Abstract
SUMMARYPlanetary scale interannual deformations of the Earth’s surface, of millimetric amplitude, have recently been related to both geomagnetic field changes and motion within the fluid outer core. We calculate the temporal variations of the dynamical pressure at the surface of the core associated with core flow models inverted from geomagnetic observations. From these we compute predictions of the changes in Earth’s topography in response to elastic deformations in the mantle. We show that at decadal periods, the predicted changes in Earth’s topography are at most of the order of 0.3 mm. Focused at interannual periods between 4 and 9.5 yr, the predicted topography variations are smaller than 0.05 mm, at least an order of magnitude smaller than the reported observations. These amplitudes are only weakly sensitive to the choice of hypothesis used to reconstruct fluid motions at the core surface. We conclude that surface deformations induced by dynamical pressure changes in the core are below the detection level at present-day. Alternative geophysical sources must be sought to explain the observed millimetric interannual variations of the planetary scale topography, and its associated gravity variations. We currently see no justification for a physical relationship between interannual fluctuations of the geomagnetic field and of Earth’s observed deformations. We conjecture that the largest gravity signal of core origin is potentially associated with decadal longitudinal oscillations of the inner core. It might be detectable as longer series will become available.
Highlights
T Two recent studies (Ding & Chao 2018; Watkins et al 2018) have put to the fore the presence of a IP planetary scale ∼ 1 mm amplitude signal in the surface displacement recorded by the Global PosiR tioning System (GPS) network, each with a period of approximately 6 yr
ITED 4.2.2 Sub-decadal fluctuations D To focus on a possible 6-yr signal of core origin, as put forward by Ding & Chao (2018) and Watkins E et al (2018), we investigate interannual deformations contained in the time-series of the coefficients N dmn c,s
PT 5 DISCUSSION RI 5.1 The limited topography changes from outer core dynamics SC We have shown here that decadal changes in core flows lead to pressure changes of the order of 50U 100 Pa at the core-mantle boundary (CMB)
Summary
The study of Watkins et al (2018) argues for a connection between axisymmetric (or zonal) core A flows and surface vertical displacement data These scenarios are potentially appealing since it has M been shown that zonal azimuthal fluid motions in the outer core can explain the observed changes in the length-of-day (LOD) at a period of 6 yr (Gillet et al 2010, 2015b). In both Ding & Chao (2018) and Watkins et al (2018), the role of core flows was suggested in part on the basis of this
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