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Gee et al. 1988
Gee, J., Tauxe, L., Hildebrand, J.A., Staudigel, H. and Lonsdale, P. (1988). Nonuniform magnetization of Jasper Seamount. Journal of Geophysical Research 93: doi: 10.1029/88JB00488. issn: 0148-0227.
Paleopoles derived from seamounts have been used to reconstruct the tectonic history of ocean basins; however, the interpretation of seamount magnetization models and the validity of seamount paleopoles may be affected by inhomogeneous magnetization. Multibeam bathymetric data, sea surface and deep-tow magnetic field data, and paleomagnetic analyses of dredged samples were used to examine the origin of nonuniform magnetization within Jasper Seamount (30¿27'N, 122¿44'W). Models indicate that the seamount is predominantly reversely magnetized with local zones of normal polarity as corroborated by deep-two measurements. Lithologies likely to be volumetrically important in a seamount eddifice show highly variable magnetic properties. Basalts have high intensities (0.5--27.0 A/m), high Koenigsberger ratios (Q) and low viscous remanence (VRM) acquisition. Low Q ratios and high VRM acquisition coefficients of coarse-grained material and volcaniclastics suggest that they may have substantial viscous and induced components. Models for Jasper are characterized by low uniform intensities and far-sided paleopoles. The shallow model inclinations may be attributed to nondipolar components in the time-averaged geomagnetic field. The low intensities of the uniform models and the large nonuniform component in the seminorm solutions imply a complex distribution of magnetization sources within Jasper. This nonuniformity may result from either lithological variability or construction of the seamount spanning two or more polarity intervals. ¿ American Geophysical Union 1988 Paleopoles derived from seamounts have been used to reconstruct the tectonic history of ocean basins; however, the interpretation of seamount magnetization models and the validity of seamount paleopoles may be affected by inhomogeneous magnetization. Multibeam bathymetric data, sea surface and deep-tow magnetic field data, and paleomagnetic analyses of dredged samples were used to examine the origin of nonuniform magnetization within Jasper Seamount (30¿27'N, 122¿44'W). Models indicate that the seamount is predominantly reversely magnetized with local zones of normal polarity as corroborated by deep-two measurements. Lithologies likely to be volumetrically important in a seamount eddifice show highly variable magnetic properties. Basalts have high intensities (0.5--27.0 A/m), high Koenigsberger ratios (Q) and low viscous remanence (VRM) acquisition. Low Q ratios and high VRM acquisition coefficients of coarse-grained material and volcaniclastics suggest that they may have substantial viscous and induced components. Models for Jasper are characterized by low uniform intensities and far-sided paleopoles. The shallow model inclinations may be attributed to nondipolar components in the time-averaged geomagnetic field. The low intensities of the uniform models and the large nonuniform component in the se
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Keywords
Geomagnetism and Paleomagnetism, Geomagnetic induction, Information Related to Geographic Region, Pacific Ocean
Journal
Journal of Geophysical Research
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Publisher
American Geophysical Union
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