The origin of the asymmetry in the Iceland hotspot along the Mid-Atlantic Ridge from continental breakup to present-day

The Iceland hotspot has profoundly influenced the creation of oceanic crust throughout the North Atlantic basin. Enigmatically, the geographic extent of the hotspot influence along the Mid-Atlantic Ridge has been asymmetric for most of the spreading history. This asymmetry is evident in crustal thic...

Full description

Bibliographic Details
Published in:Earth and Planetary Science Letters
Main Authors: Howell, Samuel M., Ito, Garrett, Breivik, Asbjorn J., Rai, Abhishek, Mjelde, Rolf, Hanan, Barry, Sayıt, Kaan, Vogt, Peter
Format: Article in Journal/Newspaper
Language:unknown
Published: EARTH AND PLANETARY SCIENCE LETTERS 2014
Subjects:
North Atlantic
Mantle plumes
Mid-ocean ridges
Continental rifting
Hotspots
Dehydration
Aegir Ridge
Kolbeinsey
Kolbeinsey Ridge
Mid-Atlantic Ridge
Reykjanes
Iceland
Online Access:https://hdl.handle.net/11511/36012
https://doi.org/10.1016/j.epsl.2014.02.020
Description
Summary:The Iceland hotspot has profoundly influenced the creation of oceanic crust throughout the North Atlantic basin. Enigmatically, the geographic extent of the hotspot influence along the Mid-Atlantic Ridge has been asymmetric for most of the spreading history. This asymmetry is evident in crustal thickness along the present-day ridge system and anomalously shallow seafloor of ages similar to 49-25 Ma created at the Reykjanes Ridge (RR), SSW of the hotspot center, compared to deeper seafloor created by the now-extinct Aegir Ridge (AR) the same distance NE of the hotspot center. The cause of this asymmetry is explored with 3-D numerical models that simulate a mantle plume interacting with the ridge system using realistic ridge geometries and spreading rates that evolve from continental breakup to present-day. The models predict plume-influence to be symmetric at continental breakup, then to rapidly contract along the ridges, resulting in widely influenced margins next to uninfluenced oceanic crust. After this initial stage, varying degrees of asymmetry along the mature ridge segments are predicted. Models in which the lithosphere is created by the stiffening of the mantle due to the extraction of water near the base of the melting zone predict a moderate amount of asymmetry; the plume expands NE along the AR similar to 70-80% as far as it expands SSW along the RR. Without dehydration stiffening, the lithosphere corresponds to the near-surface, cool, thermal boundary layer; in these cases, the plume is predicted to be even more asymmetric, expanding only 40-50% as far along the AR as it does along the RR. Estimates of asymmetry and seismically measured crustal thicknesses are best explained by model predictions of an Iceland plume volume flux of similar to 100-200 m(3)/s, and a lithosphere controlled by a rheology in which dehydration stiffens the mantle, but to a lesser degree than simulated here. The asymmetry of influence along the present-day ridge system is predicted to be a transient configuration in which plume influence along the Reykjanes Ridge is steady, but is still widening along the Kolbeinsey Ridge, as it has been since this ridge formed at similar to 25 Ma. (C) 2014 Elsevier B.V. All rights reserved.

Similar Items