Investigating the feasibility of resolving hydrological processes with a Differential Quantum Gravimeter by hydrological scenario modeling

Quantum sensors have gained increased attention in the last years, both from the applied but also from the manufacturer perspective. Most instruments are still limited to operation within a dedicated lab. With the Absolute Quantum Gravimeter (AQG), one device has already proven mobile capabilities and was used in several research studies. This application perspective is an important topic for new instruments, in order to meet scientific requirements in terms of usability and usefulness for various research interests.

One of these research interests is hydrology. From the monitoring perspective, hydrological observations in the field traditionally rely on point measurements, often in form of invasive sensor installations. These spatially-limited observations sometimes complicate natural hydrological process investigations. An advantage is provided when using the hydrogravimetric method, with its integral nature of monitoring water mass changes as a whole.

In this contribution, we address the above-mentioned important topics for a first feasibility study of an emerging instrument: the Differential Quantum Gravimeter (DQG). Developed by Exail Quantum Sensors, the DQG measures the acceleration due to gravity and the vertical gravity gradient simultaneously. It is an industry-grade demonstrator that has been operational for three years now and has achieved state-of-the-art sensitivity on the gradient of about 60E/sqrt(tau) and a long-term stability on the gradient around 1E. For gravity measurements the performances are on par or better than the AQG with a sensitivity of 600nm/s²/sqrt(tau) and a stability down to 5nm/s².

In preparation for first field measurements, we were interested in its performance for resolving hydrological dynamics and processes. We set up different hydrological modeling scenarios to forward model gravity responses and their DQG-related gravity gradients from water mass changes. Scenarios for obtaining these water mass changes consisted of vertical 1D models using the software Hydrus. Developing scenarios from very simple to more complex soil layer setups, we tested different forcing types (precipitation, evapotranspiration) with varying magnitudes and durations. The overall objective was to simulate resulting gravity gradients at different locations as the DQG would monitor them. Varying the theoretical placement of the DQG within the model domain enabled us to investigate its sensitivity to the simulated hydrological processes with respect to its location and distance to different magnitudes of water mass changes. Forward modeled data was averaged at different time periods and combined with realistically expected noise of the instrument. The study helps to evaluate the capabilities of the instrument as a tool to observe water fluxes in the soil, as well as optimal implementation of the DQG for planning first field measurements.