Zhang Guoliang et al. (2012): Geochemistry of basalts from IODP Site U1365; implications for magmatism and mantle source signatures of the mid-Cretaceous Osbourn Trough

Leg/Site/Hole:
IODP 329
IODP 329 U1365
Identifier:
2012-069480
georefid
10.1016/j.lithos.2012.04.014
doi
Creator:
Zhang Guoliang
Chinese Academy of Sciences, Institute of Oceanology, Laboratory of Marine Geology and Environment, Qingdao, China
author
Smith-Duque, Christopher
University of Southampton, United Kingdom
author
Tang Suohan
Chinese Academy of Geological Sciences, Institute of Geology, China
author
Li He
Chinese Academy of Sciences, Institute of Geology and Geophysics, China
author
Zarikian, Carlos
Integrated Ocean Drilling Program Management International, United States
author
D'Hondt, Steven
author
Inagaki, Fumio
author
Identification:
Geochemistry of basalts from IODP Site U1365; implications for magmatism and mantle source signatures of the mid-Cretaceous Osbourn Trough
2012
Lithos (Oslo)
Elsevier, Amsterdam, Netherlands
144-145
73-87
The Integrated Ocean Drilling Program site U1365 drilled into the basement of the southwest Pacific crust formed from the mid-Cretaceous Osbourn Trough that rifted apart the Manihiki and Hikurangi Plateaus (the Greater Manihiki). The basalt geochemistry at this site is crucial for understanding the magmatic processes and mantle source of the mid-Cretaceous Osbourn Trough. The recovered fresh basalts were low-K tholeiitic normal (N) and depleted (D) mid-ocean ridge basalt (MORB). Their trace element and Sr-Nd isotope compositions indicate a Pacific-type mantle source rather than any significant influences from the nearby Louisville Seamount Chain or from the Greater Manihiki Plateau. Despite the presence of a plume head underneath the Osbourn Trough at its initial stage, the insignificance of a plume head could be explained by the long-distance (>1000 km) southward migration of the Osbourn Trough. Lavas at site U1365 vary from low-MgO (<6.9 wt.%) N-MORB at the bottom to high-MgO (8 wt.% to 9.5 wt.%) D-MORB and, then, to medium-MgO (7.3 wt.% to 8.2 wt.%) N-MORB according to their eruption sequences, which was accompanied by magma mixing in the magma reservoir. The D-MORB group lavas have higher melting degrees than those of N-MORB group based on their concentrations of TiO (sub 2) , Na (sub 2) O and CaO corrected for crystallization relative to MgO=7.8 wt.%. The major element compositions of the high-MgO D-MORB lavas were consistent with partial melting in the spinel-peridotite zone over a pressure interval from approximately 3.1 GPa to 2 GPa in the mantle. The significant overlap of N-MORB and D-MORB in Sr-Nd isotopes suggests that chemical differences between the two groups were derived from the mantle melting processes. Based on comparison with lavas from the East Pacific Rise where a positive correlation of mantle melting degree vs. spreading rate is shown, we suggest that the Osbourn Trough might have a full spreading rate of approximately 140 mm/yr. Thus, the slow ridge-like axial morphology of the Osbourn Trough should be a character of an extinct fast ridge. Abstract Copyright (2012) Elsevier, B.V.
English
Serial
Coverage:Geographic coordinates:
North:-38.0000
West:174.0000East: 180.0000
South:-43.0000
Isotope geochemistry; Igneous and metamorphic petrology; alkaline earth metals; assemblages; basalts; chemical composition; Cretaceous; East Pacific; Expedition 329; geochemistry; Hikurangi Trough; ICP mass spectra; igneous rocks; Integrated Ocean Drilling Program; Invertebrata; IODP Site U1365; isotope ratios; isotopes; magmatism; major elements; Manihiki Plateau; mantle; mass spectra; Mesozoic; metals; microfossils; mid-ocean ridge basalts; mid-ocean ridges; Middle Cretaceous; Nd-144/Nd-143; neodymium; ocean floors; Osbourn Trough; Pacific Ocean; Protista; Radiolaria; rare earths; sea-floor spreading; South Pacific; Southeast Pacific; Southwest Pacific; spectra; Sr-87/Sr-86; stable isotopes; strontium; trace elements; volcanic rocks; West Pacific; X-ray fluorescence spectra;
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