation conditions required to achieve all of the observed features. The proposed dynamic mantle movements in the Vestan interior may offer a means of heat transport to the system to provide a thermal environment inducive to slow cooling as well as generate the incremental stress fields required for the polyphase plastic deformation observed in the olivine. [ABSTRACT FROM AUTHOR]

Published
2015
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7. In situ identification of a CAI candidate in 81P/Wild 2 cometary dust by confocal high resolution synchrotron X-ray fluorescence

Author

Schmitz, Sylvia, Brenker, Frank E., Schoonjans, Tom, Vekemans, Bart, Silversmit, Geert, Vincze, Laszlo, Burghammer, Manfred, and Riekel, Christian

Subjects
*COSMIC dust, *COMETS, *AEROGELS, *SPACE exploration, *PRINCIPAL components analysis, *SYNCHROTRON radiation, *OPTICAL resolution, *X-ray spectroscopy
Abstract

Abstract: We detected additional CAI-like material in STARDUST mission samples of comet 81P/Wild 2. Two highly refractory cometary dust fragments were identified in the impact track 110 [C2012, 0, 110, 0, 0] by applying high resolution synchrotron induced confocal and conventional XRF analysis (HR SR-XRF). The use of a polycapillary lens in front of the detector for confocal spectroscopy dramatically improves the fidelity of particle measurements by removing contribution from the surrounding aerogel. The high spatial resolution (300×300nm2; 300×1000nm2) obtained allowed the detailed non-destructive in situ (trapped in aerogel) study of impacted grains at the sub-μm level. For the two largest particles of the track, the terminal particle and a second particle along the impact track, Ca concentration is up to 30 times higher than CI and Ti is enriched by a factor of 2 compared to CI. High resolution (HR) SR-XRF mapping also reveals that the highest concentrations of Ca, Ti, Fe (and Ni) measured within each grain belongs to different areas of the respective maps which indicate that the particles are composed of several chemically diverse mineral phases. This is in agreement with the finding of a complex phase assemblage of highly refractory minerals in the first ever detected Stardust mission CAI grain “Inti” of Track 25. Principle component analysis (PCA) is a powerful tool for extracting the dominant mineral components and was applied to the two grains indicating that regions in the terminal particle and the second particle are consistent with anorthite or grossite and gehlenite, monticellite or Dmitryivanovite (CaAl2O4), respectively. Our new findings demonstrate that the HR SR-XRF with confocal geometry and PCA analysis is capable of identifying CAI-like fragments without the need to extract particles from the aerogel matrix which is a time-consuming, complex and destructive process. Furthermore, the detection of new CAI-like fragments in the coma dust of comet 81P/Wild 2 strengthens the observation that strong mixing effects and, therefore, mass transport before or during comet formation must have occurred at least up to the region where Kuiper Belt comets formed (∼30AU). [Copyright &y& Elsevier]

Published
2009
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8. Cation ordering in omphacite and effect on deformation mechanism and lattice preferred orientation (LPO)

Author

Brenker, Frank E., Prior, Dave J., and Müller, Wolfgang Friedrich

Subjects
*METAMORPHISM (Geology), *PETROLOGY
Abstract

We present microstructural data and lattice preferred orientations (LPOs) of omphacites from a suite of eclogites, from the Adula/Cima Lunga nappe (Central Alps). Our work shows a surprisingly strong correlation between the measured LPO and the ordering state of cations in omphacite. Estimates of deformation temperature from metamorphic petrology, together with measured omphacite compositions and LPOs, determine the field (ordering state), on the omphacite phase diagram, into which each sample falls. LPOs dominated by L-type and S-type signatures are developed in samples that fall in the P2/n field (ordered structure) and C2/c field (disordered structure), respectively.Dislocations with b=1/2〈−110〉 or b=[001] are observed in the transmission electron microscope (TEM) in all samples. The former change from a perfect dislocation in the C2/c structure to a partial in P2/n. Any movement of a partial dislocation requires the formation or growth of a stacking fault. Furthermore, in order to pass an obstacle a partial dislocation has to constrict to a unit dislocation. The energy to form a constriction is high in omphacite due to the large separation width. Thus, the activity of the b=1/2〈−110〉 dislocation is hindered in the P2/n structure relative to the C2/c structure, which change the balance between the two and might give rise to the different LPOs. [Copyright &y& Elsevier]

Published
2002
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9. Mineralogy, petrology, and oxygen isotopic composition of Northwest Africa 12379, metal-rich chondrite with affinity to ordinary chondrites.

Author

Jansen, Christian A., Brenker, Frank E., Zipfel, Jutta, Pack, Andreas, Labenne, Luc, Nagashima, Kazuhide, Krot, Alexander N., Bizzarro, Martin, and Schiller, Martin

Subjects
MINERALOGY, CHONDRULES, CHONDRITES, METEORITES, PETROLOGY, INCLUSIONS (Mineralogy & petrology), OXYGEN, SIDEROPHILE elements
Abstract

Northwest Africa (NWA) 12379 is a new metal-rich chondrite with unique characteristics distinguishing it from all previously described meteorites. It contains high Fe,Ni-metal content (∼ 70 vol.%) and completely lacks interchondrule matrix; these characteristics are typical only for metal-rich carbonaceous (CH and CB) and G chondrites. However, chondrule sizes (60 to 1200 μm; mean = 370 μm), their predominantly porphyritic textures, nearly equilibrated chemical compositions of chondrule olivines (Fa 18.1–28.3 , average Fa 24.9±3.2 , PMD = 12.8; Cr 2 O 3 = 0.03 ± 0.02 wt.%; FeO/MnO = 53.2 ± 6.5 (wt.-ratio); n = 28), less equilibrated compositions of low-Ca pyroxenes (Fs 3.2–18.7 Wo 0.2–4.5 ; average Fs 14.7±3.7 Wo 1.4±1.3 ; n = 20), oxygen-isotope compositions of chondrule olivine phenocrysts (Δ17O ∼ 0.2–1.4‰, average ∼ 0.8‰), and the presence of coarse-grained Ti-bearing chromite, Cl-apatite, and merrillite, all indicate affinity of NWA 12379 to unequilibrated (type 3.8) ordinary chondrites (OCs). Like most OCs, NWA 12379 experienced fluid-assisted thermal metamorphism that resulted in formation of secondary ferroan olivine (Fa 27) that replaces low-Ca pyroxene grains in chondrules and in inclusions in Fe,Ni-metal grains. Δ17O of the ferroan olivine (∼ 4‰) is similar to those of aqueously-formed fayalite in type 3 OCs, but its δ18O is significantly higher (15–19‰, average = 17‰ vs. 3―12‰, average = 8‰, respectively). We suggest classifying NWA 12379 as the ungrouped metal-rich chondrite with affinities of its non-metal fraction to unequilibrated OCs and speculate that it may have formed by a collision between an OC-like body and a metal-rich body and subsequently experienced fluid-assisted thermal metamorphism. Trace siderophile element abundances and isotopic compositions (e.g., Mo, Ni, Fe) of the NWA 12379 metal could help to constrain its origin. [ABSTRACT FROM AUTHOR]

Published
2019
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10. Fundamental parameter based quantification algorithm for confocal nano-X-ray fluorescence analysis

Author

Schoonjans, Tom, Silversmit, Geert, Vekemans, Bart, Schmitz, Sylvia, Burghammer, Manfred, Riekel, Christian, Brenker, Frank E., and Vincze, Laszlo

Subjects
*ALGORITHMS, *CONFOCAL fluorescence microscopy, *X-ray spectroscopy, *MONTE Carlo method, *COSMIC dust
Abstract

Abstract: A new method for the quantification of X-ray fluorescence (XRF) was derived based on the fundamental parameter method (FPM). The FPM equations were adapted to accommodate the special case of confocal nano-XRF, i.e. X-ray nano-beam excitation coupled with confocal detection, taking into account the special characteristics of the detector channel polycapillary. A thorough error estimation algorithm based on the Monte Carlo method was applied, producing a detailed analysis of the uncertainties of the quantification results. The new FPM algorithm was applied on confocal nano-XRF data obtained from cometary dust returned by NASA''s Stardust mission, recorded at beamline ID13 of the European Synchrotron Radiation Facility. [Copyright &y& Elsevier]

Published
2012
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11. NanoSIMS analysis and Auger electron spectroscopy of silicate and oxide stardust from the carbonaceous chondrite Acfer 094

Author

Vollmer, Christian, Hoppe, Peter, Stadermann, Frank J., Floss, Christine, and Brenker, Frank E.

Subjects
*CARBONACEOUS chondrites (Meteorites), *OXYGEN isotopes, *SCANNING Auger electron microscopy, *STOICHIOMETRY, *ASTRONOMICAL observations, *MOLECULAR clouds, *CLUSTERING of particles
Abstract

Abstract: We have detected 138 presolar silicate, 20 presolar oxide and three presolar complex grains within the carbonaceous chondrite Acfer 094 by NanoSIMS oxygen isotope mapping. These grains were further investigated by scanning electron microscopy (SEM) and Auger electron spectroscopy for morphological and chemical details and their distribution within the meteorite matrix. The three complex grains consist of Al-rich oxides (grossite and hibonite) attached to non-stoichiometric Si-rich silicates. Refractory Al-rich oxides therefore serve as seed nuclei for silicates to condense onto, which is proposed by condensation theory and astronomical observations. However, in the majority of presolar silicates we did not find any indications for large subgrains. Most of the grains (80%) belong to O isotope Group I (17O-enriched) and come from 1 to 2.5 asymptotic giant branch (AGB) stars of close-to-solar or slightly lower-than-solar metallicity. About 60% of these grains are irregular in shape; ∼40% display elliptical morphologies together with smooth, platy surfaces. Three grains with large 17O enrichments (17O/16O>3×10−3) have highly irregular shapes and are very small (<250nm); these grains may have formed in binary star systems or around higher mass () AGB stars. About 10% of the presolar silicates in this study can be assigned to the O isotope Group IV, which most likely originate from type II supernovae (SNeII). These grains are also generally smaller than 300nm and are often irregular in shape (88%), consistent with the SNII origin scenario. The presolar grains are generally evenly distributed within the matrix on an mm scale, although in one case a statistically significant clustering of five grains in one 10×10μm2 sized field is observed. This could be an important hint that the distribution of presolar material in the parental molecular cloud was heterogeneous on a very fine scale. The matrix-normalized abundance of silicate stardust in Acfer 094 is 163±14ppm, which is among the highest abundance of O-rich stardust in primitive meteorites. Oxide stardust comprises 26±6ppm of the matrix. Auger Nanoprobe measurements of 69 presolar silicates and oxides (30 on a quantitative, 39 on a qualitative basis) indicate that most of the grains are Fe-rich (Mg/(Mg+Fe) of 0.82 and lower), which is either due to non-equilibrium condensation, secondary alteration, or both. (Mg+Fe)/Si ratios of the silicates are mostly non-stoichiometric and scatter around pyroxene-like rather than olivine-like compositions, which is consistent with recent Auger and transmission electron microscopy observations and astrophysical predictions. Mg-rich grains (Mg/(Mg+Fe)>0.5) more likely exhibit elliptical, smooth surfaces (14 out of 18 grains), which is an indication that these grains have not been strongly altered since their circumstellar condensation. We identified only one grain similar to the “glass with embedded metal and sulfides” (GEMS) with a statistically significant sulfur content (>2–3at.%). It remains unclear why the typical high-sulfur GEMS grains are only found in interplanetary dust particles, but have not yet been unequivocally identified in primitive meteorites. [Copyright &y& Elsevier]

Published
2009
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12. Origin of SiO2-rich components in ordinary chondrites

Author

Hezel, Dominik C., Palme, Herbert, Nasdala, Lutz, and Brenker, Frank E.

Subjects
*SILICA, *CHONDRITES, *CHONDRULES, *SILICON compounds
Abstract

Abstract: Silica-rich objects are common minor components in ordinary chondrites (OC), occurring as fragments and as chondrules. Their typical paragenesis is orthopyroxene+SiO2 (with bulk SiO2 >65wt%) and occasionally with additional olivine and/or spinel. Individual silica-rich components (SRC) have previously been studied in various types of OCs, although there is only one comprehensive study of these objects by Brigham et al. [Brigham, C.A., Murrell, M.T., Yabuki, H., Ouyang, Z., El Goresy, A., 1986. Silica-bearing chondrules and clasts in ordinary chondrites. Geochim. Cosmochim. Acta 50, 1655–1666]. Several different explanations of how SRCs formed have been published. The main question is how silica-enrichment was achieved, because CI-chondritic atomic Mg/Si-ratio is 1.07 and as a consequence only olivine and pyroxene, but no free silica should be stable. There are two basic possibilities for the SiO2-enrichment: (1) a RedOx-mechanism or magmatic fractionation on the parent body and (2) fractional condensation or recycling of chondrule mesostasis in the solar nebula. To better constrain the origin of these objects, we measured major and rare earth elements in SRCs of various types of ordinary chondrites, and in addition, we studied silica polymorphism in these objects using an in situ micro-Raman technique. Bulk chondrule compositions define mixing lines between the compositions of olivine and pyroxene. The SRCs extend these lines to an SiO2 end member. In contrast, magmatic trends grossly deviate from these mixing lines. Concentrations of CaO, Al2O3, and REE in the pyroxenes of the SRCs are low (0.01 to 1×CI) and the CI-normalized REE-patterns are virtually flat, typical of bulk chondrules, but untypical of magmatic trends. We therefore conclude that SiO2-rich objects are not of magmatic origin. They are the result of fractional condensation in the solar nebula. The silica in SRCs occurs mainly as tridymite and sometimes as cristobalite or—in very rare cases—as quartz. Some SiO2-phases yielded a yet unknown micro-Raman spectrum, which we were unable to identify. The often chondrule-like shape of SRCs as well as the presence of high-temperature SiO2-polymorphs lead to the following model for the origin of SRCs: formation of SiO2-rich precursors in the solar nebula by fractional condensation, reheating to temperatures between 1140 and >1968K, thereby forming the SRCs,—probably during the chondrule-forming process—followed by rapid cooling. [Copyright &y& Elsevier]

Published
2006
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