Seismic Stratigraphy of the Ontong Java Plateau

Mosher, D.; Mayer, Larry A.; Shipley, Tom H.; Winterer, Edward L.; Hagen, Rick A.; Marsters, Janice C.; Bassinot, Frank; Wilkens, Roy H; Lyle, Mitchell W

doi:10.2973/odp.proc.sr.130.047.1993

Cited by 12 publications

(17 citation statements)

References 24 publications

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“…These sequences continue to Site 289/586, and sequence mE has been interpreted at ODP Sites 807, 1183, and 1186. The sequences are laterally continuous and mostly parallel in water depths less than $2800 m; this relationship is consistent with observations from the northern and northeastern OJP Mosher et al, 1993]. In this region, seafloor topography largely reflects the morphology of the top of basement, despite the sediment and sedimentary rock column being >1000 m thick .…”

Section: Sedimentary Section Of the Main Ojpsupporting

confidence: 87%

“…Sediment and sedimentary rock characterized by reflections of low to high amplitude may be divided into three sequences: middle Miocene (mM), Miocene/Oligocene transition (M/O), and middle Eocene (mE) ( Figure 3). Similar high-amplitude reflections have been reported elsewhere on the OJP [e.g., Mosher et al, 1993]. At Site 806, near Site 289/586, synthetic seismograms were confined to the upper sedimentary section .…”

Section: Sedimentary Section Of the Main Ojpsupporting

confidence: 85%

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Intrabasement reflections of the Ontong Java Plateau: Implications for plateau construction

Inoue¹,

Coffin²,

Nakamura

et al. 2008

Geochem Geophys Geosyst

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[1] The Early Cretaceous Ontong Java Plateau (OJP) in the western equatorial Pacific, Earth's most voluminous large igneous province (LIP), is characterized by intrabasement seismic reflections. To investigate the nature of such reflections, we have analyzed new and all older multichannel seismic (MCS) reflection data from the OJP using an instantaneous phase velocity analysis technique and synthetic seismograms. Intrabasement reflections are most prevalent on the main OJP, especially on its crest. On MCS data, the reflections (1) are semicontinuous and subparallel to the top of igneous basement; (2) in places, have the opposite phase of seafloor reflections; and (3) have an average frequency of $20 Hz. We calculate synthetic seismograms using impedance contrasts between massive lava and pillow lava flows obtained from downhole logs at OJP scientific drill sites and show that these lithologies can produce intrabasement reflections similar to those observed in the MCS data. Alternatively, to evaluate the possibility of sediment/sedimentary rock interbeds causing the intrabasement reflections, we use published Early Cretaceous sedimentation rates determined from OJP drill sites and published estimates for the duration of massive OJP volcanism to calculate a range of possible sedimentary interbed thicknesses. The range proves to be below the detection limit of the MCS data. Therefore, we conclude that the intrabasement reflections arise from alternating relatively thin lava flows produced at low effusion rates and relatively thick massive flows generated at high effusion rates, both originating from vents and fissures on the OJP, probably on its crest.

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Section: Sedimentary Section Of the Main Ojpsupporting

confidence: 87%

Section: Sedimentary Section Of the Main Ojpsupporting

confidence: 85%

Intrabasement reflections of the Ontong Java Plateau: Implications for plateau construction

Inoue¹,

Coffin²,

Nakamura

et al. 2008

Geochem Geophys Geosyst

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“…The data are presented versus depth (above) and versus age (below). On the latter figures, the depth of the lysocline versus age are shown, as interpreted by Mosher et al (1993).…”

Section: Resultsmentioning

confidence: 99%

“…9. The data for Site 803 and Site 807 are plotted versus depth as well as versus age, the latter accompanied by a curve showing the interpreted level of the lysocline versus time (Mosher et al , 1993). The general level of intraparticle porosity is lower at Site 803 than at Site 807, corresponding to the results of Lind (1993b).…”

Section: Resultsmentioning

confidence: 99%

Chemical and mechanical processes during burial diagenesis of chalk: an interpretation based on specific surface data of deep‐sea sediments

Borre¹,

Fabricius²

1998

Sedimentology

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Burial diagenesis of chalk is a combination of mechanical compaction and chemical recrystallization as well as cementation. We have predicted the characteristic trends in specific surface resulting from these processes. The specific surface is normally measured by nitrogen adsorption but is here measured by image analysis of scanning electron micrographs. This method concentrates on the micritic matrix alone. Deep‐sea sediments are ideally suited to the study of burial diagenesis because they accumulate in a relatively conservative tectonic setting. We used material from the Ontong Java Plateau in the Pacific, where a > 1 km thick package of chalk facies sediments accumulated from the Cretaceous to the present. In the upper 200–300 m the sediment is unconsolidated carbonate ooze, throughout this depth interval compaction is the principal porosity reducing agent, but recrystallization has an equal or larger influence on the textural development. In the chalk interval below, compaction is not the only porosity reducing agent but it has a larger influence on texture than concurrent recrystallization. Below 850 m grain‐bridging cementation becomes important resulting in a lithified limestone below 1100 m. This interpretation is based on specific surface data alone, and modifies current diagenetic models.

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“…This carbonate low is expressed as a seismic reflector that can be traced over thousands of kilometers across the central equatorial Pacific (Mayer et al, , 1986. Mosher et al (1993) identified a reflector in the western equatorial Pacific that was tentatively correlated with this central equatorial reflector, and Bloomer et al (this volume) were able to link this central equatorial Pacific reflector with a similar reflector in the eastern equatorial Pacific, which they correlated with the 9.5-Ma "carbonate crash." Farrell et al (this volume) further explore the regional extent of the "carbonate crash" by rationalizing the age models and correlating the carbonate records (converted to mass accumulation rate) from a number of central equatorial Pacific sites (RC12-65, RC12-66, DSDP Site 574) with those from Leg 138.…”

Section: Middle/late Miocene Carbonate Transitionmentioning

confidence: 99%

Paleoceanography of the Eastern Equatorial Pacific during the Neogene: Synthesis of Leg 138 Drilling Results

Pisias¹,

Mayer²,

Mix³

1995

Proceedings of the Ocean Drilling Program

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The primary objective of Leg 138 was to provide detailed information about the ocean's response to global climate change during the Neogene. Two north-south transects were drilled (95° and 110°W) within the region of equatorial divergence-driven upwelling (and thus high accumulation rates and resolution) and spanning the major equatorial ocean current boundaries (and thus recording a high-amplitude signal of the response of the sediment to climatically and/or tectonically driven changes in ocean circulation). The Neogene is marked by a number of well-known climatic and tectonic events (the closing of the Isthmus of Panama, the onset of North Atlantic Deep Water (NADW), the rapid uplift of the Himalayas, the major intensification of Northern Hemisphere glaciation), and the response of the ocean before and after these events was a key focus of Leg 138 drilling.To address these objectives at the highest resolution possible, the Leg 138 scientific staff developed a number of new shipboard strategies and analytical procedures. These included the real-time analysis of the near-continuous gamma ray attenuation porosity evaluator (GRAPE) and susceptibility profiles produced by the multisensor track (MST) on unsplit cores to monitor core recovery and, if necessary, to modify the drilling strategy to ensure proper offset of coring gaps; the collection of near-continuous color reflectance data on split cores; the logging of the first hole drilled at each site to optimize drilling and sampling strategies for subsequent holes; and the use of multiple continuous records to unambiguously construct complete composite sections for each site. The complete, continuous records provided by the GRAPE (with a temporal resolution of often yr), in conjunction with an excellent microfossil stratigraphy and often excellent magnetostratigraphy, allowed for astronomical tuning of the stratigraphic record and resulted in a set of internally consistent, high-resolution age models that provide a secure, absolute time scale for the past 6 m.y. For the period before 6 m.y., the absolute time calibration is less secure, but it is still better than any previously offered.The high-resolution stratigraphic framework of Leg 138 provided new insight into the previously ambiguous tectonic history of the region. By assuming that maximum sedimentation rates along the north-south transect would be expected at the equator, the Leg 138 stratigraphy supports the 1985 work of Cox and Engerbretson, which calls for two different poles of rotation of the Pacific Plate during the interval 0-20 Ma. The Leg 138 plate reconstructions also support several previously hypothesized ridge crest jumps and a slowing of the absolute motion of the Nazca Plate at about 5 Ma.Although Leg 138 data that predates about 13 Ma is limited, the impression that one can gain from these data is that the eastern equatorial Pacific was characterized by relatively high carbonate concentrations and accumulation rates before about 11 Ma. This pattern was interrupted occasionally by r...

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Seismic Stratigraphy of the Ontong Java Plateau

Cited by 12 publications

References 24 publications

Intrabasement reflections of the Ontong Java Plateau: Implications for plateau construction

Intrabasement reflections of the Ontong Java Plateau: Implications for plateau construction

Chemical and mechanical processes during burial diagenesis of chalk: an interpretation based on specific surface data of deep‐sea sediments

Paleoceanography of the Eastern Equatorial Pacific during the Neogene: Synthesis of Leg 138 Drilling Results

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