Crustal motion observations from Global Positioning System (GPS) networks have not yet been fully exploited in previous studies on glacial isostatic adjustment (GIA) and mantle rheology structure. In this study, we have isolated GIA signals from vertical velocity observations at rigorously selected (over 2,000) GPS stations from the Nevada Geodetic Laboratory (NGL) by removing the effects of atmospheric and oceanic loading, as well as changes in the contemporary glaciers. We have also attempted to include hydrological and sea-level loading corrections based on the most updated model products, but found them still not accurate enough for GIA-related studies. Therefore, we recommend the GPS-derived global GIA uplift rate dataset MIDAS-AO without hydrological and sea-level loading corrections applied. Under the constraints of MIDAS-AO uplift rates, we refined the VM5a viscosity model and obtained two revised viscosity profiles, VM5aR_AO1 and VM5aR_AO2, that differ by an extra layer in the transition zone of the latter profile. With respect to VM5a, VM5aR_AO1 indicates a slight increase of viscosity within the upper mantle, while VM5aR_AO2 favors a softer upper part of the upper mantle and a stiffer transition zone. Maps of the variations of model-dataset misfits show that our new viscosity profiles commonly recover a better fit for sites located at the Scandinavian Peninsula and south of the Hudson Bay.

It has been standard practice for about two decades to compute GPS-based station velocity uncertainties using the apparent noise statistics of the non-linear position residuals rather than assume white noise (WN) behavior. The latter choice would yield unrealistic velocity uncertainties. The most common noise types used are power-law, usually close to flicker noise (FN), over most frequencies mixed with WN at the shortest periods. The complicating impact of offsets in the position time series, mostly caused by equipment changes or tectonic events, has not been fully appreciated. These are far less benign than recently suggested. In addition to contributing a pseudo-random walk noise (RW) component to the velocity errors, estimating offset parameters changes the apparent noise color towards whiter. Spectral power is effectively drained by offsets at periods longer than roughly the mean span between them. This consequently promotes a Gauss-Markov process as the apparently preferred noise model and, importantly, obscures the presence of RW and long-period Earth deformation in the series. Both effects can lead to potentially under-estimated velocity uncertainties. The full value of decadal-long GPS time series for geodynamical applications is thereby greatly eroded by recurring offsets, especially when they occur quasi-regularly. In addition, contrary to common assumption, the noise color is generally not fixed with time, but clearly becomes whiter in more recent data. The origin of the colored noise and its whitening over time remain elusive.