Abstract
The GRACE/GRACE-FO satellites have observed large scale mass changes, contributing to the mass budget calculation of the hydro-and cryosphere. The scale of the observable mass changes must be in the order of 300 km or bigger to be resolved. Smaller scale glaciers and hydrologic basins significantly contribute to the closure of the water mass balance, but are not detected with the present spatial resolution of the satellite. The challenge of future satellite gravity missions is to fill this gap, providing higher temporal and spatial resolution. We assess the impact of a geodetic satellite mission carrying on board a cold atom interferometric gradiometer (MOCASS: Mass Observation with Cold Atom Sensors in Space) on the resolution of simulated geophysical phenomena, considering mass changes in the hydrosphere and cryosphere. Moreover, we consider mass redistributions due to seamounts and tectonic movements, belonging to the solid earth processes. The MOCASS type satellite is able to recover 50% smaller deglaciation rates over a mountain range as the High Mountains of Asia compared to GRACE, and to detect the mass of 60% of the cumulative number of glaciers, an improvement respect to GRACE which detects less than 20% in the same area. For seamounts a significantly smaller mass eruption could be detected with respect to GRACE, reaching a level of mass detection of a submarine basalt eruption of 1.6 109 m3. This mass corresponds to the eruption of Mount Saint Helens. The simulations demonstrate that a MOCASS type mission would significantly improve the resolution of mass changes respect to existing geodetic satellite missions.
Highlights
Variations of the gravity acceleration on the Earth surface occur on a wide spectrum of time and spatial scales
MOCASS shows to be superior, because it is able to catch lower fluctuation rates, which instead lie on the error curve of GRACE, and cannot be detected
First estimates show that MOCASS brings significant improvement in the gravity field with respect to GRACE
Summary
Variations of the gravity acceleration on the Earth surface occur on a wide spectrum of time and spatial scales. Plurennial trends in the gravity field variations have been recorded and studied in the Himalaya region (Braitenberg & Shum, 2017; Matsuo & Heki, 2010; Sun et al, 2009) and interpreted as due to the combination of hydrologic, isostatic and tectonic effects. The satellite observations from GRACE of the gravity changes have been validated with terrestrial superconducting gravimeters and have shown the complimentarity between terrestrial and satellite observation from GRACE (Abe et al, 2012; Weise et al, 2009, 2012) These past satellite missions employed a combination of electrostatic accelerometers, which recorded both inertial and gravitational accelerations; the GNSS tracking of the satellite allowed removing the inertial components unveiling the pure gravity attractions. The area is characterized by an intense tectonic activity, along the Main Himalayan Thrust, that is responsible of an uplift of the frontal chain and to significant hydrologic variations
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