Skewness of Magnetic Anomalies M0 to M29 in the Northwestern Pacific

Larson, Roger L.; Sager, William W.

doi:10.2973/odp.proc.sr.129.137.1992

Cited by 22 publications

(41 citation statements)

References 20 publications

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“…It is remarkable that the amplitudes from MlON and M I are so large (about 1000 nT). Larson & Sager (1991) indicated a possibility that there is a sequence of lineations from M22 to M25 south of the Mid-Pacific Mountains; this is backwards with respect to our sequence. The reversal sequence was identified by only one track.…”

Section: Phoenix Lineation Setmentioning

confidence: 77%

Magnetic anomaly lineations from Late Jurassic to Early Cretaceous in the west-central Pacific Ocean

Nakanishi

Tamaki

Kobayashi

1992

Geophysical Journal International

163

140

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S U M M A R YLate Jurassic to Early Cretaceous (Mesozoic) magnetic anomaly lineations (the Phoenix, Magellan, Mid-Pacific Mountains, Hawaiian and Japanese lineation sets) with fracture zones in the west-central Pacific Ocean were identified more comprehensively than in any previous studies. We fixed 2100 positions of identified magnetic anomalies based on magnetic data of 283 cruise tracks. Two remarkable fracture zones, the Phoenix and Central Pacific Fracture Zones, were mapped and newly named. Our newly identified lineations from MlON to MO around the Mid-Pacific Mountains, which belong to the Hawaiian lineation set, illustrated that the sea-floor south of t h e Mid-Pacific Mountains has the same age as that of the north (132-118 Ma). Our analysis of skewness parameters revealed that the older part of the Phoenix set (M17-M29) has skewness different from that of the younger part (Ml-M14), implying an effect of magnetic overprints by the Cretaceous volcanism. It was confirmed that the spreading rate of the Mesozoic Pacific spreading system was the fastest in the world in the Mesozoic. A drastic change in spreading rates occurred simultaneously at the period between chrons M21 and M20 (149.5-148.5 Ma) in all the Mesozoic Pacific spreading systems. The event appears to be synchronous with events in other oceans such as the Mesozoic Atlantic and Indian Oceans.

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Section: Phoenix Lineation Setmentioning

confidence: 77%

Magnetic anomaly lineations from Late Jurassic to Early Cretaceous in the west-central Pacific Ocean

Nakanishi

Tamaki

Kobayashi

1992

Geophysical Journal International

163

140

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“…Revising published poles (Cox and Gordon, 1984;Sager and Pringle, 1988), we derived three poles with mean ages of 126,104, and 92 Ma. To help in bracketing the age range of the MPM, we also used a paleopole for 85 Ma that was constrained mainly by seamountanomaly inversions (Sager and Pringle, 1988) and two anomalyskewness-based poles for the end of the M-series reversals, MO to M5 and M6 to M10N (Larson and Sager, 1992 Duncan and Clague (1985) of Pacific Plate motion relative to the hotspots. Ages of volcanism for each site are from Pringle and Duncan (this volume).…”

Section: Recoverymentioning

confidence: 99%

“…They are labeled, in italics, by age in millions of years. Filled squares show paleolatitudes determined from the skewness of seafloor magnetic lineations M0 to M5, M6 to M10N, and M10N to M16 (Larson and Sager, 1992). Vertical bars show 95% confidence limits of paleolatitude; horizontal bars show either one standard deviation of error on mean age or on basalt radiometric dates, or age ranges for points having ages constrained by biostratigraphy or magnetostratigraphy.…”

Section: Origin and Formation Of Igneous Basementmentioning

confidence: 99%

Synthesis of Drilling Results from the Mid-Pacific Mountains: Regional Context and Implications

Edward¹,

William²

1995

Proceedings of the Ocean Drilling Program, 143 Scientific Results

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The results of drilling on Resolution and Allison guyots, in the Mid-Pacific Mountains (MPM), document a long history of volcanism, subsidence, and accumulation of Hauterivian-Albian shallow-water carbonate sediments. Mid-Cretaceous emersion was followed by subsidence and accumulation of pelagic sediments.Basement beneath Resolution Guyot is subaerial flows of alkalic basalt, with radiometric dates averaging 127.6 ±2.1 Ma, emplaced at about 14°S. Overlying shallow-water carbonates are 1620 m thick. Sediments at Site 866, 2 km inward from the platform edge, were deposited in shallow subtidal to intertidal depths, with intermittent subaerial exposure. At Site 867, 0.5 km from the platform edge, beach and storm deposits are common, and at Site 868,0.1 km from the edge, sponges and rudists in life positions indicate a platform-margin environment.At Allison Guyot, alkalic basalt sills were cored at the bottom of Hole 865A. Seismic profiles suggest as much as 600 m of sediments underlie the sills, which have 40 Ar/ 39 Ar radiometric dates averaging 110.7 ±1.2 Ma. The drilled strata, 730 m thick, extend from near the base to nearly the top of the Albian. The section begins with about 200 m of clayey limestone deposited in quiet, swampy waters. Upward, clays gradually disappear, reflecting the burial of volcanic hills as the seamount subsided. The rest of the series is wackestone deposited in subtidal to intertidal environments.Core and logging data at both guyots show shallowing-upward cycles of 3 to 10 m thick. Fourier analysis yields estimates of about 100 ka as the most common frequency. Longer-term fluctuations in sea level are suggested by facies successions at a decameter scale. Diagenesis was dominated by dissolution of aragonite, and cements are now marine, low-magnesium calcite. Pore-water data show the entire succession to be open to modern seawater. Dolomite dominates in the lower 400 m of carbonate strata at Resolution Guyot, and Sr-isotope data suggest much of it formed 15 to 20 m.y. after deposition. Compaction of limestone over buried basement topography proceeded apace with deposition and continued after drowning of the guyots.During the latest Albian, a fall in relative sea level of nearly 200 m exposed limestone strata on both guyots to subaerial and wave erosion, but whether the cause was tectonic or eustatic is not yet known. By mid-Turonian time, the guyots had re-submerged, but only pelagic sediments accumulated. Why no further shallow-water sediments accumulated on the guyots is a mystery. They were at about 8°S (Resolution) to 11°S (Allison) at the time of emergence. Upper Cretaceous pelagic sediments are preserved only in cavities within Albian limestone. Eocene and Paleocene sediments on Allison Guyot, about 120 m thick, were deposited at near-equatorial latitudes. The Lower Cretaceous platform is variably encrusted with phosphorite and ferromanganese oxides, even where buried beneath pelagic sediments.Primary control on acoustic-wave velocity is from diagenetic changes in density. Cha...

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“…Poles located a significant distance from the APWP are probably erroneous. [Cox and Gordon, 1984;Sager, 1992;Larson and Sager, 1992]. Seamount D5 also has a pole to the northwest of the old end of the APWP, so together with IW and HT, they may be Early Cretaceous in age.…”

Section: Resultsmentioning

confidence: 99%

“…Inversion of magnetic anomalies over seamounts [Vacquier, 1962;Parker et al, 1987] is most commonly applied to the Pacific plate because this plate contains plentiful seamounts. Since many of these seamounts have not been dated, paleomagnetic results from these inversions have been used to study volcanism in individual chains as well as over the entire plate [Sager and Keating, 1984;Sager and Pringle, 1987;Sager, 1992;Sager et al, 1993]. In 1990 and 1992 we conducted a systematic geophysical survey of the Joban Seamount Chain (JSC) and nearby Daigo-Kashima (D5) seamount (Figures I and 2) in the northwestern Pacific [Kobayashi, 1991[Kobayashi, , 1993.…”

Section: Introductionmentioning

confidence: 99%

Paleomagnetism of the Joban Seamount Chain: Its origin and tectonic implications for the Pacific plate

Masalu¹,

Tamaki²,

Sager³

1997

J. Geophys. Res.

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Skewness of Magnetic Anomalies M0 to M29 in the Northwestern Pacific

Cited by 22 publications

References 20 publications

Magnetic anomaly lineations from Late Jurassic to Early Cretaceous in the west-central Pacific Ocean

Magnetic anomaly lineations from Late Jurassic to Early Cretaceous in the west-central Pacific Ocean

Synthesis of Drilling Results from the Mid-Pacific Mountains: Regional Context and Implications

Paleomagnetism of the Joban Seamount Chain: Its origin and tectonic implications for the Pacific plate

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