Magma–Carbonate Interaction Processes and Associated CO2 Release at Merapi Volcano, Indonesia: Insights from Experimental Petrology

Deegan, Frances M.; Troll, Valentin R.; Freda, Carmela; Misiti, Valeria; Chadwick, Jane P.; McLeod, Claire; Davidson, Jon P.

doi:10.1093/petrology/egq010

Cited by 154 publications

(169 citation statements)

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“…Previous workers (e.g. Chadwick et al 2007;Deegan et al 2010;Troll et al 2012Troll et al , 2013Borisova et al 2013) have proposed that CO 2 liberation via crustal carbonate assimilation has the potential to sustain and intensify eruptions at Merapi. Monitoring data of the 2010 eruption indicate large CO 2 emissions prior to the 2010 eruption (Surono et al 2012), and previous melt inclusions have been interpreted to reflect CO 2 fluxing at Merapi (Nadeau et al 2013).…”

Section: Clinopyroxene Crystallisation and Melt Inclusion Entrapmentmentioning

confidence: 97%

“…Clocchiatti et al 1982;Camus et al 2000;Gertisser and Keller 2003;Chadwick et al 2007;Deegan et al 2010;Troll et al 2012Troll et al , 2013. Magma-carbonate interaction liberates CO 2 through decarbonation reactions of crustal carbonates to the diopside and wollastonite assemblages observed in the xenoliths, adding to the magmatic volatile budget with the potential to sustain and intensify eruptions at Merapi (Deegan et al 2010;Troll et al 2012Troll et al , 2013.…”

Section: Merapi Magmatic System and Volatilesmentioning

confidence: 99%

“…In addition, crustal carbonate assimilation and the resulting CO 2 liberation has also been invoked to play a significant role in governing the explosivity of eruptions (Chadwick et al 2007;Deegan et al 2010;Troll et al 2012Troll et al , 2013Borisova et al 2013). Secondary ion mass spectrometry (SIMS) volatile data (CO 2 , H 2 O, F, Cl, S) of Merapi clinopyroxene and amphibole-hosted silicate melt inclusions in lava and scoria from unknown eruptive origins have recently been published by Nadeau et al (2013).…”

Section: Introductionmentioning

confidence: 99%

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Pre- and syn-eruptive degassing and crystallisation processes of the 2010 and 2006 eruptions of Merapi volcano, Indonesia

Preece

Gertisser

Barclay

et al. 2014

Contrib Mineral Petrol

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clasts resulting from sub-plinian convective column collapse. This paper presents geochemical data for melt inclusions and their clinopyroxene hosts extracted from dense dome lava, grey scoria and white pumice generated during the peak of the 2010 eruption. These are compared with clinopyroxenehosted melt inclusions from scoriaceous dome fragments from the prolonged dome-forming 2006 eruption, to elucidate any relationship between pre-eruptive degassing and crystallisation processes and eruptive style. Secondary ion mass spectrometry analysis of volatiles (H 2 O, CO 2 ) and light lithophile elements (Li, B, Be) is augmented by electron microprobe analysis of major elements and volatiles (Cl, S, F) in melt inclusions and groundmass glass. Geobarometric analysis shows that the clinopyroxene phenocrysts crystallised at depths of up to 20 km, with the greatest calculated depths associated with phenocrysts from the white pumice. Based on their volatile contents, melt inclusions have reequilibrated during shallower storage and/or ascent, at depths of ~0.6-9.7 km, where the Merapi magma system is interpreted to be highly interconnected and not formed of discrete magma reservoirs. Melt inclusions enriched in Li show uniform "buffered" Cl concentrations, indicating the presence of an exsolved brine phase. Boron-enriched inclusions also support the presence of a brine phase, which helped to stabilise B in the melt. Calculations based on S concentrations in melt inclusions and groundmass glass require a degassing melt volume of 0.36 km 3 in order to produce the mass of SO 2 emitted during the 2010 eruption. This volume is approximately an order of magnitude higher than the erupted magma (DRE) volume. The transition between the contrasting eruptive styles in 2010 and 2006 is linked to changes in magmatic flux and changes in degassing style, with the explosive activity in 2010 driven by an influx of deep magma, which overwhelmed the shallower magma system and ascended rapidly, accompanied by closed-system degassing. AbstractThe 2010 eruption of Merapi (VEI 4) was the volcano's largest since 1872. In contrast to the prolonged and effusive dome-forming eruptions typical of Merapi's recent activity, the 2010 eruption began explosively, before a new dome was rapidly emplaced. This new dome was subsequently destroyed by explosions, generating pyroclastic density currents (PDCs), predominantly consisting of dark coloured, dense blocks of basaltic andesite dome lava. A shift towards open-vent conditions in the later stages of the eruption culminated in multiple explosions and the generation of PDCs with conspicuous grey scoria and white pumice Communicated by O. Müntener. Electronic supplementary materialThe online version of this article

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Section: Clinopyroxene Crystallisation and Melt Inclusion Entrapmentmentioning

confidence: 97%

Section: Merapi Magmatic System and Volatilesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Pre- and syn-eruptive degassing and crystallisation processes of the 2010 and 2006 eruptions of Merapi volcano, Indonesia

Preece

Gertisser

Barclay

et al. 2014

Contrib Mineral Petrol

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“…Lentini, 1982;Grasso and Lentini, 1982;Pedley and Grasso, 1992), Mt. Vesuvius (Bruno et al, 1998;Iacono-Marziano et al, 2009), the Colli Albani volcanic district (Chiodini and Frondini, 2001;Iacono-Marziano et al, 2007;Freda et al, 2008;Gaeta et al, 2009;Mollo et al, 2010a) and the Campi Flegrei volcanic district (D'Antonio, 2011) in Italy, Popocatépetl volcano (Goff et al, 2001) and the Colima volcanic complex (Norini et al, 2010), both Mexico, Yellowstone volcanic system, USA (Werner and Brantley, 2003) and Merapi, Indonesia (Chadwick et al, 2007;Deegan et al, 2010;Troll et al, 2012). It becomes clear therefore, that an important element of volcano stability must focus on the understanding of the potential thermally-induced weakening of rock representative of the carbonate successions present under active volcanoes.…”

Section: Accepted M Manuscriptmentioning

confidence: 99%

Thermal weakening of the carbonate basement under Mt. Etna volcano (Italy): Implications for volcano instability

Heap

Mollo

Vinciguerra

et al. 2013

Journal of Volcanology and Geothermal Research

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The physical integrity of a sub-volcanic basement is crucial in controlling the stability of a volcanic edifice. For many volcanoes, this basement can comprise thick sequences of carbonates that are prone to significant thermally-induced alteration. These debilitating thermal reactions, facilitated by heat from proximal magma storage volumes, promote the weakening of the rock mass and likely therefore encourage edifice instability. Such instability can result in slow, gravitational spreading and episodic to continuous slippage of unstable flanks, and may also facilitate catastrophic flank collapse. Understanding the propensity of a particular sub-volcanic basement to such instability requires a detailed understanding of the influence of high temperatures on the chemical, physical, and mechanical properties of the rocks involved. The juxtaposition of a thick carbonate substratum and magmatic heat sources makes Mt. Etna volcano an ideal candidate for our study. We investigated experimentally the effect of temperature on two carbonate rocks that have been chosen to represent the deep, heterogeneous sedimentary substratum under Mt. Etna volcano. This study has demonstrated that thermalstressing resulted in a progressive and significant change in the physical properties of the two rocks. Porosity, wet (i.e., water-saturated) dynamic Poisson's ratio and wet Vp/Vs ratio all increased, whilst P-and S-wave velocities, bulk sample density, dynamic and static Young's modulus, dry Vp/Vs ratio, and dry dynamic Poisson's ratio all decreased. At temperatures of 800 °C, the carbonate in these rocks completely dissociated, resulting in a total mass loss of about 45% and the release of about 44 wt.% of CO 2 . Uniaxial deformation experiments showed that high in-situ temperatures (> 500°C) significantly reduced the strength of the carbonates and altered their deformation behaviour. Above 500 °C the rocks deformed in a ductile manner and A C C E P T E D M A N U S C R I P T ACCEPTED MANUSCRIPTthe output of acoustic emissions was greatly reduced. We speculate that thermally-induced weakening and the ductile behaviour of the carbonate substratum could be a key factor in explaining the large-scale deformation observed at Mt. Etna volcano. Our findings are consistent with several field observations at Mt. Etna volcano and can quantitatively support the interpretation of (1) the irregularly low seismic velocity zones present within the sub-volcanic sedimentary basement, (2) the anomalously high CO 2 degassing observed, (3) the anomalously high Vp/Vs ratios and the rapid migration of fluids, and (4) the increasing instability of volcanic edifices in the lifespan of a magmatic system. We speculate that carbonate sub-volcanic basement may emerge as one of the decisive fundamentals in controlling volcanic stability.

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“…Among released volcanic gases, carbon dioxide (CO 2 ) is early by an uprising magma, already at mantle depth and represents the most important contribution to diffuse degassing, whereas water (H 2 O), the most abundant magmatic volatile species, is released at shallower depths, and undergoes condensation both along its pathways toward the surface, and in the soil (Granieri et al, 2010;Di Muro et al, 2016 ). Besides magmatic degassing, soil CO 2 degassing at the surface may also be related to several other sources such as (1) mantle, (2) subducted crustal rocks and sediments, (3) carbonate rocks and, (4) biogenic components Deegan et al, 2010;Troll et al, 2012;Burton et al, 2013;Dionis et al, 2015). Carbon isotopic composition is a useful tool to discriminate between these different sources of CO 2 emissions and to reveal potential mixing among gases deriving from different sources.…”

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confidence: 99%

Investigating the deepest part of a volcano plumbing system: Evidence for an active magma path below the western flank of Piton de la Fournaise (La Réunion Island)

Boudoire

Liuzzo

Muro

et al. 2017

Journal of Volcanology and Geothermal Research

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Peripheral diffuse degassing of CO 2 from the soil occurs across the western flank of Piton de la Fournaise volcano (La Réunion Island, Indian Ocean) along a narrow zone. In this area, carbon isotopic analysis on soil gas samples highlights significant mixing between magmatic and organic end-members. The zones with the strongest magmatic signature (highest δ 13 C) overlap spatial distribution of hypocenters recorded shortly before and during volcano reactivation and allow discriminating a N135° degassing lineament, with a minimum length of 11 km and 140 ± 20 m-width. Such orientation is in accordance with that of an old dyke network along the rift zone and with N120-130° and N140-155° lineaments related to the inheritance of oceanic lithosphere structures. Our findings show that this N135° lineament represents a preferential magmatic pathway for deep magma transfer below the volcano flank. Moreover, spatial distributions of recent eccentric cones indicate a well-founded possibility that future eruptions may by-pass the shallow plumbing system of the central area of the volcano, taking a lateral pathway along this structure. Our results also confirm that Piton de la Fournaise activity is linked to a laterally shifted plumbing system and represent a major improvement in identifying the main high-risk area on the densely populated western flank of the volcano.

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Magma–Carbonate Interaction Processes and Associated CO2 Release at Merapi Volcano, Indonesia: Insights from Experimental Petrology

Cited by 154 publications

References 81 publications

Pre- and syn-eruptive degassing and crystallisation processes of the 2010 and 2006 eruptions of Merapi volcano, Indonesia

Pre- and syn-eruptive degassing and crystallisation processes of the 2010 and 2006 eruptions of Merapi volcano, Indonesia

Thermal weakening of the carbonate basement under Mt. Etna volcano (Italy): Implications for volcano instability

Investigating the deepest part of a volcano plumbing system: Evidence for an active magma path below the western flank of Piton de la Fournaise (La Réunion Island)

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