Your search keyword '"Schlindwein, V"' showing total 3 results

1. Magmatic Activity and Dynamics of Melt Supply of Volcanic Centers of Ultraslow Spreading Ridges: Hints From Local Earthquake Tomography at the Knipovich Ridge

Author

Meier, M., Schlindwein, V., Schmid, F., 1 Alfred Wegener Institute Helmholtz Centre for Polar and Marine Research Bremerhaven Germany, and 4 Geomar Helmholtz Centre for Ocean Research Kiel Kiel Germany

Subjects

Geophysics, Knipovich Ridge, mid‐ocean ridge, Geochemistry and Petrology, ddc:551.22, seismicity, partial melt area, local earthquake tomography, ultraslow spreading, results, Seismic cycle related deformations, HYDROLOGY, Estimation and forecasting, INFORMATICS, Forecasting, IONOSPHERE, MAGNETOSPHERIC PHYSICS, MARINE GEOLOGY AND GEOPHYSICS, Midocean ridge processes, Plate tectonics, Submarine tectonics and volcanism, MATHEMATICAL GEOPHYSICS, Prediction, Probabilistic forecasting, OCEANOGRAPHY: GENERAL, Ocean predictability and prediction, NATURAL HAZARDS, Monitoring, forecasting, prediction, POLICY SCIENCES, RADIO SCIENCE, Interferometry, Ionospheric physics, Tomography and imaging, SEISMOLOGY, Seismicity and tectonics, Tomography, Continental crust, Earthquake dynamics, Earthquake source observations, Earthquake interaction, forecasting, and prediction, Subduction zones, SPACE WEATHER, Policy, TECTONOPHYSICS, Plate boundary: general, Plate motions: general, Plate motions: past, Plate motions: present and recent, Research Article, mid-ocean ridge, partial melt area [EXPLORATION GEOPHYSICS, Gravity methods, GEODESY AND GRAVITY, Transient deformation, Tectonic deformation, Time variable gravity, Gravity anomalies and Earth structure, Satellite geodesy], ddc

Abstract

Along ultraslow spreading ridges melt is distributed unequally, but melt focusing guides melt away from amagmatic segments toward volcanic centers. An interplay of tectonism and magmatism is thought to control melt ascent, but the detailed process of melt extraction is not yet understood. We present a detailed image of the seismic velocity structure of the Logachev volcanic center and adjacent region along the Knipovich Ridge. With travel times of P‐ and S‐waves of 3,959 earthquakes we performed a local earthquake tomography. We simultaneously inverted for source locations, velocity structure and the Vp/Vs‐ratio. An extensive low velocity anomaly coincident with high Vp/Vs‐ratios >1.9 lies underneath the volcanic center at depths of 10 km below sea level in an aseismic area. More shallow, tightly clustered earthquake swarms connect the anomaly to a shallow anomaly with high Vp/Vs‐ratio beneath the basaltic seafloor. We consider the deep low‐velocity anomaly to represent an area of partial melt from which melts ascent vertically to the surface and northwards into the adjacent segment. By comparing tomographic studies of the Logachev and Southwest Indian Ridge Segment‐8 volcano we conclude that volcanic centers of ultraslow spreading ridges host spatially confined, circular partial melt areas below 10 km depth, in contrast to the shallow extended melt lenses along fast spreading ridges. Lateral feeding over distances of 35 km is possible at orthogonal spreading segments, but limited at the obliquely spreading Knipovich Ridge., Plain Language Summary: Mid‐ocean ridges mark the tectonic plate boundaries, where the plates drift apart. Fresh magma rises into the gap and builds new seafloor. The slower the plates drift apart, the less magma is present underneath the ridge. At very slow spreading ridges there is not enough magma to build new seafloor along the entire length of the ridge. Rather, melt is guided toward individual volcanic centers spaced at about 100 km, where melt accumulates and ascents. In our study we try to find melt storage areas and ascent paths of such a volcanic center. With velocities of different seismic wave types from earthquakes we map the velocity structure of the area underneath the major Logachev volcanic center. Lower velocities indicate an area partly including melt at depths of more than 10 km, far deeper than at mid‐ocean ridges with sufficient melt supply. From the deep magma reservoir, many earthquake swarms map the long ascent path of melt to the surface. The interplay of magmatic and tectonic activity is important here. In a comparison with results from another volcanic center, we find that lateral magma feeding is possible in orthogonal spreading, but limited in oblique spreading, as at the Knipovich Ridge., Key Points: Active volcanic centers at ultraslow spreading ridges host deeper and more confined partial melt areas than faster spreading ridges. Earthquake swarms delineate melt ascent paths from the partial melt area to the surface. Lateral feeding at shallow depths into subordinate segments is prevented by ridge obliquity., Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659

Published

2021

2. Performance of localization algorithms for teleseismic mid-ocean ridge earthquakes: the 1999 Gakkel Ridge earthquake swarm and its geological interpretation.

Author

Korger, E. I. M. and Schlindwein, V.

Subjects

*SEISMIC waves, *SEISMIC wave velocity, *EARTHQUAKES, *SEISMOLOGY, *GEOPHYSICS, *ALGORITHMS

Abstract

SUMMARY In 1999, an unusual earthquake swarm at the 85°E/85°N volcanic centre on the ultraslow spreading Gakkel Ridge, Arctic Ocean, was detected teleseismically. The swarm lasted over 9 months and counted 252 events with mb≥ 3.1. It represents the strongest and largest ever recorded mid-ocean ridge earthquake swarm, and it occurred at a site where spreading rates are only about 10 mm yr-1. We relocated the earthquake swarm comparing the performance of three different localization algorithms: (1) the absolute least-squares routine HYPOSAT, (2) the absolute probabilistic routine NonLinLoc and (3) the relative least-squares routine Mlocate. The epicentres as calculated by each algorithm mostly did not agree within their error ellipses. Thus, the choice of location algorithm proved more critical than, for example, the choice of a local velocity model. We compiled a set of well-localized events which closely agree in at least two routines, mostly Mlocate and NonLinLoc. We conclude that the earthquake swarm of 1999 was related to a spreading episode and shows a complex interplay of tectonic and magmatic events. Our geological interpretation revealed three phases in swarm activity: In the first phase from January 17 up to February 1 fracturing of the crust took place, either as a result of or enabling magmatic intrusion. Seismicity in the second phase from February 2 to April 6 expanded along- and across axis. It showed signs of magmatic interaction, but a clear dyke migration pattern is absent. At the beginning of the third phase, a distinct break in the event rate suggested a change in the physical process, either an adjustment of the stress field to the new regime or a transition to an effusive stage. [ABSTRACT FROM AUTHOR]

Published

2012

3. Segmentation of the eastern North Greenland oblique-shear margin — Regional plate tectonic implications

Author

Døssing, A., Stemmerik, L., Dahl-Jensen, T., and Schlindwein, V.

Subjects

*PLATE tectonics, *CONTINENTAL margins, *SEDIMENTARY basins, *SEISMIC reflection method, *GEOPHYSICS, *CENOZOIC stratigraphic geology, *PALEOZOIC stratigraphic geology

Abstract

Abstract: Late Cenozoic opening of the Fram Strait led to formation of the NW–SE striking, eastern North Greenland oblique-shear margin at transition from the Norwegian–Greenland Sea to the SW Eurasia Basin. Onshore geology exposed on large peninsulas in front of the major Greenland Inland Ice reveals a highly complex, Paleozoic–early Cenozoic pre-opening setting. However, due to extreme ice conditions, very little is known about the offshore areas seawards of – and between – the peninsulas. Consequently, prevailing structural-tectonic models of the margin tend to be significantly oversimplified and inadequate. We present the first, combined onshore–offshore, model of the margin integrating onshore outcrops with potential field data, new offshore seismic reflection data and receiver-function analysis of seismic broad band data. The results reveal a margin which is far more complex than previously anticipated. In particular, we interpret strong margin segmentation along N/NE-striking fault structures. The structures are likely to have formed by Late Mesozoic–early Cenozoic strike-slip tectonics and have continued to be active during the late Cenozoic. A more than 8km deep sedimentary basin is interpreted to underlie the central Wandel Sea, confined by these N/NE-striking structures. We suggest that similar margin segmentation affected the conjugate Yermak Plateau–North Svalbard margin as well as parts of the NE Greenland margin to the SE. Hence, the results have important implications for the general understanding of the Mesozoic–early Cenozoic development of the intra-continental De Geer Mega-shear Region between North Greenland and Eurasia. [Copyright &y& Elsevier]

Published

2010