Research Seminar: 'The ignimbrites of Terceira: a petrogenetic puzzle of peralkaline pyroclastics'

Research Seminar: 'The ignimbrites of Terceira: a petrogenetic puzzle of peralkaline pyroclastics'
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This is a past event

Please join us for a research seminar to be given by Dr Adam Jeffery of Keele University on ‘The ignimbrites of Terceira: a petrogenetic puzzle of peralkaline pyroclastics’. The seminar will take place on Nov. 16th at 13:00-14:00 in Meston Lecture Theatre 2. All are welcome to attend.

Abstract

The recent (< 100 ka) volcanic stratigraphy of Terceira, Azores, includes at least seven peralkaline trachytic ignimbrite formations, attesting to a history of explosive eruptions. In this study, the petrogenesis and pre-eruptive storage conditions of the ignimbrite-forming magmas are investigated via whole-rock major and trace element geochemistry, melt inclusion and groundmass glass major element and volatile compositions, mineral chemistry, thermobarometrical models, and petrogenetic modelling. The primary aims of this contribution are to develop a model for the magmatic plumbing system from which the ignimbrite-forming trachytes of Terceira were produced by evaluating various petrogenetic processes and constraining pre-eruptive magma storage conditions. We also place the ignimbrite-forming magmas into the context of the Terceira suite, and discuss potential implications of pre-eruptive magma conditions for eruptive behaviour.

Results indicate that the ignimbrite-forming comenditic trachytes are generated predominantly by extended fractional crystallisation of basaltic parental magmas at redox conditions around 1 log unit below the fayalite-magnetite-quartz buffer. This was achieved via a polybaric fractionation pathway, in which mantle-derived basalts stall and fractionate to hawaiitic compositions at lower crustal depths (~ 15 km), before ascending to a shallow crustal magma storage zone (~ 2 to 4 km) and fractionating towards comenditic trachytic compositions. The most evolved pantelleritic magmas of Terceira (not represented by the ignimbrites) are plausibly generated by continued fractionation from the comenditic trachytes. Syenite autoliths represent portions of peralkaline trachytic melt which crystallised in-situ at the margins of a silicic reservoir. Trachytic enclaves hosted within syenitic autoliths provide direct evidence for a two-stage mingling process, in which ascending hawaiites are mixed with trachytic magmas in the shallow crustal magma storage zone. The resulting hybridised trachytes then ascend further and mix with the more evolved peralkaline trachytes in the uppermost cap of the system, passing first through a syenitic crystal mush. The reduced viscosities of the peralkaline silicic magmas of this study in relation to their metaluminous counterparts facilitate rapid crystal-melt segregation via crystal settling, generating compositionally zoned magma bodies and, in some instances, relatively crystal-poor erupted magmas. Reduced viscosity may also inhibit highly explosive activity (e.g. formation of a sustained eruption column), and limit the majority of explosive eruptions to low pyroclastic fountaining or ‘boil-over’ eruption styles. The formation of intermediate magmas within the system is considered to be limited to episodic mixing between mafic and silicic magmas.

Venue
Meston Lecture Theatre 2