Mount Early and Sheridan Bluff: petrology

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 bas...

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Bibliographic Details
Main Authors: K.S. Panter, J. Reindel, J.L. Smellie
Format: Article in Journal/Newspaper
Language:unknown
Published: Geological Society of London 2020
Subjects:
Geology
FOS Earth and related environmental sciences
Antarctic
East Antarctica
Sheridan Bluff
Mount Early
Antarc*
Antarctica
Online Access:https://dx.doi.org/10.6084/m9.figshare.c.5231830.v1
https://geolsoc.figshare.com/collections/Mount_Early_and_Sheridan_Bluff_petrology/5231830/1
Description
Summary: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 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 facilitated by the detachment and dehydration of metasomatized mantle lithosphere.

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