Volcanism in Antarctica: 200 Million Years of Subduction, Rifting and Continental Break-up
CONTAINS OPEN ACCESS
This memoir is the first to review all of Antarctica's volcanism between 200 million years ago and the Present. The region is still volcanically active. The volume is an amalgamation of in-depth syntheses, which are presented within distinctly different tectonic settings. Each is described in terms of (1) the volcanology and eruptive palaeoenvironments; (2) petrology and origin of magma; and (3) active volcanism, including tephrochronology. Important volcanic episodes include: astonishingly voluminous mafic and felsic volcanic deposits associated with the Jurassic break-up of Gondwana; the construction and progressive demise of a major Jurassic to Present continental arc, including back-arc alkaline basalts and volcanism in a young ensialic marginal basin; Miocene to Pleistocene mafic volcanism associated with post-subduction slab-window formation; numerous Neogene alkaline volcanoes, including the massive Erebus volcano and its persistent phonolitic lava lake, that are widely distributed within and adjacent to one of the world's major zones of lithospheric extension (the West Antarctic Rift System); and very young ultrapotassic volcanism erupted subglacially and forming a world-wide type example (Gaussberg).
Chapter 5.3b Mount Early and Sheridan Bluff: petrology
Correspondence: [email protected]
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Published:May 27, 2021
Abstract
This study discusses the petrological and geochemical features of two monogenetic Miocene volcanoes, Mount Early and Sheridan Bluff, which are the above-ice expressions of Earth's southernmost volcanic field located at c. 87° S on the East Antarctic Craton. Their geochemistry is compared to basalts from the West Antarctic Rift System to test affiliation and resolve mantle sources and cause of melting beneath East Antarctica. Basaltic lavas and dykes are olivine-phyric and comprise alkaline (hawaiite and mugearite) and subalkaline (tholeiite) types. Trace element abundances and ratios (e.g. La/Yb, Nb/Y, Zr/Y) of alkaline compositions resemble basalts from the West Antarctic rift and ocean islands (OIB), while tholeiites are relatively depleted and approach the concentrations levels of enriched mid-ocean ridge basalt (E-MORB). The magmas evolved by fractional crystallization with contamination by crust; however, neither process can adequately explain the contemporaneous eruption of hawaiite and tholeiite at Sheridan Bluff. Our preferred scenario is that primary magmas of each type were produced by different degrees of partial melting from a compositionally similar mantle source. The nearly simultaneous generation of lower degrees of melting to produce alkaline types and higher degrees of melting forming tholeiite was most likely to have been facilitated by the detachment and dehydration of metasomatized mantle lithosphere.
- alkali basalts
- Antarctica
- basaltic composition
- basalts
- Cenozoic
- chemical composition
- chemical ratios
- dates
- dikes
- hawaiite
- igneous rocks
- intrusions
- lapilli
- lava
- lithosphere
- mantle
- melting
- mid-ocean ridge basalts
- Neogene
- pillow lava
- pyroclastics
- Queen Maud Range
- rift zones
- Tertiary
- tholeiite
- tholeiitic basalt
- trace elements
- Transantarctic Mountains
- tuff
- volcanic fields
- volcanic rocks
- volcanism
- Scott Glacier
- Mount Early
- Sheridan Bluff
- McMurdo Volcanic Group
- West Antarctic Rift System
- Meander Intrusive Group
- Upper Scott Glacier volcanic field
- Western Ross Supergroup