A comprehensive geological, geochemical, and petrogenetic study of hotspot-related oceanic basalt-rhyolite series rocks from Ascension Island, South Atlantic Ocean.

dc.contributor.advisorWeaver, Barry,en_US
dc.contributor.authorKar, Adityamoy.en_US
dc.date.accessioned2013-08-16T12:29:50Z
dc.date.available2013-08-16T12:29:50Z
dc.date.issued1997en_US
dc.description.abstractThe mafic rocks (basalt-hawaiite-mugearite-benmoreite) of Ascension Island form four distinct groups: low Zr/Nb hawaiite, high Zr/Nb basalt, intermediate Zr/Nb basalt to benmoreite, and Dark Slope Crater (DSC) hawaiite and mugearite.en_US
dc.description.abstractThe geochemical characteristics of the felsic rocks are largely consistent with an origin by fractional crystallization of high Zr/Nb mafic magmas (identical $\rm\sp{143}Nd/\sp{144}Nd$ and similar Pb isotopic ratios). Syenite, monzonite, and granite xenoliths are cumulate rocks from, and intrusive equivalents of, fractionating felsic magmas. Internal (mineral) isochrons for two granite xenoliths give ages of $\sim$1.0 Ma. Most of the felsic volcanic rocks and granite are also characterized by high $\rm\spƠS̜r/\spƠ$̜Sr ($>$0.706) compared to mafic rocks $\rm(\spƠS̜r/\spƠS̜r}0.704)$ in some of the feldspar phenocrysts from felsic rocks. d$\spÔΩ̜$O ranges of +5.5 to +8.1$\perthous$ (whole rock) and +5.5 to +7.2$\perthous$ (feldspar) in the felsic rocks also indicate the involvement of a high d$\spÔΩ̜$O component, and suggest that hydrothermally-altered pre-existing volcanic basement may have been cannibalized during felsic magma differentiation.en_US
dc.description.abstractCrystal fractionation controls compositional variation within each mafic group, however, it cannot be the cause of the differences between the groups. The high and intermediate Zr/Nb groups have similar Sr-Nd-Pb isotopic characteristics and were derived from the same mantle source (HIMU-type). The low Zr/Nb and DSC groups have different radiogenic isotopic characteristics due to contributions from enriched mantle components (HIMU-type). The dominant component, present in the high, intermediate, and low Zr/Nb groups, has the composition of the St. Helena hotspot and has mixed to varying degrees with the depleted upper mantle. The more minor component, present only in the DSC group and some intermediate Zr/Nb samples, has higher $\rm\sp{208}Pb/\sp{204}Pb$ relative to $\rm\sp{208}Pb/\sp{204}Pb$ than the St. Helena hotspot. This component may be of local lithospheric origin.en_US
dc.format.extent1 v. (various pagings) :en_US
dc.identifier.urihttp://hdl.handle.net/11244/5526
dc.noteSource: Dissertation Abstracts International, Volume: 58-08, Section: B, page: 4102.en_US
dc.noteMajor Professor: Barry Weaver.en_US
dc.subjectGeology.en_US
dc.subjectBasalt Ascension Island (Atlantic Ocean)en_US
dc.subjectGeochemistry Ascension Island (Atlantic Ocean)en_US
dc.subjectPetrogenesis Ascension Island (Atlantic Ocean)en_US
dc.subjectRhyolite Ascension Island (Atlantic Ocean)en_US
dc.subjectGeochemistry.en_US
dc.thesis.degreePh.D.en_US
dc.thesis.degreeDisciplineConoco Phillips School of Geology and Geophysicsen_US
dc.titleA comprehensive geological, geochemical, and petrogenetic study of hotspot-related oceanic basalt-rhyolite series rocks from Ascension Island, South Atlantic Ocean.en_US
dc.typeThesisen_US
ou.groupMewbourne College of Earth and Energy::Conoco Phillips School of Geology and Geophysics
ou.identifier(UMI)AAI9806319en_US

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