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Geodynamic Information in Peridotite Petrology 总被引:12,自引:1,他引:12
Systematic differences are observed in the petrology and majorelement geochemistry of natural peridotite samples from thesea floor near oceanic ridges and subduction zones, the mantlesection of ophiolites, massif peridotites, and xenoliths ofcratonic mantle in kimberlite. Some of these differences reflectvariable temperature and pressure conditions of melt extraction,and these have been calibrated by a parameterization of experimentaldata on fertile mantle peridotite. Abyssal peridotites are examplesof cold residues produced at oceanic ridges. High-MgO peridotitesfrom the Ronda massif are examples of hot residues producedin a plume. Most peridotites from subduction zones and ophiolitesare too enriched in SiO2 and too depleted in Al2O3 to be residues,and were produced by meltrock reaction of a precursorprotolith. Peridotite xenoliths from the Japan, Cascades andChilePatagonian back-arcs are possible examples of arcprecursors, and they have the characteristics of hot residues.Opx-rich cratonic mantle is similar to subduction zone peridotites,but there are important differences in FeOT. Opx-poor xenolithsof cratonic mantle were hot residues of primary magmas with1620% MgO, and they may have formed in either ancientplumes or hot ridges. Cratonic mantle was not produced as aresidue of Archean komatiites. KEY WORDS: peridotite; residues; fractional melting; abyssal; cratonic mantle; subduction zone; ophiolite; potential temperature; plumes; hot ridges 相似文献
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Pressures at which partial crystallization occurs for mid-oceanridge basalts (MORB) have been examined by a new petrologicalmethod that is based on a parameterization of experimental datain the form of projections. Application to a global MORB glassdatabase shows that partial crystallization of olivine + plagioclase+ augite ranges from 1 atm to 1·0 GPa, in good agreementwith previous determinations, and that there are regional variationsthat generally correlate with spreading rate. MORB from fast-spreadingcenters display partial crystallization in the crust at ridgesegment centers and in both mantle and crust at ridge terminations.Fracture zones are likely to be regions where magma chambersare absent and where there is enhanced conductive cooling ofthe lithosphere at depth. MORB from slow-spreading centers displayprominent partial crystallization in the mantle, consistentwith models of enhanced conductive cooling of the lithosphereand the greater abundance of fracture zones through which theypass. In general, magmas that move through cold mantle experiencesome partial crystallization, whereas magmas that pass throughhot mantle may be comparatively unaffected. Estimated pressuresof partial crystallization indicate that the top of the partialmelting region is deeper than about 2035 km below slow-spreadingcenters and some ridge segment terminations at fast-spreadingcenters. KEY WORDS: MORB; olivine gabbro; partial crystallization; partial melting; ridge segmentation; fracture zones; crust; mantle; lithosphere 相似文献
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A VOLUME IN HONOUR OF THE WORK OF MICHAEL J. O'HARA, ON THE OCCASION OF HIS 70TH BIRTHDAY
The 20th century was eventful inall areas of Earth Science. Continental drift and sea-floorspreading became embodied in the theory of plate tectonics,isotopically heterogeneous mantle was recognized as a by-productof plate tectonics, large igneous provinces were identifiedas possibly originating from mantle plumes - the list goes on.One thing these revolutions have in common is the process ofscientific debate - which Mike O'Hara has stimulated vigorouslyin the field of 相似文献
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Plume-Associated Ultramafic Magmas of Phanerozoic Age 总被引:19,自引:12,他引:19
A parameterization of experimental data in the 0·27·0GPa pressure range constrains both forward models of potentialprimary magma compositions that exit the melting regime in themantle and inverse models for computing the effects of olivinefractionation for any olivine-phyric lava suite. This is usedto infer the MgO contents of primary magmas from Gorgona, Hawaii,Baffin Island and West Greenland. They typically contain 1820%MgO for wide variations in assumed peridotite source compositions,but MgO can drop to 1417% for Fe-enriched sources, andincrease to 2426% for fractional melts from Gorgona.Primary magmas with 1820% MgO have potential temperaturesof 15201570°C. For Gorgona picrites with 24% MgO,the potential temperature and initial melting pressure wereabout 1700°C and 8·0 GPa, respectively; melting washot and deep, consistent with the plume model. There are importantrestrictions to magma mixing in mantle plumes. Primary magmasthat exit the melting regime are both well-mixed aggregate fractionalmelts and isolated fractional melts. The latter can originatefrom a hot plume axis and be in equilibrium with olivines havingmg-numbers of 93·093·6, but they have MgOcontents and thermal characteristics that are difficult to constrain. KEY WORDS: komatiite; picrite; basalt; MORB; olivine; mantle plumes; primary magmas; equilibrium melting; accumulated fractional melting 相似文献
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