Cold Atom Interferometry (CAI) has proven to be a very efficient technique to achieve high sensitivity for absolute inertial sensing. It is proposed to use CAI accelerometers onboard future generations of satellite gravimetry missions to provide long-term stability and precise measurements of the non-gravitational forces acting on the satellites. This would reduce the overall instrumental errors and improve our knowledge of the Earth gravity field and its change over time. This would allow a better understanding of climate change processes and various geophysical phenomena (e.g. post-glacial rebound). Even though the accuracy and long-term stability of CAI-based accelerometers seem promising, they suffer from long dead times and a comparati...
For more than two decades, satellite gravimetry missions have provided unique data about mass redist...
In various geoscience disciplines, there is a huge interest in knowing the mass variations of the Ea...
MOCASS (Mass Observation with Cold Atom Sensors in Space) is an on-going study project funded by the...
Cold Atom Interferometry (CAI) has proven to be a very efficient technique to achieve high sensitivi...
Proof-of-principle demonstrations have been made for cold atom interferometer (CAI) sensors. Using C...
International audienceSatellite gravity missions, like GRACE and GRACE Follow-On, successfully map t...
Abstract Satellite gravity missions, like GRACE and GRACE Follow-On, successfully map the Earth’s gr...
The interest in a higher spatial and temporal resolution of the Earth's gravity field is large in va...
Cold Atom Interferometer (CAI) accelerometry is proposed for future generations of satellite gravime...
International audienceThe prospects of future satellite gravimetry missions to sustain a continuous ...
The success of GRACE-FO and its predecessors has demonstrated the benefits of satellite gravimetry f...
Cold Atom Interferometry (CAI) is a promising new technology for gravity missions, enabling measurem...
For more than two decades, satellite gravimetry missions have provided unique data about mass redist...
In various geoscience disciplines, there is a huge interest in knowing the mass variations of the Ea...
MOCASS (Mass Observation with Cold Atom Sensors in Space) is an on-going study project funded by the...
Cold Atom Interferometry (CAI) has proven to be a very efficient technique to achieve high sensitivi...
Proof-of-principle demonstrations have been made for cold atom interferometer (CAI) sensors. Using C...
International audienceSatellite gravity missions, like GRACE and GRACE Follow-On, successfully map t...
Abstract Satellite gravity missions, like GRACE and GRACE Follow-On, successfully map the Earth’s gr...
The interest in a higher spatial and temporal resolution of the Earth's gravity field is large in va...
Cold Atom Interferometer (CAI) accelerometry is proposed for future generations of satellite gravime...
International audienceThe prospects of future satellite gravimetry missions to sustain a continuous ...
The success of GRACE-FO and its predecessors has demonstrated the benefits of satellite gravimetry f...
Cold Atom Interferometry (CAI) is a promising new technology for gravity missions, enabling measurem...
For more than two decades, satellite gravimetry missions have provided unique data about mass redist...
In various geoscience disciplines, there is a huge interest in knowing the mass variations of the Ea...
MOCASS (Mass Observation with Cold Atom Sensors in Space) is an on-going study project funded by the...