Abstract
A long-term drift in polar motion (PM) has been observed for more than a century, and Glacial Isostatic Adjustment (GIA) has been understood as an important cause. However, observed PM includes contributions from other sources, including contemporary climate change and perhaps others associated with Earth’s interior dynamics. It has been difficult to separate these effects, because there is considerable scatter among GIA models concerning predicted PM rates. Here we develop a new method to estimate GIA PM using data from the GRACE mission. Changes in GRACE degree 2, order 1 spherical harmonic coefficients are due both to GIA and contemporary surface mass load changes. We estimate the surface mass load contribution to degree 2, order 1 coefficients using GRACE data, relying on higher-degree GRACE coefficients that are dominantly affected by surface loads. Then the GIA PM trend is obtained from the difference between observed PM trend (which includes effects from GIA and surface mass loads) and the estimated PM trend mostly associated with surface mass loads. A previous estimate of the GIA PM trend from PM observations for the period 1900–1978 is toward 79.90° W at a speed of 3.53 mas/year (10.91 cm/year). Our new estimate for the GIA trend is in a direction of 61.77° W at a speed of 2.18 mas/year (6.74 cm/year), similar to the observed PM trend during the early twentieth century. This is consistent with the view that the early twentieth-century trend was dominated by GIA and that more recently there is an increasing contribution from contemporary surface mass load redistribution associated with climate change. Our GIA PM also agrees with the linear mean pole during 1900–2017. Contributions from other solid Earth process such as mantle convection would also produce a linear trend in PM and could be included in our GIA estimate.
Highlights
Polar motion (PM), movement of Earth’s rotational axis relative to the crust, is a geophysical phenomenon excited by relative motion and mass redistribution within the Earth system
This is consistent with the hypothesis that Glacial Isostatic Adjustment (GIA) dominated PM trends during the early twentieth century and that later trends are more affected by contemporary surface mass redistribution, perhaps related to a warming climate
This has been assumed to be due to GIA, but it must include effects from climate-driven contemporary surface mass loads and possibly mantle convection or other interior sources
Summary
Polar motion (PM), movement of Earth’s rotational axis relative to the crust, is a geophysical phenomenon excited by relative motion and mass redistribution within the Earth system. PM observations and prediction (from geophysical data and models) provide a unique integrated view of Earth system changes. The direction of PM drift changed around 2005, largely due to accelerated ice melting in Greenland (Chen et al 2013), and additional changes in direction around 2011 were caused by terrestrial water storage sources (Adhikari and Ivins 2016). Identification of these contemporary sources has been enabled by entirely new capabilities to measure changes in Earth’s gravity field provided by the GRACE mission (Tapley et al 2019)
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