Nature of sub-volcanic magma chambers, Deccan Province, India: Evidence from quantitative textural analysis of plagioclase megacrysts in the giant plagioclase basalts

Sub-volcanic magma chambers might be a widespread component of flood basalt provinces, and their presence can be revealed in some cases by plagioclase megacrystic basalts. In at least four levels within the Deccan flood basalt sequence the generally low abundance of small plagioclase crystals increa...

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Bibliographic Details
Published in:Journal of Petrology
Main Authors: HIGGINS, MD, CHANDRASEKHARAM, D
Format: Article in Journal/Newspaper
Language:English
Published: OXFORD UNIV PRESS 2007
Subjects:
Crystal Size Distributions
Skaergaard Intrusion
Distribution Csd
Flood Basalts
Crystallization
Rocks
Eruption
Constraints
Dynamics
Kinetics
Texture
Microstructure
Continental Basalt
Megacrysrt
Plagioclase
Crystal Shape
Galapagos
Sept Iles
Surtsey
Online Access:http://dspace.library.iitb.ac.in/xmlui/handle/10054/10348
https://doi.org/10.1093/petrology/egm005
http://hdl.handle.net/10054/10348
Description
Summary:Sub-volcanic magma chambers might be a widespread component of flood basalt provinces, and their presence can be revealed in some cases by plagioclase megacrystic basalts. In at least four levels within the Deccan flood basalt sequence the generally low abundance of small plagioclase crystals increases to 5-25%, with some as large as 30 mm long. These Giant Plagioclase Basalt (GPB) flows were formed by mixing of megacryst-rich and megacyst poor magmas. The crystal size distributions (CSD) of these megacrysts mostly plot as almost straight lines on a classic CSD diagram. For a plagioclase, growth rate of 10(-10) mm/s steady-state magma chamber models and simple continuous growth suggest residence tunes of 500-1500 years. However the lack of crystals smaller than 2 arm suggests that coarsening may have been involved and crystal shape can help define the environment where this happened. Plagioclase megacrysts are very tabular and commonly form clusters of sub parallel crystals, characteristics that are also found in the plagioclase of anorthosites formed by flotation at the top of shallow magma chambers and crystallization in a high Peclet number regime (e.g Skaergaard; Sept Iles). A possible history is as follows. (1) Plagioclase megacrysts crystallize in a connecting magma chamber just below the lava pile. (2) Currents sweep the crystals to the top of the chamber, where they accumulate as a result of their buoyancy. The crystals coarsen in response to the continuous supply of hot magma. (3) New magma sweeps through the plagioclase mush, mingles and mixes, then erupts to form the GPBs. The residence time recorded by the megacrysts in the GPBs is that of the magma chamber where the megacrysts formed, not that of the magmas that make up the megacryst-poor part of the GPBs or the other megacryst poor lavas. Lavas with megacrysts similar to the GPBs are uncommon but widespread (Galapagos, Surtsey, etc.), and suggest the presence of sub-volcanic magma chambers elsewhere.

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