3D gravity modelling reveals off-axis crustal thickness variations along the western Gakkel Ridge (Arctic Ocean)

Near-orthogonal ultra-slow (13.3mmyr−1 to 6.5mmyr−1) sea floor spreading in the absence of large transform faults make the Arctic Gakkel Ridge ideally suited for the study of magmatic processes. To enable this, we generated a three-dimensional gravity model of crustal thickness over the ridge and pa...

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Bibliographic Details
Published in:Tectonophysics 2016-11, Vol.691, p.85-97
Main Authors: Schmidt-Aursch, Mechita C., Jokat, Wilfried
Format: Article
Language:English
Subjects:
Anomalies
Basalt
Basins
Convection
Crustal thickness
Faults
Gakkel Ridge
Geological faults
Gravitation
Gravity
Inflow
Magma
Magmatism
Magnetic anomalies
Mantle
Mantle convection
Melt generation
Mid-ocean ridge
Mid-ocean ridges
Modelling
Ocean basins
Ocean floor
Oceanic crust
Oceans
Ridges
Sea floor spreading
Spreading
Thickening
Three dimensional models
Transform faults
Volcanic cones
Volcanology
Water inflow
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Summary:Near-orthogonal ultra-slow (13.3mmyr−1 to 6.5mmyr−1) sea floor spreading in the absence of large transform faults make the Arctic Gakkel Ridge ideally suited for the study of magmatic processes. To enable this, we generated a three-dimensional gravity model of crustal thickness over the ridge and parts of the adjacent Nansen and Amundsen basins west of 65° E. The model shows that oceanic crust accreted prior to chrons C5/C6 is generally very thin (1–3km). Magnetic anomalies over this thin crust are highly variable both parallel and perpendicular to the ridge axis. This is the result of amagmatic or weakly volcanic spreading that started with the opening of the basins 56Ma ago. The separation of Greenland from Svalbard at chron C5/C6 led to the inflow of North Atlantic mantle into the western Eurasia Basin leading to a change in the mantle convection system and the establishment of a magmatic dichotomy along the Gakkel Ridge. Robust magmatism was established in the Western Volcanic Zone (6° 30′ W–3° 30′ E), leading to creation of a 6.6km thick igneous crust, characterized by a strong positive axial magnetic anomaly, numerous volcanic cones, and widespread thick mid-ocean ridge basalts. The transition to the neighbouring Sparsely Magmatic (3° 30′ E–29° E) and Eastern Volcanic (29° E–85° E) zones is sharp. Peridotites cover the central valley and the inner rift flanks, the central magnetic anomaly vanishes and crustal thickness decreases to 1–4km. Transverse basement ridges, extending for as much as 100km into the adjacent basins, intersect the central valley. Although partly of tectonic origin, the transverse ridges are also an expression of long-living magmatic centres, as revealed by increased magnetic anomaly intensities and local thickening of the crust to values as great as 5.9km. •Thickness of oceanic crust is highly variable along and across axis.•Perpendicular basement ridges are partly of tectonic rather than of volcanic origin.•Spreading was amagmatic or low volcanic until chrons C5/C6.•Separation of Greenland and Svalbard provoked enhanced magmatism in the West.•Change of mantle convection triggered focussed magmatism in the East.
ISSN:0040-1951
1879-3266
DOI:10.1016/j.tecto.2016.03.021