Crustal Deformation due to Atmospheric Pressure Loading in New Zealand

Crustal Deformation due to Atmospheric Pressure Loading in New ZealandWe investigate atmospheric pressure loading displacements in New Zealand using global and regional air-pressure data collected over a period of 50 years (1960-2009). The elastic response of the Earth to atmospheric loading is calculated by adopting mass loading Love numbers based on the parameters of the Preliminary Reference Earth Model (PREM). The ocean response to atmospheric loading is computed utilising a modified inverted barometer theory. The results reveal that the atmospheric loading vertical displacements are typically smallest along coastal regions, while gradually increasing inland with the maximum peak-to-peak displacement of 13.1 mm for this study period. In contrast, the largest horizontal displacements are found along coastal regions, where the maximum peak-to-peak displacement reaches 2.7 mm. The vertical displacements have a high spatial correlation, whereas the spatial correlation of the horizontal displacement components is much smaller. A spectral decomposition of the atmospheric loading time series shows that the signal is a broad band with most energy between 1 week and annual periods, and with a couple of peaks corresponding to approximately annual forcing and its overtones. The largest amplitudes in the atmospheric loading time series have an annual and semi-annual period.

Response of Regional Sea Level to Atmospheric Pressure Loading in a Climate Change Scenario

The regional response of the global ocean to low-frequency changes in atmospheric pressure loading, ηib, is analyzed as it occurs in the Max Planck Institute for Meteorology (MPI-M) coupled ocean–atmosphere climate model in response to increased atmospheric CO2 concentrations. Results suggest that long-term changes in ηib can lead to increases in high-latitude sea level by up to 5 and 10 cm, respectively, after doubling and quadrupling the atmospheric CO2 content. At low latitudes, sea level will decrease simultaneously between 2 and 4 cm through the combined effects of changes in the atmospheric circulation and through the increase of its moisture content. In subpolar regions, associated rates of sea level increase are of the order of 0.4–0.6 mm yr−1 for quadrupled atmospheric CO2 concentrations, while in mid- and low latitudes, sea level will decrease at a rate of 0.2 mm yr−1. Differences between doubling and quadrupling CO2 concentrations indicate regionally dependent nonlinearities in the changing climate system. The analysis suggests that in some regions (including the coasts of northern Europe) low-frequency ηib changes could be as large as 10%–20% of a global sea level increase anticipated over the next 100 yr. While not being a dominant effect, amplitudes of long-period ηib changes are large enough to be included in future estimates of climate-related regional sea level change. Increasing the vertically integrated atmospheric CO2 content by 4 and 12 kg m−2 (on global average), in response to doubling and quadrupling atmospheric CO2 concentrations, suggests associated reductions of global sea level by 0.6 and 1.7 cm, respectively. The differences between two different model solutions are significant, especially in the Southern Ocean, where they show significantly different atmospheric mass and pressure distributions, and at low latitudes, where differences resemble the contribution of increased moisture content added to the inverted-barometer (IB) effect in the MPI-M solution.