EGU2020-491
https://doi.org/10.5194/egusphere-egu2020-491
EGU General Assembly 2020
© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

Factors controlling fracture distribution within a carbonate-hosted relay ramp: insights from the Tre Monti fault (Central Apennines)

Marco Mercuri1, Eugenio Carminati1, Maria Chiara Tartarello1, Marco Brandano1, Paolo Mazzanti1,2, Alessandro Brunetti2, Ken J. W. McCaffrey3, and Cristiano Collettini1
Marco Mercuri et al.
  • 1Sapienza Università di Roma, Dipartimento di Scienze della Terra, Rome, Italy (marco.mercuri@uniroma1.it)
  • 2NHAZCA S.r.l., spin-off company Sapienza Università di Roma, Rome, Italy
  • 3Durham University, Earth Sciences Department, Durham, UK

Fractures constitute the main pathway for fluids in fault damage zones hosted in low-porosity rocks. Understanding the factors controlling fracture distribution is hence fundamental to better assess fluids circulation in fault damage zones, with evident implications for fault mechanics, hydrogeology and hydrocarbon exploration. Being usually characterized by a strong damage and structural complexity, this is of particularly importance for relay zones.

We integrated classical and modern structural geology techniques to investigate the factors controlling fracture distribution within a portion of a relay ramp damage zone pertaining to the Tre Monti fault (Central Italy). The damage zone is hosted within peritidal carbonates and located at the footwall of the relay ramp front segment. We analysed the distribution of the fracture density in the outcrop through (1) scanlines measured in the field, (2) oriented rock samples, and (3) scan-areas performed on a virtual outcrop model obtained by aerial structure-from-motion.

Our results highlight structural and lithological control on fracture distribution. Scanlines and virtual scan-areas show that fracture density increases with the distance from the front segment of the relay ramp. Moreover, all the methods highlight that supratidal and intertidal carbonate facies exhibit higher fracture density than subtidal limestones.

This apparently anomalous trend of fracture density, that increases moving away from a main fault segment, has two main explanations. (1) The damage is associated with the relay ramp development: approaching the centre of the relay ramp (i.e., moving away from the front segment) an increase in the number of subsidiary faults with their associated damage zones promotes high fracture densities. (2) The increase in fracture density can be attributed to the increasing content in supratidal and intertidal carbonate facies that are more abundant in the centre of the relay ramp.

Our results provide important suggestions for factors controlling fracture distribution and fluid flow within relay ramps hosted by shallow water limestones. We show that the trend of fracture distribution with respect to a main fault is not easily predictable in presence of a relay ramp, because it can be modulated by the subsidiary faults formation and slip during the relay ramp development. Moreover, carbonate facies play a non-negligible role in fracture distribution within fault zones hosted in shallow-water carbonates.

How to cite: Mercuri, M., Carminati, E., Tartarello, M. C., Brandano, M., Mazzanti, P., Brunetti, A., McCaffrey, K. J. W., and Collettini, C.: Factors controlling fracture distribution within a carbonate-hosted relay ramp: insights from the Tre Monti fault (Central Apennines), EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-491, https://doi.org/10.5194/egusphere-egu2020-491, 2020.

Displays

Display file