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7 results on '"Uni K. Petersen"'

1. A review of the NE Atlantic conjugate margins based on seismic refraction data

Author

Thomas Funck, Uni K. Petersen, Wolfram Geissler, Ken McDermott, G. S. Kimbell, Ögmundur Erlendsson, and Sofie Gradmann

Subjects
Iceland plume, Underplating, Rift, Volcanic passive margin, 010504 meteorology & atmospheric sciences, Geology, Ocean Engineering, Crust, 010502 geochemistry & geophysics, 01 natural sciences, Paleontology, Oceanic crust, 14. Life underwater, Seismic refraction, Magmatic underplating, Geomorphology, 0105 earth and related environmental sciences, Water Science and Technology
Abstract

The NE Atlantic region evolved through several rift episodes, leading to break-up in the Eocene that was associated with voluminous magmatism along the conjugate margins of East Greenland and NW Europe. Existing seismic refraction data provide good constraints on the overall tectonic development of the margins, despite data gaps at the NE Greenland shear margin and the southern Jan Mayen microcontinent. The maximum thickness of the initial oceanic crust is 40 km at the Greenland–Iceland–Faroe Ridge, but decreases with increasing distance to the Iceland plume. High-velocity lower crust interpreted as magmatic underplating or sill intrusions is observed along most margins but disappears north of the East Greenland Ridge and the Lofoten margin, with the exception of the Vestbakken Volcanic Province at the SW Barents Sea margin. South of the narrow Lofoten margin, the European side is characterized by wide margins. The opposite trend is seen in Greenland, with a wide margin in the NE and narrow margins elsewhere. The thin crust beneath the basins is generally underlain by rocks with velocities of >7 km s−1 interpreted as serpentinized mantle in the Porcupine and southern Rockall basins; while off Norway, alternative interpretations such as eclogite bodies and underplating are also discussed.

Published
2016

2. Review of velocity models in the Faroe–Shetland Channel

Author

Thomas Funck and Uni K. Petersen

Subjects
Shetland, 010504 meteorology & atmospheric sciences, Geology, Ocean Engineering, Channel (broadcasting), 010502 geochemistry & geophysics, 01 natural sciences, Geomorphology, 0105 earth and related environmental sciences, Water Science and Technology
Published
2016

3. Moho and basement depth in the NE Atlantic Ocean based on seismic refraction data and receiver functions

Author

Wolfram Geissler, Thomas Funck, Ken McDermott, Ögmundur Erlendsson, Uni K. Petersen, Sofie Gradmann, and G. S. Kimbell

Subjects
geography, Iceland plume, geography.geographical_feature_category, Rift, 010504 meteorology & atmospheric sciences, Geology, Ocean Engineering, Structural basin, 010502 geochemistry & geophysics, 01 natural sciences, Basement (geology), Volcano, 13. Climate action, Ridge, Oceanic crust, 14. Life underwater, Seismic refraction, Seismology, 0105 earth and related environmental sciences, Water Science and Technology
Abstract

Seismic refraction data and results from receiver functions were used to compile the depth to the basement and Moho in the NE Atlantic Ocean. For interpolation between the unevenly spaced data points, the kriging technique was used. Free-air gravity data were used as constraints in the kriging process for the basement. That way, structures with little or no seismic coverage are still presented on the basement map, in particular the basins off East Greenland. The rift basins off NW Europe are mapped as a continuous zone with basement depths of between 5 and 15 km. Maximum basement depths off NE Greenland are 8 km, but these are probably underestimated. Plate reconstructions for Chron C24 (c. 54 Ma) suggest that the poorly known Ammassalik Basin off SE Greenland may correlate with the northern termination of the Hatton Basin at the conjugate margin. The most prominent feature on the Moho map is the Greenland–Iceland–Faroe Ridge, with Moho depths >28 km. Crustal thickness is compiled from the Moho and basement depths. The oceanic crust displays an increased thickness close to the volcanic margins affected by the Iceland plume.

Published
2016

4. P-wave velocity distribution in basalt flows of the Enni Formation in the Faroe Islands from refraction seismic analysis

Author

Uni K. Petersen, M. S. Andersen, and R. James Brown

Subjects
Geophysics, Geochemistry and Petrology, P wave, Geophone, Waveform, Tomography, Inverse problem, Geologic map, Geology, Smoothing, Seismology, Seismic analysis
Abstract

The main objective of this work is to establish the applicability of shallow surfaceseismic traveltime tomography in basalt-covered areas. A densely sampled ∼1300-m long surface seismic profile, acquired as part of the SeiFaBa project in 2003 (Japsen et al. 2006) at Glyvursnes in the Faroe Islands, served as the basis to evaluate the performance of the tomographic method in basalt-covered areas. The profile is centred at a ∼700-m deep well. VP, VS and density logs, a zero-offset VSP, downhole-geophone recordings and geological mapping in the area provided good means of control. TheinversionwasperformedwithfacilitiesoftheWideAngleReflection/Refraction Profiling program package (Ditmar et al. 1999). We tested many inversion sequences while varying the inversion parameters. Modelled traveltimes were verified by fullwaveform modelling. Typically an inversion sequence consists in several iterations that proceed until a satisfactory solution is reached. However, in the present case with high velocity contrasts in the subsurface we obtained the best result with two iterations: first obtaining a smooth starting model with small traveltime residuals by inverting with a high smoothing constraint and then inverting with the lowest possible smoothing constraint to allow the inversion to have the full benefit of the traveltime residuals. The tomogram gives usable velocity information for the near-surface geology in the area but fails to reproduce the expected velocity distribution of the layered basalt flows. Based on the analysis of the tomogram and geological mapping in the area, a model was defined that correctly models first arrivals from both surface seismic data and downhole-geophone data.

Published
2012

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