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Abstract During the subduction of an oceanic plate, fluids are released from metabasaltic crust, metasediment, and serpentinite under high‐pressure/low‐temperature conditions. Although some fluids may eventually leave the slab, some participate in metamorphic reactions within the slab during subduction and exhumation. To identify fluid sources and other controls influencing mineral composition, we report the in situ‐measured δ18O of lawsonite and garnet in blueschist‐ to eclogite‐facies rocks from 10 subduction zones that represent various field settings, including mélanges, structurally coherent terranes, and an eclogite xenolith derived from a subducted plate. Lawsonite records distinct δ18O depending on the host rock type and other rock types that were fluid sources during lawsonite growth. In general, lawsonite in metabasalt (7.6 ± 0.2–14.8 ± 1.1‰) is isotopically lighter than in metasediment (20.6 ± 1.4–24.1 ± 1.3‰) but heavier than in metagabbro (4.0 ± 0.4–7.9 ± 0.3‰). The extent of δ18O fractionation was evaluated for lawsonite–fluid and lawsonite–garnet pairs as a function of temperature (T). Results demonstrate that variations of >1.7‰ in lawsonite and >0.9‰ in garnet are not related to changingT. More likely, the relative contributions of fluids derived from isotopically heavier lithologies (e.g., sediments) versus lighter lithologies (e.g., ultramafic rocks) are the major control. Monte Carlo simulations were performed to investigate the sources of metasomatic fluids and the water/rock ratio that formed lawsonite‐bearing metasomatite. Results indicate that δ18OLwsand δ18OGrtrecord interactions with fluids sourced from diverse lithologies (sediment, serpentinite), further supporting that δ18OLwsis a useful indicator of subduction fluid‐rock interactions.
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This content will become publicly available on September 1, 2026
Tracing Fluid‐Rock Interactions and Migration Pathways in Shallow Megathrust Shear Zones Through Rock Magnetic Analysis
Abstract Megathrust shear zones are the main fluid transport pathways during the seismic cycle and play a key role in controlling physicochemical alteration. Defining fluid‐rock interaction in wall rocks provides evidence for unraveling the hydrogeology of shear zones and their link to active fluid circulation. We analyzed the variation in concentration, grain size and assemblages of magnetic minerals in the wall rocks of a shallow megathrust (the Sestola Vidiciatico shear zone) where no evidence of high‐frictional heating has been recorded. The Sestola Vidiciatico shear zone preserves evidence of active fluid circulation and stress‐switch during the last brittle phases of the Early to Middle Miocene subduction of the Adriatic plate beneath the frontal prism of the European plate. Magnetic properties indicate low bulk heat transfer during the seismic cycle. Changes in magnetic mineral concentrations highlight iron depletion from clay minerals and dissolution of iron‐oxides for interaction with exotic fluids during the coseismic phase. The relative distribution of Fe‐oxides and goethite suggests migration of Fe‐enriched fluids along fractures during the coseismic/postseismic phase, followed by precipitation for interaction with local fluids. Subsequent alteration and weathering of magnetic minerals, accompanied by the formation of hematite and maghemite, are related to partial oxidation during the interseismic phase. Heterogeneity in magnetic mineral distribution supports active fluid circulation during repeated seismic events and/or exhumation. Rock magnetic characterization of wall rocks in exhumed megathrust represents a promising tool to better understand the role of fluid migration and redox conditions during seismic cycles in subduction zones.
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- Award ID(s):
- 2153786
- PAR ID:
- 10655577
- Publisher / Repository:
- American Geophysical Union
- Date Published:
- Journal Name:
- Journal of Geophysical Research: Solid Earth
- Volume:
- 130
- Issue:
- 9
- ISSN:
- 2169-9313
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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