000004852 001__ 4852
000004852 005__ 20200310075322.0
000004852 037__ $$aPOSTER-2020-0065
000004852 100__ $$aVan Camp, M.
000004852 245__ $$aMeasuring gravity changes for decades
000004852 260__ $$c2020
000004852 269__ $$c2020-05-08
000004852 520__ $$aBeing sensitive to any phenomena associated with mass transfer, terrestrial gravimetry allows the monitoring of many phenomena at the 10E-10 g level (1 nm/s²) such as Earth tides, groundwater content, tectonic deformation, or volcanic activity. This sensitivity is richness, but also a source of problems because data interpretation requires separating the signatures from the different sources, including possible measurement artefacts associated with high precision. Separating the signal from a given source requires a thorough knowledge of both the instrument and the phenomena.  At the Membach geophysical laboratory, Belgium, the same superconducting gravimeter has monitored gravity continuously for more than 24 years. Together with 300 repeated absolute gravity measurements and environmental monitoring, this has allowed us to reach an unprecedented metrological knowledge of the instrument and of its sensitivity to hydrological and geophysical signals.  Separation is possible whenever the phenomena exhibit distinct time/frequency signatures, such as (pseudo)periodic phenomena or long-term processes, so that the signatures from other sources average out by stacking. For example, when performing repeated gravity measurements to evidence slow tectonic deformation, the easiest way to mitigate hydrological effects is to accumulate measurements for many years, at the same epoch of the year: the impact of seasonal variations is then minimized, and the interannual variations cancel out. Using 10 repeated absolute gravity campaigns at the same epoch of the year, we showed that the gravity rate of change uncertainty reaches on average 3–4 nm/s²/yr. Concurrently, using superconducting gravimeter time series longer than 10 years, we also investigated the time variations of tidal parameters. It is also possible to separate phenomena, by observing them by both gravity and some other techniques, with a different transfer function. By using 11 year-long times series from the gravimeter and soil moisture probes, and by stacking the observations, we measured directly the groundwater mass loss by evapotranspiration in the forest above the laboratory of Membach. Always with a precision better than 1 nm/s² (~2.5 mm of water), we also monitored ground partial saturation dynamics and combining the gravity data with a weather radar allowed measuring convective precipitation at a scale of up to 1 km². Extracting and interpreting those elusive signals could only by achieved throughout multi-instrumentation, multi-disciplinary collaborative studies, and 25 years of hard work.
000004852 594__ $$aNO
000004852 6531_ $$aGravity
000004852 6531_ $$aMembach
000004852 6531_ $$aTectonic deformation
000004852 6531_ $$aHydrogeology
000004852 6531_ $$aSuperconducting gravimeter
000004852 6531_ $$aAbsolute gravimeter
000004852 6531_ $$aMetrology
000004852 700__ $$ade Viron, O.
000004852 700__ $$aFrancis, O.
000004852 773__ $$tEGU, Vienna
000004852 8560_ $$fmichel.vancamp@observatoire.be
000004852 85642 $$ahttps://meetingorganizer.copernicus.org/EGU2020/session/34769
000004852 980__ $$aCPOSTER