Earthquakes occur suddenly and without any unambiguous precursory signals identified to date. Our inability to develop prior warnings of earthquakes in the short term in purely natural or anthropically modified contexts, or to develop technologies that are ‘earthquake free’, is due to our poor understanding of the processes at depth that accompany earthquake occurrence. F-IMAGE aimed to provide an important contribution to this understanding with wide implications for seismic risk assessment and mitigation, and for industrial activities associated with induced seismicity, such as geothermal or mining.
The F-IMAGE project studies the rock around faults, and the mechanical behavior of the faults and their interactions with the rock around them. The methods of analysis to enable functional imaging of the Earth's crust need to be improved, or changed. Our developments rely heavily on continuous ambient seismic records, which are widely available and globally under-exploited. We characterize the fault zone in terms not only of classical seismic velocities, but also of its scattering strength related to complexity and damage. We aim to describe how these structures evolve in time, or to be more precise, to monitor some observables that can be related to the physical processes at work.
We develop and improve methods to measure new observables such as: temporal evolution of elastic properties in the vicinity of faults; changes in scattering properties as indicative of damage to the rock; time-dependent classification of the various components of the continuous motion of the Earth surface (e.g. micro-earthquakes, tremors, noise of different origins); statistical behavior of the seismic activity in relation to other observations, and primarily geodetic measurements. Our guess is that with such new data in hand, obtained through the more recent progress in seismology and geodesy, we open new fields of research that are associated with the new observables and the weak signals that have been discarded in the past.
These new techniques have been applied to high-risk areas and have shown their potential for the imaging of fluid movements, direct measurement of slow slip in fault roots, localization of shear in the mantle or discovery of transient deformation at large depth. The methodological developments of F-IMAGE are useful well beyond this present project with already applications in water resource management, volcanology or glaciology.