Andrzej S. Pilski scite author profile

Andrzej S. Pilski

4Publications

76Citation Statements Received

76Citation Statements Given

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Nicolaus Copernicus University

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The Zakłodzie enstatite meteorite: Mineralogy, petrology, origin, and classification

Przylibski

Zagożdżon

Kryza

et al. 2005

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Abstract-The Zak≥odzie meteorite was found in September 1998, about 40 km west of ZamoúÊ, in southeast Poland. Macroscopic and microscopic observations (in transmitted and reflected light), microprobe analyses, cathodoluminescence images, and X-ray diffraction data show that the meteorite is composed of clino-and orthoenstatite, two generations of feldspars, relict olivine (forsterite), a polymorph of SiO 2 (apparently cristobalite), and opaque minerals: Fe-Ni alloy (kamacite and taenite), troilite, schreibersite, graphite, and sulfide (Mg, Mn, Fe)S, which is probably keilite. The texture is fine-to inequigranular of cumulate type, locally intergranular. The MgS-FeS thermometer indicates that the sulfides crystallized at ∼580-600 ºC. Thus, the Zak≥odzie meteorite formed by the nearly complete melting of an enstatite chondrite protolith, probably at ∼4.4 Ga; the process was likely caused by the decay of the 26 Al nuclide in the planetesimal interior. The second stage of its evolution, which could have happened at ∼2.1 Ga, involved partial re-melting of most fusible components, probably due to collision with another body. The structure, composition, and origin of the meteorite and its relation to the parent rock indicate that Zak≥odzie may represent a primitive enstatite achondrite.

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Low‐Ir IAB irons from Morasko and other locations in central Europe: One fall, possibly distinct from IAB‐MG

Pilski

Wasson

Muszyński

et al. 2013

Meteorit & Planetary Scien

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Abstract-Differences in texture and discovery location prompted us to analyze 16 irons from Morasko; one from Seel€ asgen, known to have a similar composition; and a new mass found at Jankowo Dolne. These were analyzed in duplicate by instrumental neutronactivation analysis (INAA). The results show that all 18 samples have very similar compositions, distinct from all other IAB irons except Burgavli; we conclude that they are all from a single shower. Eight of the samples were from regions with large amounts of cohenite (but were largely free of inclusions) and six were from samples with very little cohenite; we could find no resolvable difference in composition between these sets, a fact that suggests that the C contents of the metal phases were similar in the two areas. Although Morasko has been classified into the IAB main group (IAB-MG), its Ir plots well outside the main group field on an Ir-Au diagram. We considered the possibility that the low Ir reflected contamination by a melt from a IAB region that ponded and experienced fractional crystallization; however, because Morasko has Pt, W, and Ga values that are the same as the highest values in IAB-MG, we rejected this model. We therefore conclude that Morasko formed from a different melt than the IAB-MG irons; the Morasko melt was produced by impact heating, but one or more of the main Ir carriers did not melt, leaving much of the Ir in the unmelted residue. Copper is the only element that shows resolvable differences among Morasko samples. Most (13 of 18) samples have 149 AE 4 lg g À1 Cu, but three have 213 AE 10 lg g À1

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Petrology of the Baszkówka L5 chondrite: A record of surface‐forming processes on the parent body

Przylibski

Pilski

Zagożdżon

et al. 2003

Meteorit & Planetary Scien

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Abstract-We review the petrology of Baszkówka, present new microprobe data on mineral constituents, and propose a model for surface properties of the parent body consistent with these data. The low shock index and high porosity of the Baszkówka L5 chondrite mean that considerable primary textural and petrographic detail is preserved, allowing insight into the structure and evolution of the parent body. This meteorite formed in a sedimentary environment resembling that in which pyroclastic rocks are deposited. The origin of the component chondrules, achondritic fragments (mostly olivine and pyroxene aggregates), chondritic-achondritic aggregates, and compound chondrules can be explained by invoking collision of 2 melted or partially melted planetesimals, each covered with a thin crust. This could have happened at an early stage in the evolution of the solar system, between 1 and 2 Myr after its origin. The collision resulted in the formation of a cloud containing products of earlier magmatic crystallization (chondrite and achondrite fragments) from which new chondrules were created. Particle collision in this cloud produced fragmented chondrules, chondritic-achondritic aggregates, and compound chondrules. Within this low-density medium, these particles were accreted on the surface of the larger of the planetesimals involved in the collision. The density of the medium was low enough to prevent grain-size sorting of the components but high enough to prevent the total loss of heat and to enable the welding of fragments on the surface of the body. The rock material was homogenized within the cloud and, in particular, within the zone close to the planetesimal surface. The hot material settled on the surface and became welded as molten or plastic metal, and sulfide components cemented the grains together. The process resembled the formation of welded ignimbrites. Once these processes on the planetesimal surface were completed, no subsequent recrystallization occurred. The high porosity of the Baszkówka chondrite indicates that the meteorite comes from a near-surface part of the parent body. Deeper parts of the planetesimal would have been more massive because of compaction.

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Mineralogy and petrology of two ordinary chondrites and their correlation with other meteorites

Owocki

Pilski²

2009

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Abstract. Two ordinary chondrites are compared and classified using transmitted and reflected light microscopy and electron microprobe analyses. Both meteorites were confiscated by the Polish Customs Service at the border with Belarus. The first meteorite (called in this paper Terespol-1) is a L/LL6 chondrite, its classification being supported by the equilibrated compositions of olivine and orthopyroxene and the presence of large recrystallized feldspars (< 150 mm). The specimen examined experienced weak shock metamorphism (S3) and moderate weathering (although metal in the inner part of the meteorite seems to be unaffected by oxidization). The other meteorite (called in this paper Terespol-2) is a LL6 chondrite which experienced weak shock metamorphism (S3) and is unaffected by weathering. The Terespol-2 meteorite shares its classification with the Dhofar 1401 chondrite but the lack of data prevents further correlation. Both meteorites have been correlated with known findings from the Meteoritical Bulletin database and an attempt is made to identify their place of origin (fall event). Results indicate that Terespol-1 is most closely related to the Dhofar 1316 chondrite and we suggest that both meteorites at least came from the same parent body.

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Andrzej S. Pilski

The Zakłodzie enstatite meteorite: Mineralogy, petrology, origin, and classification

Low‐Ir IAB irons from Morasko and other locations in central Europe: One fall, possibly distinct from IAB‐MG

Petrology of the Baszkówka L5 chondrite: A record of surface‐forming processes on the parent body

Mineralogy and petrology of two ordinary chondrites and their correlation with other meteorites

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