The possibility of a net rotation of the lithosphere with respect to the mantle is generally overlooked since it depends on the adopted mantle reference frames, which are arbitrary. We review the geological and geophysical signatures of plate boundaries, and show that they are markedly asymmetric worldwide. Then we compare available reference frames of plate motions relative to the mantle and discuss which is at best able to fit global tectonic data. Different assumptions about the depths of hotspot sources (below or within the asthenosphere, which decouples the lithosphere from the deep mantle) predict different rates of net rotation of the lithosphere relative to the mantle. The widely used no-net-rotation (NNR) reference frame, and low (<0.2°–0.4°/Ma) net rotation rates (deep hotspots source) predict an average net rotation in which some plates move eastward relative to the mantle (e.g., Nazca). With fast (>1°/Ma) net rotation (shallow hotspots source), all plates, albeit at differe
The possibility of a net rotation of the lithosphere with respect to the mantle is generally overlooked since it depends on the adopted mantle reference frames, which are arbitrary. We review the geological and geophysical signatures of plate boundaries, and show that they are markedly asymmetric worldwide. Then we compare available reference frames of plate motions relative to the mantle and discuss which is at best able to fit global tectonic data. Different assumptions about the depths of hotspot sources (below or within the asthenosphere, which decouples the lithosphere from the deep mantle) predict different rates of net rotation of the lithosphere relative to the mantle. The widely used no-net-rotation (NNR) reference frame, and low (<0.2°-0.4°/Ma) net rotation rates (deep hotspots source) predict an average net rotation in which some plates move eastward relative to the mantle (e.g., Nazca). With fast (>1°/Ma) net rotation (shallow hotspots source), all plates, albeit at different velocity, move westerly along a curved trajectory, with a tectonic equator tilted about 30° relative to the geographic equator. This is consistent with the observed global tectonic asymmetries. © 2014 China University of Geosciences (Beijing) and Peking University.
Tectonically asymmetric Earth: From net rotation to polarized westward drift of the lithosphere / Doglioni, Carlo; Carminati, Eugenio Ambrogio Maria; Crespi, Mattia Giovanni; Marco, Cuffaro; Mattia, Penati; Federica, Riguzzi. - In: GEOSCIENCE FRONTIERS. - ISSN 1674-9871. - ELETTRONICO. - (2014), p. ----. [10.1016/j.gsf.2014.02.001]
Tectonically asymmetric Earth: From net rotation to polarized westward drift of the lithosphere
DOGLIONI, Carlo;CARMINATI, Eugenio Ambrogio Maria;CRESPI, Mattia Giovanni;
2014
Abstract
The possibility of a net rotation of the lithosphere with respect to the mantle is generally overlooked since it depends on the adopted mantle reference frames, which are arbitrary. We review the geological and geophysical signatures of plate boundaries, and show that they are markedly asymmetric worldwide. Then we compare available reference frames of plate motions relative to the mantle and discuss which is at best able to fit global tectonic data. Different assumptions about the depths of hotspot sources (below or within the asthenosphere, which decouples the lithosphere from the deep mantle) predict different rates of net rotation of the lithosphere relative to the mantle. The widely used no-net-rotation (NNR) reference frame, and low (<0.2°–0.4°/Ma) net rotation rates (deep hotspots source) predict an average net rotation in which some plates move eastward relative to the mantle (e.g., Nazca). With fast (>1°/Ma) net rotation (shallow hotspots source), all plates, albeit at differeI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
