A deep seismic transect from Hovgård Ridge to northwestern Svalbard across the continental-ocean transition: A sheared margin study

Ritzmann, O.; Jokat, Wilfried; Czuba, Wojciech; Guterch, A.; Mjelde, Rolf; Nishimura, Yuichi

doi:10.1111/j.1365-246x.2004.02204.x

Cited by 84 publications

(76 citation statements)

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“…They used a ray tracing model to reproduce the data, and found that crustal thickness varied widely, from 32 km for the continental crust of Svalbard to as little as 2 km (excluding the *2 km of sediment on top of the basement) near the margin between continental and oceanic crust. Mantle velocities are generally [8.0 km/s, but were found to be as low as 7.7 km/s west of Molloy transform fault, where the mantle is likely serpentinized (Ritzmann et al 2004). Also offshore from Svalbard, Geissler and Jokat (2004) Fig.…”

Section: Modeling Methods For Seismic Refraction Datamentioning

confidence: 99%

“…In order to conduct a marine seismic refraction experiment with an offset larger than tens of kilometers, Ritzmann et al (2004) used OBS instruments. They used a ray tracing model to reproduce the data, and found that crustal thickness varied widely, from 32 km for the continental crust of Svalbard to as little as 2 km (excluding the *2 km of sediment on top of the basement) near the margin between continental and oceanic crust.…”

Section: Modeling Methods For Seismic Refraction Datamentioning

confidence: 99%

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Using overlapping sonobuoy data from the Ross Sea to construct a 2D deep crustal velocity model

et al. 2011

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Sonobuoys provide an alternative to using long streamers while conducting multi-channel seismic (MCS) studies, in order to provide deeper velocity control. We present analysis and modeling techniques for interpreting the sonobuoy data and illustrate the method with ten overlapping sonobuoys collected in the Ross Sea, offshore from Antarctica. We demonstrate the importance of using the MCS data to correct for ocean currents and changes in ship navigation, which is required before using standard methods for obtaining a 1D velocity profile from each sonobuoy. We verify our 1D velocity models using acoustic finite-difference (FD) modeling and by performing depth migration on the data, and demonstrate the usefulness of FD modeling for tying interval velocities to the shallow crust imaged using MCS data. Finally, we show how overlapping sonobuoys along an MCS line can be used to construct a 2D velocity model of the crust. The velocity model reveals a thin crust (5.5 ± 0.4 km) at the boundary between the Adare and Northern Basins, and implies that the crustal structure of the Northern Basin may be more similar to that of the oceanic crust in the Adare Basin than to the stretched continental crust further south in the Ross Sea.

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Section: Modeling Methods For Seismic Refraction Datamentioning

confidence: 99%

Section: Modeling Methods For Seismic Refraction Datamentioning

confidence: 99%

Using overlapping sonobuoy data from the Ross Sea to construct a 2D deep crustal velocity model

et al. 2011

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“…The Norwegian Sea, SW Barents Sea and Svalbard margins are well-studied with extensive deep seismic studies [e.g., Faleide et al, 1991;Mjelde et al, 1997Mjelde et al, , 1998Mjelde et al, , 2002aMjelde et al, , 2005Ritzmann et al, 2002Ritzmann et al, , 2004Breivik et al, 2003Breivik et al, , 2006. In contrast, few deep seismic studies exist across the conjugate NE Greenland margin [Voss and Jokat, 2007;Jokat et al, 2004] and, so far, none to the north of 76°N.…”

Section: Introductionmentioning

confidence: 99%

East Greenland Ridge in the North Atlantic Ocean: An integrated geophysical study of a continental sliver in a boundary transform fault setting

et al. 2008

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The combined Greenland‐Senja Fracture Zones (GSFZ) represent a first‐order plate tectonic feature in the North Atlantic Ocean. The GSFZ defines an abrupt change in the character of magnetic anomalies with well‐defined seafloor spreading anomalies in the Greenland and Norwegian basins to the south but ambiguous and weak magnetic anomalies in the Boreas Basin to the north. Substantial uncertainty exists concerning the plate tectonic evolution of the latter area, including the role of the East Greenland Ridge, which is situated along the Greenland Fracture Zone. In 2002, a combined ocean‐bottom seismometer and multichannel seismic (MCS) survey acquired two intersecting wide‐angle reflection and coincident MCS profiles across and along the East Greenland Ridge. We present the results of integrated reflection seismic interpretation, first‐arrival tomography, 2D kinematic raytracing, full‐wave amplitude modeling, and gravity modeling of the intersecting profiles. The results show that (1) the Greenland Basin is characterized by a normal oceanic crustal velocity structure, (2) the velocity structure of the East Greenland Ridge is of overall continental type, and (3) a major faulted basin province above highly extended continental crust exists to the NE of the ridge. The results further suggest that a zone of extremely thin and faulted continental crust above partially serpentinized mantle peridotite defines the NW edge of the East Greenland Ridge and the transition to the NE Greenland margin.

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“…3), and that the 8000 m/s arrival is the result of an interface located substantially below this depth. Energy refracted off an up-dip interface with either serpentenized mantle (with layer velocity ∼7700 m/s; Ritzmann et al, 2004) or lower oceanic crust (velocity ∼7400 m/s; Jones, 1999, p. 342) could produce an apparent velocity of 8000 ± 100 m/s.…”

Section: Deep Structure Across the Continental Shelf And In The Northmentioning

confidence: 99%

“…If the true maximum velocity detected with sonobuoy L14S1 is 7900 m/s (within measurement uncertainty), it is also possible that the interface is in fact the Moho, but is composed of serpentinized mantle such as is observed in the Svalbard continental margin (Ritzmann et al, 2004).…”

Section: Structure Across the Continental Shelf Breakmentioning

confidence: 99%

Deep crustal structure of the Adare and Northern Basins, Ross Sea, Antarctica, from sonobuoy data

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et al. 2014

Earth and Planetary Science Letters

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A deep seismic transect from Hovgård Ridge to northwestern Svalbard across the continental-ocean transition: A sheared margin study

Cited by 84 publications

References 50 publications

Using overlapping sonobuoy data from the Ross Sea to construct a 2D deep crustal velocity model

Using overlapping sonobuoy data from the Ross Sea to construct a 2D deep crustal velocity model

East Greenland Ridge in the North Atlantic Ocean: An integrated geophysical study of a continental sliver in a boundary transform fault setting

Deep crustal structure of the Adare and Northern Basins, Ross Sea, Antarctica, from sonobuoy data

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