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Ontong Java Plateau

The Ontong Java Plateau (OJP) is the largest known oceanic plateau on , a vast submarine volcanic structure located in the southwestern , immediately north of the and extending from equatorial to mid-southern latitudes. Covering an area of approximately 2 million square kilometers—roughly the size of or —and featuring a crustal thickness of more than 30 kilometers, it constitutes a significant portion of the Pacific seafloor and is characterized by low-relief with depths generally between 1,700 and 2,000 meters. The plateau's formation involved enormous volumes of , estimated at 30–50 million cubic kilometers, erupted primarily as flood basalts during the period. Geologically, the OJP is a (LIP) believed to have originated from the impingement of a massive head on the oceanic lithosphere, leading to widespread decompression melting and the extrusion of tholeiitic basalts with relatively uniform geochemical signatures indicative of a common, plume-derived source. High-precision , including ⁴⁰Ar/³⁹Ar analyses of basalts from drill cores and dredges, places the main phase of emplacement between 117 and 108 million years ago, revealing a protracted volcanic history lasting at least 6–9 million years rather than a single cataclysmic event, as previously thought. However, recent multidisciplinary evidence suggests an earlier peak around 119 Ma synchronous with Ocean Anoxic Event 1a (OAE 1a), potentially linking the OJP to this event despite the radiometric ages. Its immense scale highlights its role in global dynamics and paleoceanographic changes during the . The OJP is increasingly viewed as a rifted fragment of the even larger Ontong Java Nui (OJN) super-plateau, which also encompasses the Manihiki Plateau to the northeast and the Hikurangi Plateau to the southwest, together forming the most voluminous magmatic event in Earth's history with a combined volume of 59–90 million cubic kilometers. Geochemical evidence, including matching isotopic ratios (e.g., ²⁰⁶Pb/²⁰⁴Pb of 18.834–19.157) in basalts from the plateaus' margins, supports a shared origin from a chemically zoned plume head around 120–125 Ma, followed by fragmentation between 118 and 86 Ma due to tectonic rifting. This hypothesis underscores the OJP's importance in understanding super-plume tectonics, the cycling of subducted slabs in the deep mantle, and the assembly of the Pacific basin's architecture. Ongoing research, including seismic imaging and deep-sea drilling, continues to probe its internal structure, such as potential dike swarms in the underlying lithosphere, to refine models of its emplacement and evolution.

Overview

Location and Extent

The Ontong Java Plateau is a vast submarine feature situated in the southwestern , centered at approximately 3°S and 160°E , and extending northward from the . It lies within the equatorial region, roughly between 0° and 10°S and 155°E and 170°E , encompassing a broad expanse of thickened . Covering an area of approximately 1.86 million km², the plateau is the largest intact oceanic plateau on , comparable in size to or slightly larger. The water depths over its surface range from an average of 2,000–3,000 m to shallower regions of about 1,700 m below , with emergent atolls such as marking the plateau's northern extent where coral reefs have built up to . These depths reflect the plateau's elevation relative to the surrounding abyssal plains, which exceed 4,000 m. The plateau's boundaries transition gradually to normal oceanic crust, bordered to the west by the Melanesian Border Plateau and its associated volcanic features, to the east by the Nauru Basin, and to the north by the Lyra Basin. To the south, it abuts the arc system, where portions of the plateau have been uplifted and exposed. As part of the proposed Ontong Java Nui superprovince, it connects geologically with the Plateau to the northeast and the Hikurangi Plateau to the southwest, forming a once-contiguous structure that covered approximately 4 million km² before fragmentation by .

Geological Significance

The Ontong Java Plateau stands as one of the world's largest oceanic plateaus and exemplifies a (LIP), formed by massive volcanic activity in the period. It spans approximately 2 million km², making it a dominant feature in the southwestern north of the . When considered alongside the adjacent and Hikurangi plateaus as remnants of the proposed Ontong Java Nui (OJN) supercomplex, these structures collectively cover over 1% of Earth's surface, highlighting their exceptional scale among global geological features. The plateau's formation involved the eruption of an estimated 40–50 million km³ of basaltic , representing one of the most voluminous igneous events on . For the broader OJN complex, total magma volume is projected at 59–90 million km³, underscoring its status as potentially the largest magmatic episode in Earth's history. This event occurred over a protracted period of approximately 6–9 million years, with average eruption rates of about 3–8 km³ per year. This event offers profound insights into dynamics, where a massive plume head is thought to have risen from the deep , inducing high-degree and rapid ascent. The resulting thickened dramatically to 30–40 km—compared to the typical 6–7 km of normal —demonstrating efficient volcanic construction and underplating processes that preserved much of the structure near the seafloor. The Ontong Java Plateau is named after the along its northeastern margin.

Geology

Composition and Structure

The Ontong Java Plateau consists primarily of tholeiitic basalts, which form the dominant rock type across its extensive . These basalts are classified into four main magmatic series based on geochemical variations observed in cores and surface exposures: the Kwaimbaita series, characterized by uniform low-potassium tholeiites that represent the most abundant and homogeneous component; the Kroenke series, featuring high-magnesium basalts that may serve as parental magmas to the Kwaimbaita type through fractional crystallization; the Singgalo series, a high-titanium variant enriched in incompatible elements and isotopically distinct, likely derived from lower-degree of a separate component; and the Wairahito series, transitional in composition between the others. Drilling efforts by the Ocean Drilling Program (ODP) have provided direct evidence of this basaltic composition. During Leg 130 in 1990, sites such as ODP 803 and 807 yielded approximately 26 m and 149 m of tholeiitic s, respectively, revealing massive flows with minimal alteration and confirming the prevalence of Kwaimbaita-type rocks. Leg 192 in 2002 further sampled the plateau at sites including ODP 1184, recovering about 338 m of basaltic volcaniclastic sequences and additional basalt flows, contributing to a total of roughly 500 m of core material that underscores the plateau's thick, monotonous volcanic carapace without significant sedimentary intercalations in the basement. The crustal architecture of the plateau features a flat-topped morphology, with an upper layer of 7–10 km thick volcanic rocks overlying a lower plutonic complex, resulting in an overall thickness of 25–36 km. Seismic data indicate P-wave velocities of 6.0–6.8 km/s in the upper crust, consistent with extrusive basalts, transitioning to 7.0–7.2 km/s in the lower crust, suggestive of gabbroic intrusions formed by deep magma underplating. Structural elements include guyots capped by atolls such as Ontong Java and Nukumanu, and prominent canyons like the Kroenke Canyon, which extends over 500 km and facilitates off the flanks; the plateau's relatively young age limits sediment cover to a thin veneer, typically less than 300 m on its summit. Isotopic analyses of the basalts reveal signatures indicative of an enriched source, with Pb-Sr-Nd ratios showing ocean island basalt-like characteristics that point to plume-derived melts experiencing high degrees of (around 30%) without substantial crustal contamination. These compositions, including elevated 87Sr/86Sr and variable εNd values, support derivation from a heterogeneous, primitive rather than recycled .

Formation Processes

The Ontong Java Plateau primarily formed through massive driven by the impingement of a large head on the base of the oceanic lithosphere during the , resulting in extensive underplating and surface eruptions that rapidly thickened the crust to over 30 km. Recent high-precision indicates this main phase occurred between 117 and 108 million years ago (Ma), spanning the to early stages, with a protracted duration of at least 6 million years rather than the previously estimated rapid pulse under 3 million years. This produced an estimated total of approximately 44 million km³, with emplacement rates significantly exceeding those of mid-ocean ridges—potentially 10 to 100 times higher during peak activity—facilitating the construction of one of Earth's largest large igneous provinces. Recent studies (as of 2024) further reveal that lavas from the OJP flowed into adjacent basins, forming the longest known submarine lava flows, up to 1600 km in length. The plume model posits that the Ontong Java originated from a thermochemical , likely linked to the Louisville , with the plume head exhibiting a of 1,000 to 2,000 upon arrival, enabling the generation of voluminous melts through decompression and heating of the . This process caused substantial lithospheric uplift and cycles, though the eruptions remained predominantly submarine due to the plateau's intraplate setting over pre-existing . A smaller secondary volcanic episode around 90 Ma (Santonian stage) added roughly 10% to the plateau's volume, involving renewed but less intense magmatism possibly from residual plume activity or localized . Recent seismic imaging (as of 2025) has identified potential dike swarms in the underlying , supporting models of plume-induced fracturing and ascent. Under the Ontong Java Nui (OJN) hypothesis, the original super-plateau encompassed an area of approximately 5 million km², formed as a contiguous entity by the same plume head before fragmentation into the modern Ontong Java, , and Hikurangi plateaus. This dispersal occurred via rifting and at the Osbourn Trough between approximately 84 and 116 Ma, driven by tectonic forces including reorganization in the southwestern Pacific. Such basalts from the primary phase, including series like the Kwaimbaita, reflect the plume's influence without direct ties to later tectonic modifications.

Tectonics

Evolutionary History

Following its initial formation between 117 and 108 Ma through volcanism, spanning at least 6 million years, the Ontong Java Plateau remained largely stable as part of the during the Normal Superchron (approximately 125–84 Ma), despite the revised timeline indicating main emplacement toward the latter part of the superchron. Rifting associated with the Osbourn Trough and other spreading centers fragmented the greater Ontong Java–Manihiki–Hikurangi superplateau into its three primary components: the Ontong Java Plateau in the northwest, the Plateau in the northeast, and the Hikurangi Plateau in the southwest, between approximately 118 and 86 Ma, with initial separation around 120–118 Ma. This fragmentation occurred amid rapid rates exceeding 18 cm/year in adjacent basins, dispersing the components across the western Pacific. The plateau has since migrated northwestward with the Pacific plate at an average velocity of about 10 cm/year, a motion that positioned it over the Louisville hotspot around 120 Ma during its formative phase, potentially linking the plume's tail to later seamount chains like the Louisville Ridge. In the Aptian stage (approximately 125–113 Ma), paleogeographic reconstructions indicate the proto-plateau was shallower than modern oceanic crust, with parts possibly emergent due to voluminous subaerial or phreatomagmatic eruptions, as evidenced by volcaniclastic deposits and interactions with contemporaneous high global sea levels that amplified its topographic relief. These conditions were influenced by broader Aptian sea-level fluctuations, which modulated the plateau's exposure and sedimentation patterns without significant subsidence until later stages. Magmatic activity on the Ontong Java Plateau evolved from an initial plume-head to a protracted tail, marked by a main between 117 and 108 representing the bulk of emplacement, with possible minor later activity around 90 , as identified through high-precision ⁴⁰Ar/³⁹Ar dating of basalts. This reflects decreasing melt production over time, transitioning from high-degree of a heterogeneous source to more focused , as inferred from geochemical variations in tholeiitic basalts across drill cores. Multidisciplinary investigations, including seismic profiling, rock dredging, and geochemical analyses from the 2023 JAMSTEC expedition, have confirmed the synchroneity of Ontong Java Nui's formation around 120 Ma and early fragmentation, supporting a unified for the superplateau followed by rapid rifting by 118–86 Ma. These findings refine the tectonomagmatic , highlighting how initial plume impingement and subsequent plate motions shaped the plateau's dispersal without invoking prolonged post-formation .

Subduction and Collision

Subduction of the Ontong Java Plateau (OJP) beneath the initiated following a period of tectonic quiescence, with convergence ceasing around 25 million years ago (Ma) due to a shift in the plate boundary and resuming approximately 10 Ma ago along the southern margin of the Solomon arc. Approximately 80% of the plateau's crustal thickness has since been subducted westward at rates of about 7–8 cm per year, reflecting the rapid convergence between the carrying the OJP and the overriding . The collision along the northern margin of the OJP with the Solomon arc has resulted in significant tectonic deformation, including the uplift of and Santa Isabel islands, where obducted sections of the plateau form prominent anticlinoria rising above . In contrast, along the southern margin proceeds more smoothly with less structural disruption, allowing continued underthrusting without widespread accretion or uplift. Only the uppermost approximately 7 km of the OJP's crust remains unsubducted and preserved on the overriding plate through accretionary processes, while deeper portions have been consumed into . Seismic tomography reveals slab fragments from the subducted OJP at depths of 400–600 km beneath the region, indicating deep penetration and potential stagnation of buoyant plateau material. The ongoing subduction of the OJP contributes to geohazards along the Solomon megathrust, including major earthquakes such as the 2007 Mw 8.1 event near Gizo, which ruptured the interface between the subducting and the overriding Solomon arc. Additionally, the influx of fluids and altered material from the subducting plateau influences arc volcanism, as evidenced by active systems on , where geochemical signatures reflect contributions from plateau-derived melts. At current convergence rates, continued is projected to lead to the full consumption of the remaining unsubducted portions of the OJP within 50–100 million years, potentially altering regional further.

Paleoenvironmental Impacts

Association with Oceanic Anoxic Events

High-precision places the main phase of Ontong Java Plateau (OJP) between 117 and 108 million years ago (Ma), spanning at least 6–9 million years. This revised timeline, based on ⁴⁰Ar/³⁹Ar analyses of basalts, indicates that the OJP emplacement postdates the Early Oceanic Anoxic Event 1a (OAE1a) at approximately 120 Ma, disconnecting it as a direct trigger for that event. However, it potentially contributed to the later OAE1b. A secondary eruptive phase around 90 Ma may have influenced minor oceanic anoxic events through similar mechanisms. Earlier studies proposed that OJP volcanism, dated to ~120–116 Ma, coincided with OAE1a and released substantial volcanic gases, including CO₂, promoting , , and anoxic conditions. Supporting evidence included biostratigraphic correlations and of volcanic ash layers. Mechanisms involved from mantle-derived melts, evidenced by negative δ¹³C excursions, intensified temperatures, reduced oxygen solubility, and nutrient release leading to and deposition. Global organic-rich shales during OAE1a showed temporal overlap with volcanic peaks and carbon perturbations. OJP basalts with elevated sulfur contents could have amplified via SO₂ emissions. Recent research on the broader Ontong Java Nui (OJN) super-plateau, encompassing the OJP, , and Hikurangi Plateaus, suggests possible earlier around 120–125 Ma that may have triggered OAE1a. A 2025 multidisciplinary study using and platinum-group element analyses from deep-sea sediments provides evidence for synchroneity between OJN and OAE1a, highlighting an ongoing debate between direct of OJP basalts and stratigraphic proxies. This contributed to mid-Cretaceous greenhouse conditions, with discussions on whether the OJP was the primary driver of OAE1a or part of multi-plume activity, such as with the . Refined is needed to resolve timing discrepancies.

Influence on Biodiversity

During the stage of the , portions of the Ontong Java Plateau (OJP) experienced subaerial exposure, as evidenced by phreatomagmatic volcaniclastic deposits at Ocean Drilling Program Site 1184, indicating explosive interactions between rising magma and surface water or air that supported emergent terrestrial ecosystems. These shallow or exposed landscapes likely facilitated the establishment of early vegetation and associated fauna, contributing to localized biodiversity hotspots amid the plateau's massive volcanic emplacement. Fragments of the broader Ontong Java Nui (OJN) superplateau, such as the Hikurangi Plateau, played a role in Gondwanan dispersal patterns by providing stable substrates that preserved ancestral lineages during the breakup of eastern , influencing biotic exchanges across the proto-Pacific. The OJP and its OJN remnants have been pivotal in shaping New Zealand's biota through vicariance events driven by tectonic fragmentation and rifting around 120 million years ago. Studies highlight how the Hikurangi Plateau, a detached OJN fragment, acted as a refugium for terrestrial organisms, enabling persistence and dispersal to ; for instance, trans-Pacific disjunctions in plants like (divergence ~8 million years ago) and invertebrates such as Andracalles weevils reflect shared vicariance histories tied to OJN dynamics. This geological framework underscores the OJP's role in fostering and evolutionary in southern Pacific and , with Zealandia's isolation amplifying these effects. In marine realms, the OJP's seamounts and guyots, formed during its , harbor unique deep-sea communities adapted to bathyal depths, including diverse assemblages of corals, sponges, and echinoderms that thrive on elevated enhancing nutrient . Modern around the plateau includes chemosynthetic ecosystems near relic hydrothermal vents from its emplacement, supporting microbial mats and specialized fauna like vestimentiferan tube worms, though drilling records indicate limited active venting today. The plateau's structure also served as "stepping stones" for marine reptiles and , providing shallow corridors across the equatorial Pacific during periods of higher levels, facilitating faunal exchanges between western and central basins. Subduction of OJP margins has paradoxically boosted by destroying ancient habitats while uplifting volcanic islands, as seen in the where collision with the Vitiaz Trench around 25-10 million years ago reversed polarity and isolated reptile populations; examples include the endemic giant Corucia , which exhibit high regional due to these tectonic barriers. Despite these insights, significant gaps persist in understanding paleo-biodiversity, with sparse records from the OJP's deep submergence precluding shallow-water assemblages today, though its vast unexplored seamounts hold potential for novel deep-sea discoveries.