Deep‐tow magnetic anomaly study of the Pacific Jurassic Quiet Zone and implications for the geomagnetic polarity reversal timescale and geomagnetic field behavior

Tominaga, Masako; Sager, William W.; Tivey, Maurice A.; Lee, Sang-Mook

doi:10.1029/2007jb005527

Cited by 47 publications

(94 citation statements)

References 60 publications

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“…The subducting direction changed from NNW to SSE to WNW to ESE at approximately 46 Ma and has been constant since that time (von Huene and Lallemand 1990). The current age of the Pacific Plate along the Japan Trench is approximately 130 to 140 Ma, as defined by a geomagnetic anomaly (Nakanishi et al 1989;Tominaga et al 2008).…”

Section: Tectonic Settingmentioning

confidence: 99%

Friction properties of the plate boundary megathrust beneath the frontal wedge near the Japan Trench: an inference from topographic variation

et al. 2014

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The 2011 Tohoku-Oki earthquake (Mw 9.0) produced a fault rupture that extended to the toe of the Japan Trench. The deformation and frictional properties beneath the forearc are keys that can help to elucidate this unusual event.In the present study, to investigate the frictional properties of the shallow part of the plate boundary, we applied the critically tapered Coulomb wedge theory to the Japan Trench and obtained the effective coefficient of basal friction μ ′ b À Áand Hubbert-Rubey pore fluid pressure ratio (λ) of the wedge beneath the lower slope. We extracted the surface slope angle and décollement dip angle (which are the necessary topographic parameters for applying the critical taper theory) from seismic reflection and refraction survey data at 12 sites in the frontal wedges of the Japan Trench. We found that the angle between the décollement and back-stop interface generally decreases toward the north. The measured taper angle and inferred effective friction coefficient were remarkably high at three locations. The southernmost area, which had the highest coefficient of basal friction, coincides with the area where the seamount is colliding offshore of Fukushima. The second area with a high effective coefficient of basal friction coincides with the maximum slip location during the 2011 Tohoku-Oki earthquake. The area of the 2011 earthquake rupture was topographically unique from other forearc regions in the Japan Trench. The strain energy accumulation near the trench axis may have proceeded because of the relatively high friction, and later this caused a large slip and collapse of the wedge. The location off Sanriku, where there are neither seamount collisions nor rupture propagation, also has a high coefficient of basal friction. The characteristics of the taper angle, effective coefficient of basal friction, and pore fluid pressure ratio along the Japan Trench presented herein may contribute to the understanding of the relationship between the geometry of the prism and the potential for generating seismo-tsunamigenic slips.

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Section: Tectonic Settingmentioning

confidence: 99%

Friction properties of the plate boundary megathrust beneath the frontal wedge near the Japan Trench: an inference from topographic variation

et al. 2014

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“…The well-defined Japanese, Hawaiian, and Phoenix magnetic lineation sets converge around a region of low-amplitude, short-wavelength magnetic anomalies known as the Jurassic Quiet Zone (JQZ). Recent and ongoing studies in the region have correlated seafloor magnetic anomalies as far back as ~170 Ma Tivey et al, 2006;Tominaga et al, 2008], but the cause of the anomalous nature of the JQZ (i.e., low-amplitude magnetic anomalies combined with rapid field fluctuations) remains unresolved. Cretaceous intraplate volcanism may play a role in obscuring seafloor magnetic records, due to the widespread emplacement of large volumes of igneous material into pre-existing Jurassic crust, and the relationship between seafloor volcanic features and JQZ magnetic anomalies has been considered in previous studies [Kent and Gradstein, 1985;Tivey et al, 2006].…”

Section: Introductionmentioning

confidence: 99%

“…In this region, the widespread emplacement of large volumes of igneous material into pre-existing Jurassic crust brings into question the relationship between Cretaceous-age seafloor volcanic features and JQZ magnetic anomalies [e.g., Sager et al, 1988, Tivey et al, 2006Tominaga et al, 2008]. We model the structure of modified oceanic crust in the JQZ using MCS images and wide-angle sonobuoy data in order to gauge the impact of Cretaceous magmatism on crustal structure and study how crustal evolution occurs through the transport and emplacement of a large distribution of melt through the lithosphere and into the crust.…”

Section: Chapter 1: Introductionmentioning

confidence: 99%

Seismic constraints on the processes and consequences of secondary igneous evolution of Pacific oceanic lithosphere

Feng¹

2016

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This thesis examines the structure of Pacific oceanic lithosphere that has been modified by post-formation magmatism in order to better understand the processes of secondary magmatic evolution of the lithosphere, which can have global-scale implications for oceanic and atmospheric chemistry. In the western Pacific, widespread Cretaceous magmatism has modified oceanic lithosphere over hundreds of millions of square kilometers. Seismic models of the upper crust from within the Jurassic Quiet Zone and the crust and upper mantle near the Mariana Trench reveal crust that is locally thickened via focused extrusive volcanism and crust that is modestly but uniformly thickened over broad regions. These distinct modes of magmatic emplacement suggest the operation of both focused and diffuse modes of melt transport through the lithosphere. Analysis of seismic observations from Guaymas Basin, in the Gulf of California, endeavor to advance our understanding of sill-driven alteration of sediments, an important consequence of secondary magmatism. We show that seismically imaged physical disruption to sediments due to igneous sill intrusion can be related to changes in sediment physical properties that reflect alteration processes. We also show how sill thickness can be estimated, enabling alteration intensity to be related to sill thickness in a variety of settings.

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“…31). Interestingly, independent indications that this may well have been the case can also be found in marine magnetic anomaly profiles which happen to be particularly weak during the 167-155 Ma time period (e.g., Tivey et al 2006;Tominaga et al 2008). This portion of the magnetic anomaly record, found in the Pacific, displays many small amplitude fluctuations and is known as the Pacific Jurassic Quiet Zone (JQZ in Fig.…”

Section: Geological Time Scalesmentioning

confidence: 91%

“…Substantial efforts are currently under way to try and recover similar detailed information about earlier field intensity variations from both sea-surface and nearbottom marine magnetic anomaly profiles (e.g. Pouliquen et al 2001;Bowers et al 2001;Tivey et al 2006;Tominaga et al 2008).…”

Section: Paleomagnetic and Seafloor Recordsmentioning

confidence: 99%

The Magnetic Field of Planet Earth

et al. 2010

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The magnetic field of the Earth is by far the best documented magnetic field of all known planets. Considerable progress has been made in our understanding of its characteristics and properties, thanks to the convergence of many different approaches and to the remarkable fact that surface rocks have quietly recorded much of its history. The usefulness of magnetic field charts for navigation and the dedication of a few individuals have also led to the patient construction of some of the longest series of quantitative observations in the history of science. More recently even more systematic observations have been made possible from space, leading to the possibility of observing the Earth's magnetic field in much more details than was previously possible. The progressive increase in computer power was also crucial, leading to advanced ways of handling and analyzing this considerable corpus G. Hulot ( ) G. Hulot et al. of data. This possibility, together with the recent development of numerical simulations, has led to the development of a very active field in Earth science. In this paper, we make an attempt to provide an overview of where the scientific community currently stands in terms of observing, interpreting and understanding the past and present behavior of the so-called main magnetic field produced within the Earth's core. The various types of data are introduced and their specific properties explained. The way those data can be used to derive the time evolution of the core field, when this is possible, or statistical information, when no other option is available, is next described. Special care is taken to explain how information derived from each type of data can be patched together into a consistent description of how the core field has been behaving in the past. Interpretations of this behavior, from the shortest (1 yr) to the longest (virtually the age of the Earth) time scales are finally reviewed, underlining the respective roles of the magnetohydodynamics at work in the core, and of the slow dynamic evolution of the planet as a whole.

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Deep‐tow magnetic anomaly study of the Pacific Jurassic Quiet Zone and implications for the geomagnetic polarity reversal timescale and geomagnetic field behavior

Cited by 47 publications

References 60 publications

Friction properties of the plate boundary megathrust beneath the frontal wedge near the Japan Trench: an inference from topographic variation

Friction properties of the plate boundary megathrust beneath the frontal wedge near the Japan Trench: an inference from topographic variation

Seismic constraints on the processes and consequences of secondary igneous evolution of Pacific oceanic lithosphere

The Magnetic Field of Planet Earth

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