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Varne, Rick et al. (2000): Macquarie Island; its geology, structural history, and the timing and tectonic setting of its N-MORB to E-MORB magmatism
Leg/Site/Hole:
Related Expeditions:
DSDP 29
DSDP 29 278
DSDP 29 279
Identifier:
ID:
2002-010619
Type:
georefid
Creator:
Name:
Varne, Rick
Affiliation:
University of Tasmania, School of Earth Sciences, Hobart, Tasmania, Australia
Role:
author
Name:
Brown, Anthony V.
Affiliation:
University of California at Davis, United States
Role:
author
Name:
Falloon, Trevor
Affiliation:
University of Houston, United States
Role:
author
Identification:
Title:
Macquarie Island; its geology, structural history, and the timing and tectonic setting of its N-MORB to E-MORB magmatism
Year:
2000
Source:
In: Dilek, Yildirim (editor), Moores, Eldridge M. (editor), Elthon, Don (editor), Nicolas, Adolphe (editor), Ophiolites and oceanic crust; new insights from field studies and the Ocean Drilling Program
Publisher:
Geological Society of America (GSA), Boulder, CO, United States
Volume:
349
Issue:
Pages:
301-320
Abstract:
Macquarie Island is an exposure above sea level of the Macquarie Ridge Complex, on the boundary between the Australian and Pacific plates south of New Zealand. Geodynamic reconstructions show that at ca. 12-9.5 Ma, oceanic crust of the Macquarie Island region was created at this plate boundary within a system of short spreading-ridge segments linked by large-offset transform faults. At this time, the spreading rate was slowing (<10 mm/yr half-spreading rate) and magmatism was waning. Probably before 5 Ma, and possibly before the extinct spreading ridge had subsided, the plate boundary became obliquely convergent, and crustal blocks were rotated, tilted, and uplifted along the ridge to form the island. Planation by marine erosion has exposed sections through the oceanic crust. The magmatism that built the oceanic crust produced melts similar in composition to the widespread normal to enriched mid-oceanic-ridge basalt (N- to E-MORB) suite found in many spreading ridges, but the melts ranged beyond E-MORB to primitive, highly enriched, and silica-undersaturated compositions. These compositions form one end member of a continuum from MORB but seem not to have been derived from a MORB-source mantle, despite sharing a Pacific MORB isotopic signature. The survival of these primitive melts may be due to their origin in a slow-spreading system that must have been closing down as extension along the plate boundary gave way to transpression, putting a stop to the upwelling of asthenosphere and decompression melting. In a more energetic, faster-spreading system, mixing would have been more efficient, the presence of this end member could not easily have been inferred from its isotopic composition, and the igneous rocks would have resembled a typical N- to E-MORB suite. Macquarie Island may therefore provide a type example of magmatism at a very slow spreading ridge and a clue to the origins of E-MORB.
Language:
English
Genre:
Rights:
URL:
Coverage:
Geographic coordinates:
North:-51.2008
West:160.0417
East: 162.3806
South:-56.3325
Keywords:
Igneous and metamorphic petrology; Solid-earth geophysics; basalts; chemical composition; crust; Deep Sea Drilling Project; dikes; DSDP Site 278; DSDP Site 279; faults; igneous rocks; intrusions; Leg 29; Macquarie Island; magmatism; metamorphism; mid-ocean ridge basalts; oceanic crust; Pacific Ocean; petrography; plate boundaries; plate tectonics; sea-floor spreading; spreading centers; tectonics; volcanic rocks; West Pacific; West Pacific Ocean Islands;
.
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