Depositional Setting, Diagenetic Processes, and Pressure Solution-Assisted Compaction of Mesozoic Platform Carbonates, Southern Apennines, Italy

Aiming at understanding the source of the fluids that mineralizing within seismically active fault zones, we investigate the noble gas isotopes (i.e., helium (He), neon (Ne), and argon (Ar)) in the fluid inclusions (FIs) trapped in the calcite veins sampled along high‐angle fault zones of the Contursi hydrothermal basin, southern Italy. The latter basin lies in close vicinity of the MW = 6.9, 1980 Irpinia earthquake and exposes numerous fault scarps dissecting Mesozoic shallow‐water carbonates. The analyses of noble gases (He, Ne, Ar) are conducted to identify the origin of the volatiles circulating along the faults at the time of calcite precipitation. Then, outcomes of this discussions are compared with currently outgassing of deep‐sourced CO2 coupled to mantle‐derived He in that area, whose output is larger than those from some volcanic areas worldwide. The results indicate that He in FIs is dominated by a crustal radiogenic component (4He), and by an up to 20% of a mantle‐derived component (3He), with a highest isotopic signature of 1.38 Ra. This value is consistent with the highest percentage of mantle‐derived He associated to high‐flux CO2 gas emission in the investigated area (1.41 Ra). We propose that the variability of the He isotopic signature measured in primary FIs can result from early trapping of fluid inclusions or post trapping processes and seismic activity that modify the pristine He isotopic signature (i.e., derived from the crust and/or mantle) in groundwater along the faults during periods of background seismicity. Such investigations are fundamental to understand fluid migration in fault systems and the role of fluids in processes of earthquake nucleation.

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Microfacies, Depositional Settings, Diagenesis and Diagenetic Evolution of the Ordovician to Devonian Homoclinal Ramp-Type Carbonate Platform Setul Group, Northern Peninsular Malaysia

Radzir,

Samah,

Ali

et al. 2024

Preprint

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The Ordovician to Devonian strata of the Setul Group in the northern region of Peninsular Malaysia represent medium- to thick-bedded, white to grayish limestone rich in biota components. A detailed study of microfacies analysis and diagenetic investigation revealed eleven (11) microfacies and five (5) diagenetic histories. The recognized microfacies include 2 mudstone, 2 wackestone, 2 packestone, 3 grainstone, chert and carbonaceous shale. The microfacies and their associations represent a homoclinal ramp depositional setting designated on the basis of the rock components. The Setul Group has undergone significant diagenetic alteration due to various diagenetic events that have altered the primary and secondary porosities. The recognized diagenetic alterations include micritization, cementation, neomorphism, compaction and dolomitization. The paragenetic sequence reveals that the carbonate rock is modified in phreatic zones and involves early to late diagenetic evolution. The microfacies and diagenetic alteration revealed that the Setul Group was deposited in a shallow marine to deep ocean environment dominated by siliciclastic and carbonate sediments.

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Depositional Setting, Diagenetic Processes, and Pressure Solution-Assisted Compaction of Mesozoic Platform Carbonates, Southern Apennines, Italy

Cited by 4 publications

References 58 publications

Multiscale discrete fracture network modelling of shallow-water carbonates: East Agri Valley Basin, Southern Italy

Multiscale discrete fracture network modelling of shallow-water carbonates: East Agri Valley Basin, Southern Italy

Tracing a Mantle Component in Both Paleo and Modern Fluids Along Seismogenic Faults of Southern Italy

Microfacies, Depositional Settings, Diagenesis and Diagenetic Evolution of the Ordovician to Devonian Homoclinal Ramp-Type Carbonate Platform Setul Group, Northern Peninsular Malaysia

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