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Oceanic core complex

Oceanic core complexes (OCCs) are domal or arched geologic structures on the seafloor, formed by the exhumation of deep and rocks via long-lived faults that accommodate lithospheric extension. These features expose intrusive igneous rocks such as gabbros and ultramafic peridotites, often with ductile deformation fabrics and serpentinization, and they develop primarily at slow- to ultraslow-spreading mid-ocean ridges where magmatic supply is limited. Analogous to continental metamorphic core complexes, OCCs reveal the internal architecture of young oceanic lithosphere and the transition from ductile to brittle deformation along surfaces. The formation of OCCs involves tectonic extension over 1–2 million years, where detachment faults act as the primary extensional boundaries between diverging tectonic plates, uplifting footwall blocks into dome-shaped megamullions with spreading-parallel corrugations reaching amplitudes of several hundred meters. This process is influenced by the of the , including brittle-ductile coupling and viscosity contrasts, as well as syn-extensional geotherms and the presence of melt, leading to either gabbro-localized (magmatically influenced) or peridotite-localized (amagmatic) models of development. In gabbro-localized OCCs, ductile shear zones within gabbroic intrusions dominate, while peridotite-localized ones feature extensive mantle-derived rocks without significant . OCCs are predominantly observed along mid-ocean ridges with full spreading rates below 55 mm/year, such as the (e.g., at 30°N, which hosts the ) and the Southwest Indian Ridge (e.g., Atlantis Bank). Ancient analogs, like the Puka and Krabbi massifs in the western Ophiolite of , preserve similar structures from Paleozoic-Mesozoic environments. These sites cover only about 3% of surveyed seafloor in such regions but are identifiable by their bathymetric domes and corrugated fault surfaces. Geophysically, OCCs exhibit mantle-like densities, heterogeneous seismic velocities due to distribution, and enhanced late-stage , making them key targets for understanding flow, melt , and hydrothermal systems. They play a critical role in oceanic crustal accretion, contributing to global geochemical cycles, deposit formation (e.g., volcanogenic massive deposits), and the of lithosphere-asthenosphere interactions in tectonically dominated spreading environments.

Definition and Characteristics

Definition

Oceanic core complexes (OCCs) are uplifted massifs consisting of lower and rocks that are exposed at the seafloor primarily through the action of long-lived faults along mid-ocean ridges. These structures represent deep sections of the oceanic exhumed to form dome-shaped features, distinguishing them from typical volcanic seafloor terrain by their exposure of plutonic and mantle-derived materials rather than extrusive basalts. OCCs are most commonly associated with slow-spreading ridges where supply is reduced, allowing faulting to dominate crustal accretion. An alternative term for these features is "megamullions," coined due to their structural and morphological resemblance to metamorphic core complexes, including large-scale doming and corrugated surfaces resulting from low-angle faulting. Unlike smaller fault scarps or volcanic edifices, OCCs exhibit footwall uplift that produces smooth, elongated domes known as corrugations, which are oriented to the direction of plate spreading and can extend 10–150 km in length, 5–15 km in width, and rise 500–4000 m above the surrounding seafloor. These dimensions highlight their role as major tectonic features that accommodate significant extensional over millions of years. In terms of composition, OCCs are dominated by gabbroic rocks of the lower crust interspersed with peridotitic material, often serpentinized due to interaction with . Thin ductile-to-brittle zones, typically 10–100 m thick, traverse these rocks and are characterized by phyllosilicates such as and , which form through hydrothermal alteration and facilitate localized deformation along the detachment surfaces. This combination of lithologies and deformation fabrics sets OCCs apart from other features like abyssal hills or fracture zones, emphasizing their unique window into deep lithospheric processes.

Morphological and Compositional Features

Oceanic core complexes (OCCs) are characterized by prominent domal morphologies rising from the seafloor, often spanning tens of kilometers in length and width, with surfaces featuring large-scale corrugations parallel to the direction of plate spreading. These corrugations, resulting from fault slip, exhibit wavelengths of several kilometers (e.g., 5.5 km at the Mado Megamullion OCC) and amplitudes of tens to hundreds of meters, superimposed by finer striations approximately 100 m in scale. The central dome areas are typically smooth and sediment-free, exposing bare rock, while the flanks are bordered by debris fields and horseshoe-shaped depressions indicative of processes. Transverse features, such as rubble ridges with relief of 1–5 m, occasionally crosscut the corrugations, reflecting additional brittle deformation. Internally, OCCs display an asymmetric cross-section dominated by a domal footwall exhumed through long-lived faulting, with hangingwall rollover basins on one side and abrupt termination at high-angle faults on the other. Shear zones within the faults, ranging from tens of centimeters to several meters thick, show anastomosing slip planes and evidence of progressive unroofing, where deeper lithologies are exposed toward the dome crest. Chaotic terrain on the flanks arises from tectonic rotation and of initial high-angle fault scarps, with debris aprons estimated at 300 m thick or less, thinning toward the hangingwall cutoff. Compositionally, OCCs primarily consist of ultramafic rocks, including serpentinized s such as and , alongside mafic gabbros that represent lower crustal intrusions into . These rocks undergo significant alteration, with serpentinization producing low-density zones (approximately 2900 kg/m³) and greenschist-facies , often accompanied by hydrothermal deposits like sulfides and iron hydroxides. breccias and minor peridotite clasts occur in unconsolidated matrices on the aprons, reflecting mixed provenance from faulting and . Geophysically, OCCs exhibit low seismic velocities (≤7.8 km/s) in the footwall due to serpentinization, which reduces rock density and creates heterogeneous velocity structures. They are marked by positive residual Bouguer gravity anomalies, arising from dense cores of and capped by thinner low-density layers several kilometers thick. Magnetic anomalies are subdued and highly heterogeneous on scales of ~5 km, attributed to demagnetization during serpentinization, which alters content and results in variable magnetization intensities (e.g., 3 A/m in peridotites).

Tectonic Setting and Formation

Tectonic Environment

core complexes primarily form in tectonic environments characterized by slow- to ultraslow-spreading mid-ocean ridges, where full spreading rates are less than 55 mm/yr (ultraslow: <20 mm/yr; slow: 20–55 mm/yr), and in back-arc basins with similarly reduced rates. These settings are marked by diminished magmatic activity, which limits the volume of melt supplied to the ridge axis and promotes tectonic rather than volcanic modes of crustal accretion. For instance, at ultraslow-spreading centers like the Mid-Cayman Spreading Center, rates below 20 mm/yr full spreading exacerbate this magmatism deficit, leading to prolonged periods of amagmatic extension. These structures are commonly associated with the ends of ridge or non-transform discontinuities, such as inside corners at ridge-transform intersections, where spreading components induce strain localization. This localization favors the development of long-lived faults that exhume deep crustal and rocks, as opposed to symmetric magmatic spreading in centers. In back-arc basins, similar arise from the interaction between subduction-driven extension and inherited structures, further concentrating deformation. In contrast, fast-spreading ridges with rates exceeding 55 mm/yr, such as the , exhibit robust magmatic accretion that constructs thicker through frequent dike injections and short-lived, high-angle normal faults, precluding the formation of oceanic core complexes. The steady supply in these environments suppresses the deep faulting necessary for core complex exhumation, resulting in minimal exposure of lower crustal or lithologies at the seafloor. In slow-spreading environments, oceanic core complexes play a critical role in accommodating 50-80% of plate separation through amagmatic extension along detachment faults, with the remainder handled by episodic magmatism. This tectonic dominance is evident in cases like the Atlantis Bank, where data indicate that detachment slip accounts for up to 80% of motion, highlighting the efficiency of these faults in building asymmetric under low-melt conditions.

Formation Mechanisms

Oceanic core complexes form primarily through the development of low-angle faults that accommodate significant extension at slow-spreading mid-ocean ridges, exhuming lower crustal and rocks to the seafloor over timescales of 1-5 million years. These faults initiate as moderately dipping normal faults with angles of approximately 20°-30° and progressively flatten to less than 10° through footwall and localization, enabling the long-term slip necessary for exhumation. The process is driven by lithospheric extension in magma-poor environments, where reduced magmatic activity promotes reliance on tectonic unroofing rather than volcanic construction. The evolutionary stages begin with fault initiation at the brittle-ductile transition zone, typically at depths of 15-20 km, where ductile deformation in the warm footwall transitions to brittle failure in the cooler hanging wall. Progressive slip along the leads to footwall uplift and rotation, forming corrugated domes as the fault surface is exposed, with exhumation rates influenced by flexural isostatic rebound and of the hanging wall. Termination occurs through reactivation of the slip plane, often triggered by renewed that stabilizes the system or by excessive bending stresses that limit further extension, typically after 0.5-1 million years of active faulting. Supporting evidence for these mechanisms includes microstructural fabrics in fault rocks, such as S-C fabrics observed in mylonites from the ductile shear zones, indicating non-coaxial shear and progressive deformation during exhumation. Numerical models demonstrate strain localization through rheological weakening, where initial high-angle faults evolve into low-angle detachments via viscoplastic flow and feedback loops in the . Fluid-rock interactions further promote weakening by facilitating and serpentinization, reducing fault strength and enabling sustained slip. Associated features include pervasive along the detachment faults, which exploits permeable pathways created by fracturing and drives fluid-mediated alteration of exhumed rocks. Under high-pressure conditions at initiation depths, these interactions can lead to the formation of assemblages in footwall rocks, preserving evidence of deep-seated .

History and Exploration

Discovery and Historical Development

Early observations of unusual bathymetric features along the in the 1980s, such as domal highs at inside-corner settings near transform faults, were initially interpreted as potential volcanic constructs or artifacts of limited-resolution data. These anomalies, documented in surveys between 26° and 30° N, hinted at tectonic processes but lacked detailed imaging to clarify their origin. The key identification of these features as detachment-related structures occurred in the mid-1990s, with high-resolution Sea Beam multibeam and data from the near 30° N revealing corrugated, low-angle slip surfaces with striations, suggestive of long-lived normal faults exhuming lower crustal and mantle rocks. This 1997 study by Cann et al. marked the first explicit recognition of such formations as products of faulting at slow-spreading ridges, shifting interpretations from volcanic to tectonic dominance. Milestone drilling expeditions followed to test these interpretations. Ocean Drilling Program (ODP) Leg 153 in late 1993 to early 1994 targeted the (MARK) area near 23° N, recovering gabbroic rocks from the western median valley wall and confirming tectonic exposure of plutonic sequences. In the 2000s, (IODP) Expeditions 304 and 305 in 2004–2005 drilled the at 30° N, penetrating over 1,200 meters into the footwall of the central dome and documenting gabbroic and ultramafic lithologies consistent with core complex exhumation. Conceptual evolution progressed from initial descriptions of "megamullions" in , large-scale corrugated domes analogous in structure and formation to continental metamorphic core complexes via detachment faulting. By 2004, these structures were formally termed oceanic core complexes in planning for IODP drilling, solidifying their recognition as oceanic counterparts to continental core complexes, emphasizing shared mechanisms of low-angle fault exhumation in extensional settings.

Methods of Exploration

The exploration of oceanic core complexes relies on a combination of techniques to map surface and subsurface features without direct contact. Multibeam is widely used to delineate the characteristic corrugated domes and megamullion structures of these complexes, providing high-resolution topographic data that reveal fault-controlled morphologies. complements this by imaging fault fabrics and backscatter patterns indicative of lithological variations and tectonic lineations on the seafloor. Additionally, and magnetic surveys help infer subsurface density contrasts and crustal composition, such as serpentinized versus gabbroic rocks, by detecting anomalies associated with uplifted lower crust. Seismic techniques provide insights into the deeper architecture of core complexes, particularly the faults that facilitate their exhumation. Multichannel seismic reflection profiling has identified low-angle reflectors interpreted as surfaces at depths of approximately 5-10 km, though imaging remains challenging due to the complex velocity structure of heterogeneous and limited resolution in slow-spreading environments. Wide-angle seismic experiments further constrain crustal thickness and velocity models, revealing thinner, faulted crust beneath core complexes compared to typical . These methods, while essential, have produced equivocal evidence for the full extent of faulting owing to from rough seafloor . Direct sampling methods enable the collection of rock specimens to analyze the composition and deformation of exposed lower crustal and upper mantle rocks. Human-occupied submersibles, such as , have conducted targeted dives to retrieve samples from fault scarps and domal highs, facilitating in situ observations of alteration and faulting. Similarly, has been deployed for rock collection and visual documentation during early investigations of core complex exposures. Scientific ocean drilling through programs like the Ocean Drilling Program (ODP) and (IODP) has recovered over 1 km of core from sites such as , exposing sequences of gabbroic rocks that confirm the exhumation of plutonic material. Recent advances incorporate autonomous underwater vehicles (AUVs) for enhanced high-resolution imaging and targeted geochemical sampling, particularly around hydrothermal vents associated with core complexes. AUVs equipped with multibeam echo sounders and cameras produce meter-scale bathymetric maps and visual data of fault surfaces and vent structures, surpassing the resolution of shipboard surveys. These vehicles also deploy sensors for geochemical analysis of vent fluids, aiding in the study of fluid-rock interactions without the logistical constraints of manned submersibles.

Distribution and Examples

Global Distribution

Oceanic core complexes (OCCs) are primarily associated with slow- to ultraslow-spreading mid-ocean ridges and certain back-arc basins, where they account for a significant portion of the seafloor exposure. At least 172 OCCs have been identified worldwide along these systems, representing up to 25% of the crustal production at slow-spreading ridges (full spreading rates of 20–55 mm/year). This estimate is based on comprehensive reviews of bathymetric, geophysical, and sampling data, though the true number may be higher as and exploration continue to reveal additional sites. The majority of known OCCs occur along major slow-spreading ridge axes, with the (MAR) hosting the largest concentration, including prominent clusters between 15°–30°N where multiple detachment-dominated segments expose mantle and lower crustal rocks. Other key locations include the Southwest Indian Ridge (SWIR), with 43 documented OCCs often linked to oblique spreading segments, and the ultraslow-spreading Gakkel Ridge in the , where amagmatic conditions favor detachment faulting and core complex development. In back-arc settings, OCCs have been identified in basins such as the Shikoku Basin in the , where rapid extension and variable magmatism promote similar faulting mechanisms. No OCCs are observed along fast-spreading ridges, such as those in the , where magmatic accretion dominates over detachment faulting. Distribution patterns reveal that OCCs tend to cluster at the ends of segments, particularly at inside corners near transform faults or non-transform offsets, where strain localization enhances detachment formation. They are rarer in ultraslow-spreading environments like the Romanche Fracture Zone on the , where extreme magmatism deficits lead to more distributed faulting rather than focused core complexes. Recent advancements in detection have utilized altimetry-derived anomalies to identify potential OCCs globally, revealing subtle bathymetric and density contrasts associated with uplifted footwalls even in unsampled regions. Formation of OCCs is influenced by spreading obliquity, with angles greater than 20° promoting faulting by partitioning extension between strike-slip and components, as observed in models and field data from oblique segments on the SWIR and . These factors align with broader tectonic environments of low magma supply, briefly referencing the dominance in settings with asymmetric spreading and limited detailed elsewhere.

Prominent Examples

One prominent example of an oceanic core complex is the , located along the at approximately 30°N, just east of the Atlantis Transform Fault intersection. This structure features a prominent corrugated dome with a relief of about 4 km above the surrounding seafloor, exposing ultramafic and gabbroic rocks through long-lived detachment faulting. Drilling during Expeditions 304 and 305 penetrated up to 1.4 km into the footwall, recovering predominantly gabbroic lower crustal rocks interspersed with serpentinized , which provide insights into the magmatic and tectonic processes forming the lower . The massif also hosts the on its southern wall, where alkaline fluids vent from serpentinized peridotite, supporting unique chemosynthetic ecosystems distinct from typical basalt-hosted black smoker systems. Another key example is the Saint Peter and Saint Paul Megamullion in the equatorial , associated with the St. Paul system. This ultramafic-dominated oceanic core complex extends approximately 90 km in length and rises up to 4 km from the seafloor, with its apex emerging as the Saint Peter and Saint Paul Archipelago, one of the few subaerial exposures of mantle rocks on the ocean floor. The structure primarily consists of serpentinized peridotites derived from depleted abyssal mantle, along with mantle-derived pyroxenites, reflecting minimal magmatic input and dominant tectonic exhumation during intra-transform ridge spreading. The oceanic core complex at 13°30'N on the exemplifies the interplay between and hydrothermal mineralization in a magmatically robust segment. Recent 2025 studies highlight its role in hosting massive deposits formed through coupled hydro-thermo-mechanical processes, with evidence of tectono-magmatic evolution involving episodic and faulting over the past 1-2 million years. The complex features active hydrothermal vents at the Semenov-2 field, where high-temperature fluids interact with ultramafic and rocks to precipitate polymetallic sulfides, alongside inactive deposits like Semenov-1 that demonstrate evolving fluid pathways. A more recent discovery is the oceanic core complex at 23°S on the Southern , identified in 2024 at the intersection of a and a . This structure exhibits classic detachment fault morphology with a domed exposing peridotites and altered gabbros, accompanied by weathered hydrothermal deposits in the form of gossans resulting from supergene oxidation. The deposits show extensive alteration halos extending several hundred meters, characterized by silicification, chloritization, and precipitation, illustrating post-formation oxidative processes in this tectonically active setting.

Research and Implications

Current Research Topics

Recent advances in seismic imaging have significantly enhanced understanding of oceanic core complexes (OCCs) through 3D S-wave studies, including those published in 2022 focusing on the at 13°N, and ongoing efforts with 2025 ocean-bottom node seismic data collection in the same region. These investigations employ models spanning approximately 60 × 60 km to map heterogeneous velocities and intricate fault geometries associated with detachment faults. Such reveals low-velocity zones indicative of and serpentinization, alongside high-velocity anomalies linked to cooler, less altered , thereby refining models of crustal accretion in magma-poor settings. In the realm of hydrothermal systems and mineralization, 2025 numerical modeling efforts have illuminated the role of detachment faults in facilitating massive sulfide deposition at OCCs, particularly at 13°30'N on the . These models demonstrate how fault-related cooling promotes fluid circulation, leading to focused of metal sulfides along fault zones, with simulations showing enhanced permeability and temperature gradients driving formation over timescales of to 1 million years. This work underscores the linkage between tectonic exhumation and hydrothermal efficiency, providing insights into potential seafloor mineral resources. Drilling expeditions in 2025, including IODP Expedition 399 at Atlantis Massif on the Mid-Atlantic Ridge and studies at Atlantis Bank on the Southwest Indian Ridge, have targeted mantle heterogeneity within embryonic ocean settings. Recovered samples from Atlantis Bank exhibit relict pyroxene cores within intercumulus clinopyroxene, evidencing early crystallization at depths exceeding 10 km below the seafloor, which points to variable melt extraction and fertile mantle domains preserved during slow spreading. These observations highlight pronounced lithological variability, from lherzolites to depleted harzburgites, challenging uniform depletion models and emphasizing localized magmatic processes in OCC formation. Additionally, IODP Expedition 402 in the Tyrrhenian Sea revealed heterogeneous fertile mantle with refertilization evidence, further illustrating variability in such settings. Ongoing debates in OCC research from 2023 to 2025 center on the role of in fault termination and the influence of spreading on 3D structure. Studies suggest that episodic melt intrusions can stabilize or disrupt propagation, potentially limiting OCC size in moderately magmatic environments. Additionally, spreading may induce along-axis variations in fault dip and , complicating symmetric models of exhumation and leading to asymmetric morphologies observed in bathymetric . Recent studies in 2024 have addressed gaps in understanding abyssal hill and weathered deposits around OCCs, particularly at 23°S on the Southern . High-resolution and sampling reveal how detachment-dominated terrains produce subdued, elongated hills contrasting with volcanic ridge segments, while weathered hydrothermal deposits—rich in iron oxyhydroxides—form perched on fault scarps, indicating prolonged exposure and low-temperature alteration post-exhumation. These findings bridge morphological evolution with surface processes, enhancing predictions of OCC lifecycle in transform-proximal settings. Furthermore, 2025 research on post-abandonment deformation at sites like Rainbow Massif demonstrates continued complex tectonic activity after detachment fault inactivation.

Geological and Economic Significance

Oceanic core complexes (OCCs) serve as critical geological windows into the mantle-crust transition zone at slow- and ultraslow-spreading mid-ocean ridges, where faulting exhumes lower crustal gabbros and peridotites to the seafloor, revealing the processes of accretion and differentiation. These exposures provide direct evidence of how interacts with to form oceanic , contributing to broader models of by illustrating asymmetric crustal construction and the role of long-lived faults in accommodating plate separation. By facilitating heat and mass transfer from the to the surface, OCCs highlight the dynamic coupling between brittle upper crust and ductile lower during extension. The primitive mantle materials exposed in OCCs, such as variably serpentinized peridotites, offer invaluable insights into deep processes, including patterns and partial melt production beneath ridges. These rocks preserve records of pressure-temperature conditions and fluid-rock interactions at depths of 5–10 km, enabling reconstructions of melt migration and extraction from the . Furthermore, OCC-hosted serpentinization systems, which generate hydrogen-rich fluids, serve as modern analogs for Hadean-era seafloor environments on and potentially habitable conditions on other rocky planets, where alkaline venting could support prebiotic chemistry. Economically, OCCs host volcanogenic massive sulfide (VMS) deposits enriched in , , , and , formed through along detachment faults that leach metals from ultramafic and gabbroic footwalls. For instance, sites like the Semenov fields on the demonstrate how fault-controlled fluid pathways concentrate these resources, positioning OCCs as potential targets for seafloor of critical metals. Additionally, serpentinization in OCCs produces abiotic at rates comparable to basaltic systems, offering a renewable energy source through natural or enhanced subsurface reactions. Environmentally, fault-dominated venting at OCCs releases alkaline fluids rich in and , influencing ocean chemistry by altering , providing donors for microbial communities, and contributing to global carbon cycling via abiotic formation. These systems also pose regulatory challenges for deep-sea , as extraction of associated deposits could disrupt fragile chemosynthetic ecosystems and , necessitating international frameworks to balance resource potential with ecological preservation.

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