Imaging the East European Craton margin in northern Poland using extended correlation processing of regional seismic reflection profiles
<p>In NE Poland, Eastern European Craton (EEC) crust of Fennoscandian affinity is concealed under a Phanerozoic platform cover and penetrated by sparse, deep research wells. Most of the inferences regarding its structure rely on geophysical data. Until recently, this area was covered only by t...
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2019-05-01
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| Series: | Solid Earth |
| Online Access: | https://www.solid-earth.net/10/683/2019/se-10-683-2019.pdf |
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doaj-27bcac2ef24e40218be2d3d6ae22ae8c2020-11-25T01:55:51ZengCopernicus PublicationsSolid Earth1869-95101869-95292019-05-011068369610.5194/se-10-683-2019Imaging the East European Craton margin in northern Poland using extended correlation processing of regional seismic reflection profilesM. Mężyk0M. Malinowski1S. Mazur2Institute of Geophysics Polish Academy of Sciences, Warsaw, 01-452, PolandInstitute of Geophysics Polish Academy of Sciences, Warsaw, 01-452, PolandInstitute of Geological Sciences Polish Academy of Sciences, 00-818, Warsaw, Poland<p>In NE Poland, Eastern European Craton (EEC) crust of Fennoscandian affinity is concealed under a Phanerozoic platform cover and penetrated by sparse, deep research wells. Most of the inferences regarding its structure rely on geophysical data. Until recently, this area was covered only by the wide-angle reflection and refraction (WARR) profiles, which show a relatively simple crustal structure with a typical three-layer cratonic crust. ION Geophysical PolandSPAN<sup>™</sup> regional seismic programme data, acquired over the marginal part of the EEC in Poland, offered a unique opportunity to derive a detailed image of the deeper crust. Here, we apply extended correlation processing to a subset (<span class="inline-formula">∼950</span> km) of the PolandSPAN<sup>™</sup> dataset located in NE Poland, which enabled us to extend the nominal record length of the acquired data from 12 to 22 s (<span class="inline-formula">∼60</span> km of depth). Our new processing revealed reflectivity patterns, which we primarily associate with the Paleoproterozoic crust formed during the Svekofennian (Svekobaltic) orogeny, that are similar to those observed along the BABEL and FIRE profiles in the Baltic Sea and Finland, respectively. We propose a mid- to lower-crustal, orogeny-normal lateral flow model to explain the occurrence of two sets of structures that can be collectively interpreted as kilometre-scale S–C<span class="inline-formula"><sup>′</sup></span> shear zones. The structures define a penetrative deformation fabric invoking ductile extension of hot orogenic crust in a convergent setting. Localized reactivation of these structures provided conduits for subsequent emplacement of gabbroic magma that produced a Mesoproterozoic anorthosite–mangerite–charnockite–granite (AMCG) suite in NE Poland. Delamination of thickened orogenic lithosphere may have accounted for magmatic underplating and fractionation into the AMCG plutons. We also found sub-Moho dipping mantle reflectivity, which we tentatively explain as a signature of the crustal accretion during the Svekofennian orogeny. Later tectonic phases (e.g. Ediacaran rifting, Caledonian orogeny) did not leave a clear signature in the deeper crust; however, some of the subhorizontal reflectors below the basement, observed in the vicinity of the AMCG Mazury complex, can be alternatively linked with lower Carboniferous magmatism.</p>https://www.solid-earth.net/10/683/2019/se-10-683-2019.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
M. Mężyk M. Malinowski S. Mazur |
| spellingShingle |
M. Mężyk M. Malinowski S. Mazur Imaging the East European Craton margin in northern Poland using extended correlation processing of regional seismic reflection profiles Solid Earth |
| author_facet |
M. Mężyk M. Malinowski S. Mazur |
| author_sort |
M. Mężyk |
| title |
Imaging the East European Craton margin in northern Poland using extended correlation processing of regional seismic reflection profiles |
| title_short |
Imaging the East European Craton margin in northern Poland using extended correlation processing of regional seismic reflection profiles |
| title_full |
Imaging the East European Craton margin in northern Poland using extended correlation processing of regional seismic reflection profiles |
| title_fullStr |
Imaging the East European Craton margin in northern Poland using extended correlation processing of regional seismic reflection profiles |
| title_full_unstemmed |
Imaging the East European Craton margin in northern Poland using extended correlation processing of regional seismic reflection profiles |
| title_sort |
imaging the east european craton margin in northern poland using extended correlation processing of regional seismic reflection profiles |
| publisher |
Copernicus Publications |
| series |
Solid Earth |
| issn |
1869-9510 1869-9529 |
| publishDate |
2019-05-01 |
| description |
<p>In NE Poland, Eastern European Craton (EEC) crust of
Fennoscandian affinity is concealed under a Phanerozoic platform cover and
penetrated by sparse, deep research wells. Most of the inferences
regarding its structure rely on geophysical data. Until recently, this area
was covered only by the wide-angle reflection and refraction (WARR) profiles,
which show a relatively simple crustal structure with a typical three-layer
cratonic crust. ION Geophysical PolandSPAN<sup>™</sup> regional seismic
programme data, acquired over the marginal part of the EEC in Poland, offered
a unique opportunity to derive a detailed image of the deeper crust. Here,
we apply extended correlation processing to a subset (<span class="inline-formula">∼950</span> km) of the PolandSPAN<sup>™</sup> dataset located in NE Poland, which
enabled us to extend the nominal record length of the acquired data from 12
to 22 s (<span class="inline-formula">∼60</span> km of depth). Our new processing revealed
reflectivity patterns, which we primarily associate with the
Paleoproterozoic crust formed during the Svekofennian (Svekobaltic) orogeny,
that are similar to those observed along the BABEL and FIRE profiles in the
Baltic Sea and Finland, respectively. We propose a mid- to lower-crustal,
orogeny-normal lateral flow model to explain the occurrence of two sets of
structures that can be collectively interpreted as kilometre-scale S–C<span class="inline-formula"><sup>′</sup></span>
shear zones. The structures define a penetrative deformation fabric invoking
ductile extension of hot orogenic crust in a convergent setting. Localized
reactivation of these structures provided conduits for subsequent
emplacement of gabbroic magma that produced a Mesoproterozoic
anorthosite–mangerite–charnockite–granite (AMCG) suite in NE Poland.
Delamination of thickened orogenic lithosphere may have accounted for
magmatic underplating and fractionation into the AMCG plutons. We also found
sub-Moho dipping mantle reflectivity, which we tentatively explain as a
signature of the crustal accretion during the Svekofennian orogeny. Later
tectonic phases (e.g. Ediacaran rifting, Caledonian orogeny) did not leave a
clear signature in the deeper crust; however, some of the subhorizontal
reflectors below the basement, observed in the vicinity of the AMCG Mazury
complex, can be alternatively linked with lower Carboniferous magmatism.</p> |
| url |
https://www.solid-earth.net/10/683/2019/se-10-683-2019.pdf |
| work_keys_str_mv |
AT mmezyk imagingtheeasteuropeancratonmargininnorthernpolandusingextendedcorrelationprocessingofregionalseismicreflectionprofiles AT mmalinowski imagingtheeasteuropeancratonmargininnorthernpolandusingextendedcorrelationprocessingofregionalseismicreflectionprofiles AT smazur imagingtheeasteuropeancratonmargininnorthernpolandusingextendedcorrelationprocessingofregionalseismicreflectionprofiles |
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