Effect of melt composition on crustal carbonate assimilation: Implications for the transition from calcite consumption to skarnification and associated <scp>CO</scp><sub>2</sub> degassing

Carter, Laura B.; Dasgupta, Rajdeep

doi:10.1002/2016gc006444

Cited by 42 publications

(26 citation statements)

References 167 publications

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“…This temperature is consistent with the clinopyroxene saturation temperatures calculated from the magmatic skarn xenolith glasses (755–917 °C, Equation 34 57 ). This thermometer reproduces experimental low temperature 900 °C carbonate assimilation data 48 within the published error of 45 °C. Varying temperatures (e.g.…”

Section: Methodssupporting

confidence: 78%

“…Our modelling results, and the general paucity of relict calcite in the xenoliths, demonstrate that magma-carbonate interaction at Merapi is very efficient at remobilising crustal CO 2 into the magmatic system and ultimately the atmosphere. Crustal carbonate assimilation has been shown to be an important contributor to CO 2 output at Merapi 11,12,48 and a widespread occurrence in arc volcanoes, which may even dwarf contributions from source contamination 1,2 . We have used a mass balance model 49 (see methods) to place constraints on the amount of crustal CO 2 produced at Merapi.…”

Section: Discussionmentioning

confidence: 99%

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Crustal CO2 contribution to subduction zone degassing recorded through calc-silicate xenoliths in arc lavas

Whitley

Gertisser

Halama

et al. 2019

Sci Rep

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Interaction between magma and crustal carbonate at active arc volcanoes has recently been proposed as a source of atmospheric CO 2 , in addition to CO 2 released from the mantle and subducted oceanic crust. However, quantitative constraints on efficiency and timing of these processes are poorly established. Here, we present the first in situ carbon and oxygen isotope data of texturally distinct calcite in calc-silicate xenoliths from arc volcanics in a case study from Merapi volcano (Indonesia). Textures and C-O isotopic data provide unique evidence for decarbonation, magma-fluid interaction, and the generation of carbonate melts. We report extremely light δ 13 C PDB values down to −29.3‰ which are among the lowest reported in magmatic systems so far. Combined with the general paucity of relict calcite, these extremely low values demonstrate highly efficient remobilisation of crustal CO 2 over geologically short timescales of thousands of years or less. This rapid release of large volumes of crustal CO 2 may impact global carbon cycling.

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Section: Methodssupporting

confidence: 78%

Section: Discussionmentioning

confidence: 99%

Crustal CO2 contribution to subduction zone degassing recorded through calc-silicate xenoliths in arc lavas

Whitley

Gertisser

Halama

et al. 2019

Sci Rep

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“…In terms of phase relations, this reaction zone might not be different from skarns. Whereas some skarns form when silicate magma or derived fluids intrude a carbonate rock (see for example, Carter and Dasgupta, 2016), our experiments show the reaction of carbonatite magma with silicate rock: an "antiskarn". The mineral assemblage of our "antiskarns" (diopside, calcite, vesuvianite, wollastonite, also cuspidine, monticellite and magnesioferrite in run D2332) highly resembles the assemblage of hydrothermal skarns, raising the possibility that some skarns or mineralogically similar rocks may in fact be paleoconduits of carbonatite magma as it traversed the crust.…”

Section: Carbonatite Metasomatismmentioning

confidence: 68%

“…However, the genetic term "endoskarn" implies the presence of a silicate intrusion and an aqueous fluid -neither of which are present in antiskarns. Alternatively, endoskarns may form by direct assimilation of carbonates by the silicate magmas at high temperatures (Di Rocco and others, 2012;Carter and Dasgupta, 2016). Like fenitic fluids, the skarn-forming metasomatic aqueous fluid exsolves due to decompression and crystallization of a pluton at shallow depths (Ͻ 5 kbar, Meinert, 1993), whereas the metasomatism of antiskarns results from direct reaction of a carbonatite with silicate wall rocks at mid-crustal depths (Ͼ 5 kbar).…”

Section: Comparison With Fenites and Endoskarnsmentioning

confidence: 99%

Carbonatitic versus hydrothermal origin for fluorapatite REE-Th deposits: Experimental study of REE transport and crustal “antiskarn” metasomatism

Anenburg

Mavrogenes

2018

Am J Sci

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Nolans-type ore deposits contain REE and Th mineralization hosted in fluorapatite veins. These veins intrude granulite facies rocks and are surrounded by a diopside selvage. Nolans-type deposits are thought to form by REE, F and P-rich hydrothermal fluids derived from alkali or carbonatitic intrusions. However, REE are not effectively transported in F and P-rich systems. REE ore deposits are commonly hydrothermally overprinted, possibly obscuring the igneous nature of the primary mineralization. We conducted a series of piston cylinder "sandwich" experiments, testing the hydrothermal fluid hypothesis, and a newly suggested process of carbonatite metasomatism. Our results confirm theoretical predictions that REE are hydrothermally immobile in these systems and the experimental phase assemblage is not compatible with the natural rocks. Our results show that fluorapatite can only host several weight percent levels of REE at temperatures higher than ϳ600°C. Below that temperature, a miscibility gap exists between REE-poor fluorapatite and REE-rich silicates such as britholite or cerite. In contrast, experiments reacting P and REE-rich carbonatite with silicate rock above 700°C closely resemble natural rocks from Nolans-type deposits. Selvage mineralogy is sensitive to the MgO content of the carbonatite. A diopside selvage formed at carbonatite MgO/(CaO؉MgO) Ϸ 0.2 while wollastonite and forsterite formed at lower and higher ratios, respectively. Phosphate solubility in carbonatites decreases with decreasing MgO contents. As diopside formed, REE-rich fluorapatite preferentially crystallized from the selvage inwards. Thus, carbonatites are effective at simultaneously mobilizing REE, F and P to the site of deposition. Nolans-type deposits are the cumulate residue of this reaction, with the carbonatite liquid migrating elsewhere. At temperatures below 700°C the carbonatitesilicate reaction additionally formed monticellite, cuspidine and magnesioferrite, resembling a skarn assemblage. Whereas skarns form by infiltration of silicate magmas or related fluids to carbonate rocks, our experiments are the opposite: intrusion of carbonatite into silicate rock. These mid-crustal skarn-like rocks may host elevated ore elements of carbonatitic affinity, such as F, P, Y, REE, Th, Ba, Sr, and Nb. We propose the term "antiskarn" to describe such systems, and suggest they trace the migration of carbonatite liquids through the crust. Hydrothermal reworking, retrogression, or metamorphism of antiskarns may obscure the carbonatitic genesis of the rocks. These metasomatic zones are the crustal equivalent of wehrlites that form by peridotitecarbonatite reaction at mantle depths.

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“…Without information regarding the rocks in which the magma intrudes, only magmatic CO 2 fluxes from continental arcs can be approximated. Experiments replicating sub-arc and lower crustal conditions show that carbonate rock can be almost wholly decarbonated (Carter and Dasgupta, 2016), which has been corroborated by observations of extremely low 13 C/ 12 C ratios of calc-silicate xenoliths from the Merapi volcano (Whitley et al, 2019). The degree to which continental arc magmas completely decarbonate their host rocks is unknown, but given the relatively open-system nature of continental arcs, these findings likely reflect upper limits for decarbonation rates.…”

Section: Introductionmentioning

confidence: 73%

Remnants and Rates of Metamorphic Decarbonation in Continental Arcs

Ramos¹,

Lackey²,

Barnes³

et al. 2020

GSAT

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Metamorphic decarbonation in magmatic arcs remains a challenge to impose in models of the geologic carbon cycle. Crustal reservoirs and metamorphic fluxes of carbon vary with depth in the crust, rock types and their stratigraphic succession, and through geologic time. When byproducts of metamorphic decarbonation (e.g., skarns) are exposed at Earth's surface, they reveal a record of reactive transport of carbon dioxide (CO 2 ). In this paper, we discuss the different modes of metamorphic decarbonation at multiple spatial and temporal scales and exemplify them through roof pendants of the Sierra Nevada batholith. We emphasize the utility of analogue models for metamorphic decarbonation to generate a range of decarbonation fluxes throughout the Cretaceous. Our model predicts that metamorphic CO 2 fluxes from continental arcs during the Cretaceous were at least 2 times greater than the present cumulative CO 2 flux from volcanoes, agreeing with previous estimates and further suggesting that metamorphic decarbonation was a principal driver of the Cretaceous hothouse climate. We lastly argue that our modeling framework can be used to quantify decarbonation fluxes throughout the Phanerozoic and thereby refine Earth systems models for paleoclimate reconstruction.

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Effect of melt composition on crustal carbonate assimilation: Implications for the transition from calcite consumption to skarnification and associated CO₂ degassing

Cited by 42 publications

References 167 publications

Crustal CO2 contribution to subduction zone degassing recorded through calc-silicate xenoliths in arc lavas

Crustal CO2 contribution to subduction zone degassing recorded through calc-silicate xenoliths in arc lavas

Carbonatitic versus hydrothermal origin for fluorapatite REE-Th deposits: Experimental study of REE transport and crustal “antiskarn” metasomatism

Remnants and Rates of Metamorphic Decarbonation in Continental Arcs

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Effect of melt composition on crustal carbonate assimilation: Implications for the transition from calcite consumption to skarnification and associated CO2 degassing

Cited by 42 publications

References 167 publications

Crustal CO2 contribution to subduction zone degassing recorded through calc-silicate xenoliths in arc lavas

Crustal CO2 contribution to subduction zone degassing recorded through calc-silicate xenoliths in arc lavas

Carbonatitic versus hydrothermal origin for fluorapatite REE-Th deposits: Experimental study of REE transport and crustal “antiskarn” metasomatism

Remnants and Rates of Metamorphic Decarbonation in Continental Arcs

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Effect of melt composition on crustal carbonate assimilation: Implications for the transition from calcite consumption to skarnification and associated CO₂ degassing