Detecting Groundwater Level Changes with Radar Interferometry

The Dutch are known for their dewatered peat pastures known as polders. These pastures are used for heavy agricultural and have to be continuously drained to compensate for the subsiding top layer due to oxidation. Additionally, the top part of the peat soil responds to changes in temperature and precipitation. Driven by moisture changes, the peat soils shrink as water is evaporated during dry, warm periods, while they swell in periods with lots of precipitation. During these dry periods, the groundwater level drops as well, mirroring the behavior of the surface. As the groundwater level drops, more organic material is exposed to air and more greenhouse gases are emitted. Monitoring the movement of the surface of the pasture could provide indirect measurements of the groundwater level and used to reveal areas that are more or less affected by a rainfall deficit. Efforts to reduce emissions can then be focused on more vulnerable areas. However, this dynamical behavior is hard to monitor with conventional geodetic means, as it is near impossible to install the required benchmarks on the soft surface of the pastures, which are needed for repeated surveying.  

Radar Interferometry presents an opportunity to observe this dynamic behavior without the need of installing equipment. The Sentinel-1a/b satellites pass the Dutch peat soils four times per week, providing the data necessary to observe the shrinking and swelling of the soils. We applied the technique to two study areas in the Netherlands, one between Delft and Rotterdam, where most of the pastures are situated on peat or peaty soils, and one above Zwolle in the center of Netherlands, near Staphorst, a peat-rich area. We processed all radar acquisitions between 2017 and 2019, which were averaged to 200 by 200 meter square windows to suppress noise. This is than further processed to obtain deformation time series. Based on these time series, areas more vulnerable to droughts were identified. Notably, 2018 – a very dry year, with a very large rainfall deficit – caused significantly more shrinkage than observed in 2017. We estimate that some areas shrunk up to 50 percent more. The associated drop in groundwater level exposed fresh peat to air for the first time, potentially increasing the emission of greenhouse gases significantly.

Climate change exposes peat soils to new and more extreme weather conditions. Radar Interferometry can monitor the impact of these conditions on the soils and can be used to reduce greenhouse emissions more effectively.