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Sołtmany/Abstract

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(74th Annual Meeting of the Meteoritical Society, Greenwich, London, UK)
 
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== 74th Annual Meeting of the Meteoritical Society, Greenwich, London, UK ==
== 74th Annual Meeting of the Meteoritical Society, Greenwich, London, UK ==
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[[Image:Soltmany_(poster_London2011).jpg|200px|thumb|74<sup>th</sup> Annual Meeting of the Meteoritical Society - poster prezentowany na konferencji przez Katarzynę Łuszczek (polska&nbsp;[[:Image:Soltmany_(poster_London2011)_PL.jpg|wersja]])]]
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[[Image:Soltmany_(poster_London2011).jpg|200px|thumb|74<sup>th</sup> Annual Meeting of the Meteoritical Society poster prezentowany na konferencji przez Katarzynę Łuszczek ({{Txt2Img|Soltmany_(poster_London2011)_PL.jpg|wersja}}&nbsp;polska)]]
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;A NEW METEORITE FALL AT SOŁTMANY, POLAND - [http://www.lpi.usra.edu/meetings/metsoc2011/pdf/5336.pdf abstract ]
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'''A NEW METEORITE FALL AT [[Sołtmany|SOŁTMANY]], POLAND''' – ({{!metsoc|n=74 |nabs=5336}})
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Ł. Karwowski<sup>1</sup>, A. S. Pilski<sup>2</sup>, T. A. Przylibski<sup>3</sup>, J. Gattacceca<sup>4</sup>, P. Rochette<sup>4</sup>, K. Łuszczek<sup>3</sup>, R. Kryza<sup>5</sup>, B. Woźniak, M. Woźniak<sup>6</sup>.
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Ł. Karwowski<sup>1</sup>, A.&nbsp;S.&nbsp;Pilski<sup>2</sup>, T.&nbsp;A.&nbsp;Przylibski<sup>3</sup>, J.&nbsp;Gattacceca<sup>4</sup>, P.&nbsp;Rochette<sup>4</sup>, K.&nbsp;Łuszczek<sup>3</sup>, R.&nbsp;Kryza<sup>5</sup>, B.&nbsp;Woźniak, M.&nbsp;Woźniak<sup>6</sup>.
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<p style="font-size:85%; line-height:160%"><sup>1</sup>University of Silesia, Faculty of Earth Sciences, ul. Będzińska 60, 41-200 Sosnowiec, Poland; <sup>2</sup>Nicolaus Copernicus Museum, ul. Katedralna 8, 14-530 Frombork, Poland; <sup>3</sup>Wrocław University of Technology, Faculty of Geoengineering, Mining and Geology, Wybrzeże S. Wyspiańskiego 27, 50-370 Wrocław, Poland; <sup>4</sup>CEREGE, Aix-Marseille Université, Aix-en-Provence, France; <sup>5</sup>Wrocław University, Institute of Geological Sciences, ul. Cybulskiego 30, 50-205 Wrocław, Poland; <sup>6</sup>University of Warsaw, Department of Biology, ul. Miecznikowa 1, 02-096 Warsaw, Poland.</p>
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<p style="font-size:85%; line-height:160%"><sup>1</sup>University of Silesia, Faculty of Earth Sciences, ul.&nbsp;Będzińska&nbsp;60, 41-200 Sosnowiec, Poland; <sup>2</sup>Nicolaus Copernicus Museum, ul.&nbsp;Katedralna&nbsp;8, 14-530 Frombork, Poland; <sup>3</sup>Wrocław University of Technology, Faculty of Geoengineering, Mining and Geology, Wybrzeże S.&nbsp;Wyspiańskiego&nbsp;27, 50-370 Wrocław, Poland; <sup>4</sup>CEREGE, Aix-Marseille Université, Aix-en-Provence, France; <sup>5</sup>Wrocław University, Institute of Geological Sciences, ul.&nbsp;Cybulskiego&nbsp;30, 50-205 Wrocław, Poland; <sup>6</sup>University of Warsaw, Department of Biology, ul.&nbsp;Miecznikowa&nbsp;1, 02-096 Warsaw, Poland.</p>
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'''Introduction:''' On April 30, 2011, at 6:03 CEST, in a farm at the village of [[Sołtmany]], NE Poland, a stone penetrated the [[:Plik:Sołtmany_(hole)_2.jpg|edge of a roof]] and crushed onto a [[:Plik:Sołtmany_(impact_point)_1.jpg|concrete step]] below. It was immediately found by the owners of the farm, alarmed by loud noise. Mr. Roman Rzepka from the nearby town of Giżycko, recognized the stone as meteoritic, and informed the authors. On May 2, fragments of the stone were purchased and distributed among laboratories for examination. Here are some preliminary results.
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'''Introduction:''' On April 30, 2011, at 6:03 CEST, in a&nbsp;farm at the village of [[Sołtmany]], NE Poland, a&nbsp;stone penetrated the {{Txt2Img|Sołtmany_(hole)_2.jpg|edge of a&nbsp;roof}} and crushed onto a&nbsp;{{Txt2Img|Sołtmany_(impact_point)_1.jpg|concrete step}} below. It was immediately found by the owners of the farm, alarmed by loud noise. Mr. Roman Rzepka from the nearby town of Giżycko, recognized the stone as meteoritic, and informed the authors. On May 2, fragments of the stone were purchased and distributed among laboratories for examination. Here are some preliminary results.
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'''Samples and macroscopic examination:''' The meteorite was broken by impact into pieces: [[Sołtmany/Galeria#Masa_główna|813 g]], 155 g and many smaller ones. TKW is at least 1066 g. Nearly all examined pieces have the fusion crust of about 1-1.5 mm thick. The crust is of the same thickness all around the meteorite, which suggests that the stone was a single fall. The hole in the roof and the trace of impact onto the step below proved that the fall was nearly vertical. Macroscopic examination showed that the stone was extremely fresh ([http://www.woreczko.pl/meteorites/features/glossary-Weathering.htm W0]), nearly white in color, with clearly visible troilite and FeNi grains, up to 2-3 mm in size, dispersed uniformly through entire meteorite. Only few [http://www.woreczko.pl/meteorites/features/glossary-Chondrules.htm chondrules] were distinguished macroscopically.
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'''Samples and macroscopic examination:''' The meteorite was broken by impact into pieces: [[Sołtmany/Galerie#Masa_główna|813&nbsp;g]], 155&nbsp;g and many smaller ones. TKW is at least 1066&nbsp;g. Nearly all examined pieces have the [http://www.woreczko.pl/meteorites/features/glossary-FusionCrust.htm fusion crust] of about 1-1.5&nbsp;mm thick. The crust is of the same thickness all around the meteorite, which suggests that the stone was a&nbsp;single fall. The hole in the roof and the trace of impact onto the step below proved that the fall was nearly vertical. Macroscopic examination showed that the stone was extremely fresh ([http://www.woreczko.pl/meteorites/features/glossary-Weathering.htm W0]), nearly white in color, with clearly visible troilite and FeNi grains, up to 2-3&nbsp;mm in size, dispersed uniformly through entire meteorite. Only few [http://www.woreczko.pl/meteorites/features/glossary-Chondrules.htm chondrules] were distinguished macroscopically.
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'''Mineralogy and petrology:''' The mean compositions of olivine (Fa<sub>25.5</sub>) and low-Ca pyroxene (Fs<sub>22</sub>) indicate that the meteorite can be classified as an [http://www.woreczko.pl/meteorites/features/glossary-Iron.htm L chondrite] [1]. This is confirmed by magnetic susceptibility [[:Image:LogX-bilan.gif|logχ = 4.71±0.04]], typical of the lower range of L chondrites [2]. The texture examined both macroscopically and in thin section, the homogeneous compositions of olivines and pyroxenes, and the large grain-size of plagioclase, all indicate type 6 chondrite. There is no difference in composition of [http://www.woreczko.pl/meteorites/features/Minerals/Silicates.htm olivines and pyroxenes] in chondrules and out of them. Low-Ca pyroxene is usually accompanied by Ca pyroxene (Wo: ~45%; Fs:~46.5%). In larger grains of feldspar (An ~10%; Or ~5%), albitic twinning is visible. Sparse chondrules are well crystallized; no glass is visible. F-Cl apatite is an accessory. Opaque minerals are represented by troilite, kamacite, taenite and rare chromite. Taenite shows an unusual texture, with areas resembling plessite. In taenite grains, tiny inclusions of metallic copper are visible. The undulatory extinction in olivine and pyroxene indicates that the chondrite is weakly shocked ([http://www.woreczko.pl/meteorites/features/glossary-ShockStage.htm S2]). This is confirmed by low anisotropy of magnetic susceptibility [3].
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'''Mineralogy and petrology:''' The mean compositions of olivine (Fa<sub>25.5</sub>) and low-Ca pyroxene (Fs<sub>22</sub>) indicate that the meteorite can be classified as an [http://www.woreczko.pl/meteorites/features/glossary-Iron.htm L chondrite]&nbsp;[1]. This is confirmed by magnetic susceptibility {{Txt2Img|LogX-bilan-syn-extended.jpg|logχ&nbsp;<nowiki>=</nowiki>&nbsp;4.71±0.04}}, typical of the lower range of L chondrites&nbsp;[2]. The texture examined both macroscopically and in thin section, the homogeneous compositions of olivines and pyroxenes, and the large grain-size of plagioclase, all indicate type 6 chondrite. There is no difference in composition of [http://www.woreczko.pl/meteorites/features/Minerals/Silicates.htm olivines and pyroxenes] in chondrules and out of them. Low-Ca pyroxene is usually accompanied by Ca pyroxene (Wo:&nbsp;~45%; Fs:&nbsp;~46.5%). In larger grains of feldspar (An&nbsp;~10%; Or&nbsp;~5%), albitic twinning is visible. Sparse chondrules are well crystallized; no glass is visible. F-Cl apatite is an accessory. Opaque minerals are represented by troilite, kamacite, taenite and rare chromite. Taenite shows an unusual texture, with areas resembling plessite. In taenite grains, tiny inclusions of metallic copper are visible. The undulatory extinction in olivine and pyroxene indicates that the chondrite is weakly shocked ([http://www.woreczko.pl/meteorites/features/glossary-ShockStage.htm S2]). This is confirmed by low anisotropy of magnetic susceptibility&nbsp;[3].
'''Acknowledgements:''' The authors are grateful to the finder of the meteorite, Mrs. Alfreda Lewandowska.
'''Acknowledgements:''' The authors are grateful to the finder of the meteorite, Mrs. Alfreda Lewandowska.
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'''References:''' <br>[1] Weisberg M. K. et al. 2006. In ''Meteorites and the Early Solar System II''. p.19-52. <br>[2] Rochette P. et al. 2003. ''Meteoritics & Planetary Science'' 38:[http://adsabs.harvard.edu/full/2003M&PS...38..251R 251-268]. <br>[3] Gattacceca J. et al. 2005. ''Earth and Planetary Science''. ''Letters''. 234:351-368.
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'''References:''' <br>[1] Weisberg M. K. et&nbsp;al. 2006. In ''[[:Szablon:Lauretta (2006)|Meteorites and the Early Solar System II]]''. [http://www.lpi.usra.edu/books/MESSII/9014.pdf p.19-52]. <br>[2] Rochette P. et&nbsp;al. 2003. ''Meteoritics & Planetary Science'' 38:{{!doi|10.1111/j.1945-5100.2003.tb00263.x|2=251-268}}. <br>[3] Gattacceca J. et&nbsp;al. 2005. ''Earth and Planetary Science''. ''Letters''. 234:{{!doi|10.1016/j.epsl.2005.03.002|2=351-368}}.
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Plik [[:File:Sołtmany_(abstract_London2011).jpg|abstrakt]]
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Plik {{Txt2Img|Sołtmany_(abstract_London2011).jpg|abstrakt}}

Aktualna wersja na dzień 23:24, 15 mar 2019

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74th Annual Meeting of the Meteoritical Society, Greenwich, London, UK

74th Annual Meeting of the Meteoritical Society – poster prezentowany na konferencji przez Katarzynę Łuszczek (wersja polska)


A NEW METEORITE FALL AT SOŁTMANY, POLAND – (74th Annual Meeting of the Meteoritical Society, London, UK, 2011. Abstract [#5336])

Ł. Karwowski1, A. S. Pilski2, T. A. Przylibski3, J. Gattacceca4, P. Rochette4, K. Łuszczek3, R. Kryza5, B. Woźniak, M. Woźniak6.

1University of Silesia, Faculty of Earth Sciences, ul. Będzińska 60, 41-200 Sosnowiec, Poland; 2Nicolaus Copernicus Museum, ul. Katedralna 8, 14-530 Frombork, Poland; 3Wrocław University of Technology, Faculty of Geoengineering, Mining and Geology, Wybrzeże S. Wyspiańskiego 27, 50-370 Wrocław, Poland; 4CEREGE, Aix-Marseille Université, Aix-en-Provence, France; 5Wrocław University, Institute of Geological Sciences, ul. Cybulskiego 30, 50-205 Wrocław, Poland; 6University of Warsaw, Department of Biology, ul. Miecznikowa 1, 02-096 Warsaw, Poland.


Introduction: On April 30, 2011, at 6:03 CEST, in a farm at the village of Sołtmany, NE Poland, a stone penetrated the edge of a roof and crushed onto a concrete step below. It was immediately found by the owners of the farm, alarmed by loud noise. Mr. Roman Rzepka from the nearby town of Giżycko, recognized the stone as meteoritic, and informed the authors. On May 2, fragments of the stone were purchased and distributed among laboratories for examination. Here are some preliminary results.

Samples and macroscopic examination: The meteorite was broken by impact into pieces: 813 g, 155 g and many smaller ones. TKW is at least 1066 g. Nearly all examined pieces have the fusion crust of about 1-1.5 mm thick. The crust is of the same thickness all around the meteorite, which suggests that the stone was a single fall. The hole in the roof and the trace of impact onto the step below proved that the fall was nearly vertical. Macroscopic examination showed that the stone was extremely fresh (W0), nearly white in color, with clearly visible troilite and FeNi grains, up to 2-3 mm in size, dispersed uniformly through entire meteorite. Only few chondrules were distinguished macroscopically.

Mineralogy and petrology: The mean compositions of olivine (Fa25.5) and low-Ca pyroxene (Fs22) indicate that the meteorite can be classified as an L chondrite [1]. This is confirmed by magnetic susceptibility logχ = 4.71±0.04, typical of the lower range of L chondrites [2]. The texture examined both macroscopically and in thin section, the homogeneous compositions of olivines and pyroxenes, and the large grain-size of plagioclase, all indicate type 6 chondrite. There is no difference in composition of olivines and pyroxenes in chondrules and out of them. Low-Ca pyroxene is usually accompanied by Ca pyroxene (Wo: ~45%; Fs: ~46.5%). In larger grains of feldspar (An ~10%; Or ~5%), albitic twinning is visible. Sparse chondrules are well crystallized; no glass is visible. F-Cl apatite is an accessory. Opaque minerals are represented by troilite, kamacite, taenite and rare chromite. Taenite shows an unusual texture, with areas resembling plessite. In taenite grains, tiny inclusions of metallic copper are visible. The undulatory extinction in olivine and pyroxene indicates that the chondrite is weakly shocked (S2). This is confirmed by low anisotropy of magnetic susceptibility [3].

Acknowledgements: The authors are grateful to the finder of the meteorite, Mrs. Alfreda Lewandowska.

References:
[1] Weisberg M. K. et al. 2006. In Meteorites and the Early Solar System II. p.19-52.
[2] Rochette P. et al. 2003. Meteoritics & Planetary Science 38:doi.
[3] Gattacceca J. et al. 2005. Earth and Planetary Science. Letters. 234:doi.

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