Magnetic structure of the upper kilometer of the marine crust at Deep Sea Drilling Project Hole 504B, eastern Pacific Ocean

Smith, Guy M.; Banerjee, Subir K.

doi:10.1029/jb091ib10p10337

Cited by 107 publications

(80 citation statements)

References 43 publications

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“…This may produce a declination error of about 17° estimated from McFadden et al (1988). This is similar to the standard deviation of the stable inclination of the sheeted dike complex (-23°, Smith and Banerjee, 1986;-17°, Dick, Erzinger, Stokking, et al, 1992). We consider that this controls the precision of our reorientations.…”

Section: Paleomagnetic Reorientationsupporting

confidence: 54%

“…It is possible that some lithologic units are normally magnetized, but for the majority the assumption is probably valid. Smith and Banerjee (1986) have described a secondary magnetization in a few samples in the upper part of the dike sequence, which they used to identify the polarity of the stable remanence component. This yielded approximately equal numbers of reversed and normal polarities, although it was not clear whether this secondary component represented a component acquired in situ, in the Earth's field, or a later viscoremanent contamination.…”

Section: Paleomagnetic Reorientationmentioning

confidence: 99%

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Structures and Magnetic Fabrics from the Lower Sheeted Dike Complex of Hole 504B Reoriented Using Stable Magnetic Remanence

Allerton¹,

McNeill²,

Stokking³

et al. 1995

Proceedings of the Ocean Drilling Program, 137/140 Scientific Results

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Structural measurements from core from the sheeted dike complex recovered during Ocean Drilling Program Legs 137 and 140 to Hole 504B have been reoriented using the paleomagnetic stable declination. Two dike margins observed in the core restore to an approximately east-west strike, and a steep dip to the north, parallel to the orientation of the Costa Rica Rift. Veins can be divided into two sets. The veins of one set are perpendicular to the dike margins, with a range of dips; these veins are interpreted as cooling fractures, formed by the thermal contraction of the dikes. The veins of the second set are parallel to the dikes, dipping steeply and striking approximately east-west. We suggest that these were formed by hot brines with high fluid pressures generated during dike intrusion by contact of fluids in the host rock with molten lava. Unmineralized fractures in the core probably result from anelastic stress-relaxation when the core is brought to the surface. Two dominant orientations occur: subhorizontal discing fractures, and subvertical fractures, which are subparallel, with a mean strike of 131°, approximately parallel to the minimum horizontal in-situ stress estimated for borehole breakout studies.The samples have a weak anisotropy of magnetic susceptibility, with a distribution of maximum axes with a dominantly shallow inclination. The origin of this fabric is not clear. In geographic coordinates the maximum axis corresponds closely to the present maximum horizontal stress direction, which suggests that the fabric may result from internal stresses. In sample coordinates the maximum fabric corresponds to the long axis of the core. This suggests that the fabric may be related to the sample, rather than being an inherent petrologic property.

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Section: Paleomagnetic Reorientationsupporting

confidence: 54%

Section: Paleomagnetic Reorientationmentioning

confidence: 99%

Structures and Magnetic Fabrics from the Lower Sheeted Dike Complex of Hole 504B Reoriented Using Stable Magnetic Remanence

Allerton¹,

McNeill²,

Stokking³

et al. 1995

Proceedings of the Ocean Drilling Program, 137/140 Scientific Results

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“…At least three processes can affect the magnetic properties of crustal rocks; low temperature oxidation/alteration of the magnetic minerals, geochemical variability and variations in geomagnetic field intensity. In axial and near axis locations extrusive basalts are assumed to comprise the majority of the magnetic source layer Smith and Banerjee, 1986;Pariso and Johnson, 1991]. The primary carrier of magnetic moment in basalts is titanomagnetite, which is altered to lower magnetic moment titanomaghemite Marshall and Cox, 1973;Pariso and Johnson, 1991].…”

Section: Source Of Variations In the Along-axis Camh Amplitudementioning

confidence: 99%

Oceanic lithosphere magnetization : marine magnetic investigations of crustal accretion and tectonic processes in mid-ocean ridge environments

Williams¹

2007

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The origin of symmetric alternating magnetic polarity stripes on the seafloor is investigated in two marine environments; along the ridge axis of the fast spreading East Pacific Rise (EPR) (90 25'-90 55'N) and at Kane Megamullion (KMM) (230 40'N), near the intersection of the slow-spreading Mid Atlantic Ridge with Kane Transform Fault. Marine magnetic anomalies and magnetic properties of seafloor samples are combined to characterize the magnetic source layer in both locations. The EPR study suggests that along-axis variations in the observed axial magnetic anomaly result from changing source layer thickness alone, consistent with observed changes in seismic Layer 2a. The extrusive basalts of the upper crust therefore constitute the magnetic source layer along the ridge axis and long term crustal accretion patterns are reflected in the appearance of the axial anomaly. At KMM the C2r.2r/C2An. In (-2.581 Ma) polarity reversal boundary cuts through lower crust (gabbro) and upper mantle (serpentinized peridotites) rocks exposed by a detachment fault on the seafloor, indicating that these lithologies can systematically record a magnetic signal. Both lithologies have stable remanent magnetization, capable of contributing to the magnetic source layer. The geometry of the polarity boundary changes from the northern to the central regions of KMM and is believed to be related to changing lithology. In the northern region, interpreted to be a gabbro pluton, the boundary dips away from the ridge axis and is consistent with a rotated conductively cooled isotherm. In the central region the gabbros have been removed and the polarity boundary, which resides in serpentinized peridotite, dips towards the ridge axis and is thought to represent an alteration front. The linear appearance of the polarity boundary across both regions indicates that the two lithologies acquired their magnetic remanence during approximately the same time interval. Seismic events caused by detachment faulting at Kane and Atlantis Transform Faults are investigated using hydroacoustic waves (T-phases) recorded by a hydrophone array. Observations and ray trace models of event propagation show bathymetric blockage along propagation paths, but suggest current models of T-phase excitation and propagation need to be improved to explain observed characteristics of T-phase data. AcknowledgementsA thesis may have your name on the title page, but it is truly the joint effort of many people that gets you through to the end of a Ph.D.. I am very grateful to my main thesis advisor Maurice Tivey, who taught me so much about magnetics and always had time to talk about my research when I knocked on his door. Learning to write a scientific paper has been a long learning curve and I really appreciate Maurice's editing skills and stamina for reading drafts of my papers. I have been lucky enough to be in the right place at the right time to work on some excellent datasets, particularly the Kane Megamullion data that makes up the majority of my thesis, and I thank Mau...

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“…The deepest penetration of marine crust (at 1076 msub-basement) was achieved on DSDP hole 504B and low-temperature altered titanomagnetite was reported to be the dominant magnetic carrier (SMITH and BANERJEE, 1986). They showed that the NRM in the lower two sections was a chemical rather than a thermal remanence.…”

mentioning

confidence: 99%

Effect of low-temperature oxidation on the remanence properties of titanomagnetites.

Nishitani

Kono

1989

J. geomagn. geoelec

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Changes in remanent magnetization and hysteresis parameters associated with low-temperature oxidation have been investigated using x=0.3, 0.5 and 0.7 synthetic titanomagnetite samples and natural submarine basalts. The intensity of remanence and the median destructive field (MDF) of TRM decreases with increasing oxidation. As oxidation proceeds, the intensity of CRM increases and its MDF decreases, except for x=0.7 titanomagnetite samples, which show maximum intensity and MDF around 0.6 of oxidation state (z). The intensity and stability of CRM become almost comparable to those of TRM in a high oxidation state. Saturation magnetization (Js) Understanding of the processes affecting the remanent magnetization of rocks is important in all paleomagnetic studies, in particular for the origin of the magnetic anomalies over the sea floor. Numerous factors affect the amplitude of marine magnetic anomalies; these include low-temperature oxidation of oceanic basalts, increase in the thickness of the magnetized layer with distance from the spreading center ($LAKELY, 1983), and the acquisition of viscous remanent magnetization (VRM) (JOHNSON and MERRILL, 1973; OZDEMIR and $ANERJEE, 1981). Among these factors, chemical changes due tolow-temperature oxidation are very important because of their relevance to the origin of the remanence of the oceanic basalts. Some authors consider that chemical remanent magnetization (CRM) due to lowtemperatureoxidation isthe origin of the remanence, while others take the view that

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Magnetic structure of the upper kilometer of the marine crust at Deep Sea Drilling Project Hole 504B, eastern Pacific Ocean

Cited by 107 publications

References 43 publications

Structures and Magnetic Fabrics from the Lower Sheeted Dike Complex of Hole 504B Reoriented Using Stable Magnetic Remanence

Structures and Magnetic Fabrics from the Lower Sheeted Dike Complex of Hole 504B Reoriented Using Stable Magnetic Remanence

Oceanic lithosphere magnetization : marine magnetic investigations of crustal accretion and tectonic processes in mid-ocean ridge environments

Effect of low-temperature oxidation on the remanence properties of titanomagnetites.

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