Chemical differentiation, cold storage and remobilization of magma in the Earth’s crust

Jackson, Matthew D.; Blundy, Jon; Sparks, R. S. J.

doi:10.1038/s41586-018-0746-2

Cited by 238 publications

(241 citation statements)

References 90 publications

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“…Moreover, these eruptible magma chambers and the upper reaches of their surrounding crystal-rich reservoirs reflect transcrustal magma systems that extend vertically into the lower crust (Cashman et al, 2017). Yet the architecture of such transcrustal systems (Marsh, 2015), the mechanisms and rates of melt transport through their mostly cool crystalline mush columns (Jackson et al, 2018), and the thermochemical conditions required to generate and store significant volumes of eruptible magma in shallow chambers that form within them (Barboni et al, 2016;Cooper & Kent, 2014) all remain elusive.…”

Section: Introductionmentioning

confidence: 99%

Magma Reservoir Below Laguna del Maule Volcanic Field, Chile, Imaged With Surface‐Wave Tomography

et al. 2019

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The Laguna del Maule (LdM) volcanic field comprises the greatest concentration of postglacial rhyolite in the Andes and includes the products of ~40 km3 of explosive and effusive eruptions. Recent observations at LdM by interferometric synthetic aperture radar and global navigation satellite system geodesy have revealed inflation at rates exceeding 20 cm/year since 2007, capturing an ongoing period of growth of a potentially large upper crustal magma reservoir. Moreover, magnetotelluric and gravity studies indicate the presence of fluids and/or partial melt in the upper crust near the center of inflation. Petrologic observations imply repeated, rapid extraction of rhyolitic melt from crystal mush stored at depths of 4–6 km during at least the past 26 ka. We utilize multiple types of surface‐wave observations to constrain the location and geometry of low‐velocity domains beneath LdM. We present a three‐dimensional shear‐wave velocity model that delineates a ~450‐km3 shallow magma reservoir ~2 to 8 km below surface with an average melt fraction of ~5%. Interpretation of the seismic tomography in light of existing gravity, magnetotelluric, and geodetic observations supports this model and reveals variations in melt content and a deeper magma system feeding the shallow reservoir in greater detail than any of the geophysical methods alone. Geophysical imaging of the LdM magma system today is consistent with the petrologic inferences of the reservoir structure and growth during the past 20–60 kyr. Taken together with the ongoing unrest, a future rhyolite eruption of at least the scale of those common during the Holocene is a reasonable possibility.

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Section: Introductionmentioning

confidence: 99%

Magma Reservoir Below Laguna del Maule Volcanic Field, Chile, Imaged With Surface‐Wave Tomography

et al. 2019

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“…The worldwide compositional abundances of igneous rocks, including both volcanic and plutonic settings, show bimodal peaks at basaltic and rhyolitic compositions, referred to as the Daly gap (Daly, 1925). One of the key processes contributing to the formation of compositional gaps is fractional crystallization (Clague, 1978;Dufek & Bachmann, 2010;Jackson et al, 2018), a reactive transport process that requires crystals to precipitate from the melt and segregate from their residual melt. While some authors (e.g., Bonnefoi et al, 1995) have hypothesized that fractional crystallization leads to even distributions of composition, studies of compaction show variable efficiency of fractional crystallization (Dufek & Bachmann, 2010;Jackson et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Crystal Fractionation by Crystal‐Driven Convection

Culha

Suckale

Keller

et al. 2020

Geophysical Research Letters

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Fractional crystallization is an essential process proposed to explain worldwide compositional abundances of igneous rocks. It requires crystals to precipitate from the melt and segregate from its residual melt, or experience crystal fractionation. The compositional abundances of volcanic systems show a bell curve distribution suggesting that the process has variable efficiencies. We test crystal fractionation efficiency in convective flow in low to intermediate crystallinity regime. We simulate the physical segregation of crystals from their residual melt at the scale of individual crystals, using a direct numerical method. We find that at low particle Reynolds numbers, crystals sink in clusters. The relatively rapid motion of clusters strips away residual melt. Our results show cluster settling can imprint observational signatures at the crystalline scale. The collective crystal behavior results in a crystal convection that governs the efficiency of crystal fractionation, providing a possible explanation for the bell curve distribution in volcanic systems.

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“…We performed thermal modelling of pulsed magma injection into the mid to lower crust coupled to experimental phase relations 32 , which allows us to track the temporal evolution of eruptible magma chemistry. Our model design builds on the theory that silicic magmas originate at mid to deep crustal levels 14,24,25,26,27,52 and that magmatic bodies are built over protracted periods of time by incremental assembly 30,31 .…”

Section: Methodsmentioning

confidence: 99%

“…To establish the link between magma recharge rates and the evolution of eruptible magma chemistries in mid crustal reservoirs, we developed a numerical model that couples heat transfer and phase petrology. The design of our model is motivated by geophysical 21,22,23 and petrological 14,24,25,26,27,28,32,52 data, which show that magmas acquire their chemistry mostly at mid to lower crustal depths, before being erupted. We do not simulate magma extraction and eruption, but we trace the evolution in the chemistry of potentially eruptible magma over time, using this as a proxy for what is likely be sampled in eruptions.…”

Section: Thermal and Petrological Modellingmentioning

confidence: 99%

Magma diversity reflects recharge regime and thermal structure of the crust

Weber¹,

Simpson²,

Caricchi³

2020

Preprint

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The chemistry of magmas erupted by volcanoes is a message from deep within the Earth's crust, which if decrypted, can provide essential information on magmatic processes occurring at inaccessible depths. While some volcanoes are prone to erupt magmas of a wide compositional variety, others sample rather monotonous chemistries through time. Whether such differences are a consequence of physical filtering or reflect intrinsic properties of different magmatic systems remains unclear. Here we show, using thermal and petrological modelling, that magma flux and the thermal structure of the crust modulate diversity and temporal evolution of magma chemistry in mid to deep crustal reservoirs. Our analysis shows that constant rates of magma input leads to eruptible magma compositions that tend to evolve from felsic to more mafic in time. Low magma injection rates into hot or deep crust produces less chemical variability of eruptible magma compared to the injection of large batches in colder or shallower crust. Our calculations predict a correlation between magma fluxes and compositional diversity that resembles trends observed in volcanic deposits. Our approach allows retrieval of quantitative information about magma input and the thermal architecture of magmatic systems from the chemical diversity and temporal evolution of volcanic products.

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Chemical differentiation, cold storage and remobilization of magma in the Earth’s crust

Cited by 238 publications

References 90 publications

Magma Reservoir Below Laguna del Maule Volcanic Field, Chile, Imaged With Surface‐Wave Tomography

Magma Reservoir Below Laguna del Maule Volcanic Field, Chile, Imaged With Surface‐Wave Tomography

Crystal Fractionation by Crystal‐Driven Convection

Magma diversity reflects recharge regime and thermal structure of the crust

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