The evolution and storage of primitive melts in the Eastern Volcanic Zone of Iceland: the 10 ka Grímsvötn tephra series (i.e. the Saksunarvatn ash)

Neave, David A.; Maclennan, J.; Thordarson, T.; Hartley, Margaret E.

doi:10.1007/s00410-015-1170-3

Cited by 40 publications

(64 citation statements)

References 129 publications

(198 reference statements)

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“…Sigmarsson et al ., ]. We note here, however, that the clinopyroxene mineral‐melt thermobarometry after Putirka [] has recently been suspected of potentially overpredicting crystallization pressures for Icelandic magmas [ Neave et al ., ]. Yet as there is no specific calibration for Icelandic magmas available and as mineral‐melt thermobarometry results are in general agreement with the bimodality obtained from OPAM pressure calculations on groundmass and whole rock compositions (see section 3.2 above), we argue that the approach employed here produces the currently most viable depth estimates of crystallization for the Holuhraun system.…”

Section: Discussionsupporting

confidence: 68%

Magma plumbing for the 2014–2015 Holuhraun eruption, Iceland

Geiger

Mattsson

Deegan

et al. 2016

Geochem Geophys Geosyst

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The 2014–2015 Holuhraun eruption on Iceland was located within the Askja fissure swarm but was accompanied by caldera subsidence in the Bárðarbunga central volcano 45 km to the southwest. Geophysical monitoring of the eruption identified a seismic swarm that migrated from Bárðarbunga to the Holuhraun eruption site over the course of two weeks. In order to better understand this lateral connection between Bárðarbunga and Holuhraun, we present mineral textures and compositions, mineral‐melt‐equilibrium calculations, whole rock and trace element data, and oxygen isotope ratios for selected Holuhraun samples. The Holuhraun lavas are compositionally similar to recorded historical eruptions from the Bárðarbunga volcanic system but are distinct from the historical eruption products of the nearby Askja system. Thermobarometry calculations indicate a polybaric magma plumbing system for the Holuhraun eruption, wherein clinopyroxene and plagioclase crystallized at average depths of ∼17 km and ∼5 km, respectively. Crystal resorption textures and oxygen isotope variations imply that this multilevel plumbing system facilitated magma mixing and assimilation of low‐δ18O Icelandic crust prior to eruption. In conjunction with the existing geophysical evidence for lateral migration, our results support a model of initial vertical magma ascent within the Bárðarbunga plumbing system followed by lateral transport of aggregated magma batches within the upper crust to the Holuhraun eruption site.

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Section: Discussionsupporting

confidence: 68%

Magma plumbing for the 2014–2015 Holuhraun eruption, Iceland

Geiger

Mattsson

Deegan

et al. 2016

Geochem Geophys Geosyst

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“…Indeed, recent work has highlighted the possibility that incomplete closure of the melt inclusions at depth or decrepitation of the inclusions followed by healing9 at different depths (Métrich and Wallace, 2008). Neave et al (2015) came to the similar conclusion 270 that melt inclusions from r msv tn, Iceland, must have lost CO 2 upon ascent to shallow depths. If this 271 second possibility is correct, bubbles in El Hierro melt inclusions do not contain significant amounts of 272 CO 2 , but most of the originally dissolved CO 2 was lost by deep degassing of the primitive basanite 273 prior to final melt inclusion entrapment.…”

Section: Deep Co 2 Degassing and Pressures Of Melt Inclusion Entrapmementioning

confidence: 73%

Mantle to surface degassing of carbon- and sulphur-rich alkaline magma at El Hierro, Canary Islands

Longpré

Stix

Klügel

et al. 2017

Earth and Planetary Science Letters

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“…Clinopyroxene is the second‐crystallizing silicate phase in the Emeishan mafic magmas, and its saturation in the magma is closely related to melt composition and crystallization pressure (e.g., Danyushevsky, ; Ghiorso & Sack, ; Grove et al, ; Langmuir et al, ). The major and trace element compositions in the melts are coupled during partial melting (e.g., Neave et al, ; Ren et al, ; Winpenny & Maclennan, ). In the case of the Emeishan mafic magmas, the high‐Ti melts have higher Ce, Nd contents, and Ce/Y, Ce/Yb ratios and are formed by lower degrees of partial melting at greater depths than low‐Ti melts (Ren et al, ; Wang et al, ; Xu et al, ).…”

Section: Discussionmentioning

confidence: 99%

Melt Diversity and Magmatic Evolution in the Dali Picrites, Emeishan Large Igneous Province

Ren

Handler

et al. 2018

JGR Solid Earth

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Picrites are potentially near‐primary melts that offer rare insights into the earliest stages of magmatic evolution. However, without detailed investigation of magmatic processes, robust records of early melt evolution and mantle melting behavior cannot be acquired. Here petrological and geochemical interrogations of the Dali picrites were conducted to investigate the magmatic processes. Compositional variation observed in the Dali picrites is dominated by variable accumulation of a wehrlitic assemblage, transported by a low MgO carrier melt. Groundmass clinopyroxenes were produced by direct crystallization of the carrier melt. In contrast, compositions of olivine‐hosted melt inclusions and clinopyroxene macrocrysts indicate that olivine and clinopyroxene macrocrysts crystallized from diverse melt batches that are genetically related to the carrier melt, which formed as a consequence of magma mixing. The compositional range of melts in equilibrium with clinopyroxene macrocrysts with Mg# < 88 (> 88) is similar to (notably smaller than) the range of melt inclusions hosted in olivine macrocrysts with equivalent forsterite values. This observation can be explained by coupling between major and trace elements during partial melting in the mantle. Overall, a process involving periodic magma replenishment, tapping, and fractional crystallization in deep magma chamber(s) can explain the compositional variations recorded in the Dali macrocryst assemblage. Close genetic relationships between macrocrysts and carrier melts appear to be common to many primitive mafic rocks, which may reflect common deep magma chamber processes whereby diverse mantle‐derived melts are injected and evolved, and the primitive macrocrysts thus formed are subsequently transported by mixed liquids, producing macrocryst‐bearing primitive mafic rocks.

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The evolution and storage of primitive melts in the Eastern Volcanic Zone of Iceland: the 10 ka Grímsvötn tephra series (i.e. the Saksunarvatn ash)

Cited by 40 publications

References 129 publications

Magma plumbing for the 2014–2015 Holuhraun eruption, Iceland

Magma plumbing for the 2014–2015 Holuhraun eruption, Iceland

Mantle to surface degassing of carbon- and sulphur-rich alkaline magma at El Hierro, Canary Islands

Melt Diversity and Magmatic Evolution in the Dali Picrites, Emeishan Large Igneous Province

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