Effect of Decoupling of Lithospheric Plates on the Observed Geoid

A joint effect of weak zones, dividing lithospheric plates, and lateral viscosity variations (LVV) in the whole mantle on the observed geoid is investigated by a new numerical approach. This technique is based on the substantially revised method introduced by Zhang and Christensen (Geophys J Int 114...

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Veröffentlicht in:	Surveys in geophysics 2014-11, Vol.35 (6), p.1361-1373
Hauptverfasser:	Kaban, Mikhail K., Petrunin, Alexey G., Schmeling, Harro, Shahraki, Meysam
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Schlagworte:	Americas Astronomy Boundaries Decoupling Dynamics Earth and Environmental Science Earth Sciences Geoids Geophysics/Geodesy Interdisciplinary research Lithosphere Mantle Mass transport Mathematical models Observations and Techniques Plate boundaries Viscosity
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description	A joint effect of weak zones, dividing lithospheric plates, and lateral viscosity variations (LVV) in the whole mantle on the observed geoid is investigated by a new numerical approach. This technique is based on the substantially revised method introduced by Zhang and Christensen (Geophys J Int 114:531–547, 1993 ) for solving the Navier–Stokes–Poisson equations in the spectral domain with strong LVV. Weak plate boundaries (WPB) are introduced based on an integrated global model of plate boundary deformations GSRM (Kreemer et al. in Geophys J Int 154:8–34, 2003 ). The effect of WPB on the geoid is significant and reaches −40 to 70 m with RMS ~20 m. The peaks are observed over large subduction zones in South America and the southwestern Pacific in agreement with previous studies. The positive geoid anomaly in South America could be explained largely by a dynamic effect of decoupling of the Nazca and South American plates. The negative changes of the geoid mostly relate to mid-oceanic ridges. The amplitude of the effect depends on the viscosity contrasts at WPB compared with the plate viscosity until its value reaches the limit of 2.5–3 orders of magnitude. This value might be considered as a level at which the plates are effectively decoupled. The effect of WPB exceeds the effect of LVV in the whole mantle and generally does not correlate with it. However, inclusion of LVV reduces the geoid perturbations due to WPB by about 10 m. Therefore, it is important to consider all factors together. The geoid changes mainly result from changes of the dynamic topography, which are about −300 to +500 m. The obtained results show that including WPB may significantly improve the reliability of instantaneous global dynamic models.
doi_str_mv	10.1007/s10712-014-9281-3
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This value might be considered as a level at which the plates are effectively decoupled. The effect of WPB exceeds the effect of LVV in the whole mantle and generally does not correlate with it. However, inclusion of LVV reduces the geoid perturbations due to WPB by about 10 m. Therefore, it is important to consider all factors together. The geoid changes mainly result from changes of the dynamic topography, which are about −300 to +500 m. 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This value might be considered as a level at which the plates are effectively decoupled. The effect of WPB exceeds the effect of LVV in the whole mantle and generally does not correlate with it. However, inclusion of LVV reduces the geoid perturbations due to WPB by about 10 m. Therefore, it is important to consider all factors together. The geoid changes mainly result from changes of the dynamic topography, which are about −300 to +500 m. The obtained results show that including WPB may significantly improve the reliability of instantaneous global dynamic models.</abstract><cop>Dordrecht</cop><pub>Springer Netherlands</pub><doi>10.1007/s10712-014-9281-3</doi><tpages>13</tpages></addata></record>
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subjects	Americas Astronomy Boundaries Decoupling Dynamics Earth and Environmental Science Earth Sciences Geoids Geophysics/Geodesy Interdisciplinary research Lithosphere Mantle Mass transport Mathematical models Observations and Techniques Plate boundaries Viscosity
title	Effect of Decoupling of Lithospheric Plates on the Observed Geoid
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