Options
Geodetic and Geophysical Research Institute, Seismological Observatory, Budapest, Hungary
2 results
Now showing 1 - 2 of 2
- PublicationRestrictedCan Earth's rotation and tidal despinning drive plate tectonics?(2010-03-19)
; ; ; ; ;Riguzzi, F.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione CNT, Roma, Italia ;Panza, G.; Dipartimento di Scienze della Terra, Università di Trieste, and ICTP, Italy ;Varga, P.; Geodetic and Geophysical Research Institute, Seismological Observatory, Budapest, Hungary ;Doglioni, C.; Dipartimento di Scienze della Terra, Università Sapienza, Roma, Italy; ; ; We re-evaluate the possibility that Earth's rotation contributes to plate tectonics on the basis of the following observations: 1) plates move along a westerly polarized flow that forms an angle relative to the equator close to the revolution plane of the Moon; 2) plate boundaries are asymmetric, being their geographic polarity the first order controlling parameter; unlike recent analysis, the slab dip is confirmed to be steeper along W-directed subduction zones; 3) the global seismicity depends on latitude and correlates with the decadal oscillations of the excess length of day (LOD); 4) the Earth's deceleration supplies energy to plate tectonics comparable to the computed budget dissipated by the deformation processes; 5) the Gutenberg–Richter law supports that the whole lithosphere is a self-organized system in critical state, i.e., a force is acting contemporaneously on all the plates and distributes the energy over the whole lithospheric shell, a condition that can be satisfied by a force acting at the astronomical scale. Assuming an ultra-low viscosity layer in the upper asthenosphere, the horizontal component of the tidal oscillation and torque would be able to slowly shift the lithosphere relative to the mantle.646 98 - PublicationRestrictedGlobal pattern of earthquakes and seismic energy distributions: Insights for the mechanisms of plate tectonics(2012-03)
; ; ; ; ; ; ; ;Varga, P.; Geodetic and Geophysical Research Institute, Seismological Observatory, Hungary ;Krumm, F.; Geodätisches Institut, Universität Stuttgart, Germany ;Riguzzi, F.; Istituto Nazionale di Geofisica e Vulcanologia, Sezione CNT, Roma, Italia ;Doglioni, C.; Dipartimento di Scienze della Terra, Università Sapienza, Roma, Italy ;Sule, B.; Geodetic and Geophysical Research Institute, Seismological Observatory, Hungary ;Wang, K.; Geodätisches Institut, Universität Stuttgart, Germany ;Panza, G. F.; Dipartimento di Geoscienze, Università di Trieste, and ICTP SAND group, Italy; ; ; ; ; ; In this paper, we analyse the distributions of number of events (N) and seismic energy (E) on the Earth's surface and along its radius as obtained from the global declustered catalogue of large independent events (M≥7.0), dissipating about 95% of the Earth's elastic budget. The latitude distribution of the seismic event density is almost symmetric with respect to the equator and the seismic energy flux distribution is bimodal; both have their medians near the equator so that they are equally distributed in the two hemispheres. This symmetry with respect to the equator suggests that the Earth's rotational dynamics contributes to modulate the long-term tectonic processes. The distributions of number and energy of earthquakes versus depth are not uniform aswell: 76% of the total earthquakes dissipates about 60% of the total energy in the first ~50 km; only 6% of events dissipates about 20% of the total amount of energy in a narrow depth interval, at the lower boundary of the upper mantle (550–680 km). Therefore, only the remaining 20% of energy is released along most of the depth extent of subduction zones (50–550 km). Since the energetic release along slabs is a minor fraction of the total seismic budget, the role of the slab pull appears as ancillary, if any, in driving plate tectonics. Moreover the concentration of seismic release in the not yet subducted lithosphere suggests that the force moving the plates acts on the uppermost lithosphere and contemporaneously all over the Earth's outer shell, again supporting a rotational/tidal modulation.403 27