Abstract
Abstract. The superconducting gravimeter (SG) GWR C025 has monitored the time variation in gravity at the Conrad Observatory (Austria) since autumn 2007. Two tiltmeters have operated continuously since spring 2016, namely a 5.5 m long interferometric water level tiltmeter and a Lippmann-type 2D pendulum tilt sensor. The co-located and co-oriented set up enables a wide range of investigations because the tilts are sensitive to both geometrical solid Earth deformations and to gravity potential changes. The tide-free residuals of the SG and both tiltmeters clearly reflect the gravity and/or deformation effects associated with short- and long-term environmental processes and reveal a complex water transport process at the observatory site. Water accumulation on the terrain surface causes short-term (a few hours) effects which are clearly imaged by the SG gravity and N–S tilt residuals. Long-term (> a few days/weeks) tilt and gravity variations occur frequently after long-lasting rain, heavy rain or rapid snowmelt. Gravity and tilt residuals are associated with the same hydrological process but have different physical causes. SG gravity residuals reveal the gravitational effect of water mass transport, while modelling results exclude a purely gravitational source of the observed tilts. Tilt residuals show the response on surface loading instead. Tilts can be strongly affected by strain–tilt coupling (cavity effect). N–S tilt signals are much stronger than those of the E–W component, which is most probably due to the cavity effect of the 144 m long tunnel being oriented in an E–W direction.
Highlights
The gravity field of the Earth changes temporally – mainly because of external forcing and due to the direct gravitational (Newtonian) and indirect effects of mass transport in the entire Earth system
Gravitational (Newtonian) tilt is the change of the plumb line direction at the sensor location as it would happen on a non-deformable planet due to the spatial displacement of the equipotential surfaces
Due to its incremental measuring principle, interferometric water level tiltmeter (iWT) sometimes suffers from interference phase cycle slips; the correct interpretation of the interferogram phase fails if the phase change between two consecutive interferograms is larger than one interference phase value, typically of 203.6 nm
Summary
The gravity field of the Earth changes temporally – mainly because of external forcing and due to the direct gravitational (Newtonian) and indirect effects of mass transport in the entire Earth system. Gravitational (Newtonian) tilt is the change of the plumb line direction at the sensor location as it would happen on a non-deformable planet due to the spatial displacement of the equipotential surfaces The latter is caused either by external forcing fields (tides) or by mass redistribution. Within the framework of the large-scale injection experiment at the German Continental Deep Drilling Program (KTB) deep drilling site, Jahr et al (2006a, b; 2008) studied the surface deformation due to fluid-induced stress changes by borehole tiltmeter array observations They detected tilt signals with magnitudes between 450 and 700 nrad after 3 months of water injection and interpreted the observations as the deformation effect extending from the upper crust to the surface being caused by induced pore pressure changes. The installation of two tiltmeters in 2014 provided new insight into possible scenarios of hydrological water transport at CO by comparing tide-free SG and tilt time series, which is subject of the investigation subsequently reported
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