Skip to main content Accessibility help
×
Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-26T16:01:15.891Z Has data issue: false hasContentIssue false

6 - CO2-Rich Melts in Earth

Published online by Cambridge University Press:  03 October 2019

Beth N. Orcutt
Affiliation:
Bigelow Laboratory for Ocean Sciences, Maine
Isabelle Daniel
Affiliation:
Université Claude-Bernard Lyon I
Rajdeep Dasgupta
Affiliation:
Rice University, Houston

Summary

This chapter reviews the systematics of partial melting of mantle lithologies – like peridotite and eclogite – in the presence of carbon dioxide. It discusses the composition of mantle-derived magmas generated in the presence of carbon dioxide and whether magmas erupted on Earth’s surface resemble carbonated magmas from the mantle. It reviews how the production of carbon dioxide-rich magma in the mantle varies as a function of tectonic settings – beneath continents and oceans and in subduction zones – and time.

Type
Chapter
Information
Deep Carbon
Past to Present
, pp. 129 - 162
Publisher: Cambridge University Press
Print publication year: 2019
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - SA
This content is Open Access and distributed under the terms of the Creative Commons Attribution licence CC-BY-NC-SA 4.0 https://creativecommons.org/cclicenses/

6.1 Introduction

Carbonate-rich magmas in Earth play a critical role in Earth’s deep carbon cycle. They have been emplaced into or erupted onto the crust as carbonatites (i.e. igneous rocks composed of >50% carbonate minerals, with SiO2 contents <20 wt.%) for the last 2.5 Ga of geological history, and one volcano (Oldoinyo Lengai, Tanzania) has erupted sodic carbonatite lavas since 1960.Reference Dawson1

Carbonate melts are inferred to exist in the upper mantle, largely on the basis of high-pressure experimental studies.Reference Wyllie, Baker and White2Reference Dasgupta and Hirschmann6 Their existence has also been inferred from the mineralogy and geochemistry of some suites of peridotite xenoliths recovered from alkali basalts,Reference Yaxley, Crawford and Green7Reference Rudnick, Mcdonough and Chappell9 and they have been observed directly in some inclusions in diamondsReference Weiss, McNeill, Pearson, Nowell and Ottley10 and minerals in sheared garnet peridotite xenoliths.Reference Golovin, Sharygin, Kamenetsky, Korsakov and Yaxley11 They may also be present in the mantle transition zone or lower mantle in association with deeply subducted, carbonate-bearing slabsReference Kiseeva, Litasov, Yaxley, Ohtani and Kamenetsky12Reference Litasov and Ohtani14 and as inclusions in lower-mantle diamonds.Reference Kaminsky15

Because of their low density, low viscosity, and ability to wet the surfaces of silicate minerals in the mantle,Reference Hunter and Mckenzie16Reference Shatskiy18 carbonate melts are able to migrate upwards from their source regions rapidly and at extremely low melt fractions. They are able to transport significant amounts of incompatible trace and minor elements, volatile elements (H2O, halogens, sulfur), and major components such as C, Mg, Ca, Fe, Na, and K. This renders them highly effective metasomatic agents and potentially major contributors to fluxes of carbon between reservoirs in the deep and shallow Earth. They are also of particular economic importance as hosts or sources of many critical metals, including the rare earth elements (REEs) Nb, Ta, P, and others.

In this chapter, we review the current understanding of the occurrence, stability, and role of carbonatites emplaced into or onto Earth’s crust and carbonate melts in the deep Earth, from lower mantle to crust. We first outline constraints from high-pressure experimental petrology and thermodynamic considerations on their stability, as functions of variables such as pressure (P), temperature (T), and oxygen fugacity (fO2). These constraints are then used in the context of different tectonic settings in Earth to infer the presence and nature of carbonate melts in those various locations.

Carbonate melts and carbonatite magmas are also often proposed to be genetically linked to some CO2-bearing silicate melts (melts with >20 wt.% SiO2 and dissolved, oxidized carbon, such as kimberlites, intraplate basalts, continental alkali basalts, etc.) through processes such as carbonate–silicate liquid immiscibility, crystal fractionation, and oxidation of diamond or graphite. Genetic relationships between carbonate melts and CO2-bearing silicate melts in appropriate settings are also considered in this chapter.

6.2 Constraints on Carbonate Stability in Earth’s Mantle

Critical to the stability, distribution, movement, and capacity for mass transport of carbonate melts at mantle pressure and temperature conditions is the fO2 of the ambient mantle. This intensive variable exerts very strong control over the speciation of C in the mantle, which can range from highly reduced metal carbides, to methane fluids, to crystalline graphite or diamond, to oxidized carbon species such as CO, CO2, or CO32– in fluids or melts.Reference Taylor and Green19

The various species of carbon in the peridotite upper mantle are further limited by P–T–fO2 conditions relative to: (1) the univariant graphite/diamond phase transition; (2) redox-dependent reactions such as enstatite–magnesite–olivine–diamond (EMOD) and enstatite–magnesite–forsterite–diopside–diamond (EMFDD; see below); (3) the carbonate peridotite (or eclogite) solidus; (4) decarbonation reactions involving carbonate minerals or carbonate in melts, and silicate phases, such as

4MgSiO3+CaMgCO32=2Mg2SiO4+CaMgSi2O6+2CO2orthopyroxene+dolomite=olivine+clinopyroxene+CO2(6.1)

and (5) fluid absent equilibria such as

2MgSiO3+CaMgCO32=2MgCO3+CaMgSi2O6orthopyroxene+dolomite=magnesite+clinopyroxene(6.2)

For example, the stability of carbonate phases versus diamond in a melt- or fluid-free, Ca-poor, magnesite harzburgite assemblage is limited in P–fO2 space by the “EMOG/D” reaction (6.2) (enstatite–magnesite–olivine–graphite/diamond):Reference Luth20, Reference Stagno, Ojwang, McCammon and Frost21

MgSiO3+MgCO3=Mg2SiO4+C+O2orthopyroxene+magnesite=olivine(6.3)

At depths from around 40–240 km on a typical cratonic geotherm, the univariant reaction will increase slightly in fO2 from about –1.2 log units below fayalite–magnetite–quartz buffer (FMQ) to about –0.5 log units below FMQ.Reference Stagno, Ojwang, McCammon and Frost21 At fO2 values above this reaction, CO2-fluid, dolomite, or magnesite will be stable depending on pressure relative to reactions (6.1) and (6.2). At fO2 values below this reaction, graphite or diamond will be stable, depending on pressure relative to the univariant graphite–diamond reaction,Reference Kennedy and Kennedy22 which lies at a pressure corresponding to about 150 km depth on a cratonic geotherm. The majority of kimberlite-borne garnet peridotite xenoliths for which fO2 has been determined lie below EMOG/D, consistent with the sampling of diamond by deeply sourced kimberlites passing through the cratonic lithosphere. This also means that carbonate melts are unlikely to be stable at depths throughout most of the cratonic mantle lithosphere, except in minor volumes (perhaps adjacent to conduits for kimberlites) where metasomatic enrichment processes may have locally oxidized the wall-rock significantly.Reference Yaxley, Berry, Rosenthal, Woodland and Paterson23

In carbon-bearing lherzolite assemblages, the EMFDD reaction (6.4) limits carbonate stability in P–T–fO2 space:

3MgSiO3+CaCO3=Mg2SiO4+CaMgSi2O6+C+O2orthopyroxene+carbonate=olivine+clinopyroxene+diamond/graphite(6.4)

At 5 GPa, this reaction lies at about –1.2 log units at 500°C, decreasing to –1.5 log units at 1300°C, for realistic activities of the various components.Reference Luth20

Melting of carbon-bearing peridotite to form melts with high activities of carbonate therefore will be restricted to those regions of the peridotitic upper mantle where the oxidation state is consistent with carbonate stability (i.e. where fO2 lies above the appropriate limiting reaction at given pressure and temperature).

The magnitude and variation of fO2 in the mantle have been the subjects of many studies over recent decades. These have used measurements by a variety of techniques (wet chemical methods, Mössbauer spectroscopy, flank method, Fe K-edge micro-X-ray absorption near-edge structure spectroscopy) of FeReference Wallace and Green3+/∑Fe in phases in peridotite xenoliths (spinel, garnet, pyroxenes) from the upper mantle, synchrotron Mössbauer measurements of Fe3+ in majoritic garnets from the sublithospheric upper mantle or mantle transition zone,Reference Kiseeva24 and Fe3+/∑Fe measurements on primitive mid-ocean ridge basalt (MORB) glassesReference Cottrell and Kelley25, Reference Berry, Stewart, O’Neill, Mallmann and Mosselmans26 coupled with high-pressure experimental and thermodynamic calibrations of relevant redox-controlling reactions.Reference Gudmundsson and Wood27Reference Stagno and Frost29 These studies indicate that it is likely that carbonate stability in peridotite is generally limited to relatively shallow parts of the continental lithosphere (i.e. depths <~100 km; see Section 6.6.2 for more details). In the next section, we review high-pressure experimental constraints on the melting of carbonate peridotite.

6.3 Experimental Constraints on the Melting of Carbonate Peridotite in the Mantle

Many high-pressure experimental studies have investigated the phase and partial melting relations of (oxidized) carbonate-bearing mantle lithologies of peridotite at upper-mantle pressures.Reference Wallace and Green3, Reference Dasgupta and Hirschmann5, Reference Dasgupta and Hirschmann6, Reference Falloon and Green30Reference Wyllie41 The stable species of carbonate in the subsolidus peridotite upper mantle is controlled by some key carbonate–silicate reactions. These include reactions (6.1), (6.2), and (6.5):

Mg2SiO4+CO2=MgSiO3+MgCO3olivine+CO2=orthopyroxene+magnesite(6.5)

These reactions have been delineated using high-pressure experiments in the CaO–MgO–SiO2 ± H2O (CMS ± H) system.Reference Newton and Sharp42Reference Brey49

In more complex natural systems, particularly those containing Fe and alkali metal components, reaction (6.4) intersects the peridotite + CO2 system at the carbonate solidus at about 2.1 GPa and 1030°C (Hawaiian pyrolite + 5 wt.% dolomiteReference Falloon and Green30), dividing the shallow subsolidus lithospheric mantle into a shallower zone in which crystalline carbonate is unstable at the expense of CO2 fluid and a deeper zone in which dolomite crystallizes as part of a spinel or garnet lherzolite assemblage. At the solidus, this reaction forms an approximately isobaric solidus ledge. At pressures greater than the ledge is a near-solidus field of sodic dolomitic carbonate melt in equilibrium with lherzolite residue. At pressures below the ledge, CO2-rich fluid coexists with spinel lherzolite.

This reaction may act as a barrier to the migration of carbonate melts formed at higher pressures than reaction (6.1) to shallower depths in continental settings where geotherms are likely to intersect it. Dolomitic carbonate melts are predicted to react according to reaction (6.1), and this may lead to elimination of the melt and crystallization of secondary clinopyroxene and olivine at the expense of orthopyroxene and, in extreme cases, conversion of harzburgite or lherzolite mantle to orthopyroxene-free, clinopyroxene-rich wehrlite along with liberation of a CO2-rich fluid. Such a process was inferred to have occurred in some spinel wehrlite xenoliths hosted in the Newer Volcanics of Victoria, southeastern Australia,Reference Yaxley, Green and Kamenetsky8, Reference Yaxley, Crawford and Green50 and in the Olmani Cinder cone, northern Tanzania.Reference Rudnick, McDonough and Chappell51 It has been suggested that only in the circumstances where magma conduits become armored with orthopyroxene-free wehrlite are dolomitic carbonatites able to ascend to pressures less than the solidus ledge, potentially entering the crust, evolving to more calcic compositions, and, in some cases, becoming emplaced in the crust or erupted.Reference Dalton and Wood52

In oceanic settings, convective geotherms are at higher temperatures than conductive geotherms in the continental lithosphere and are not expected to intersect the solidus ledge or by reaction (6.1). At higher pressures and temperatures (3.4 GPa, 1080°C),Reference Falloon and Green30 the vapor-absent reaction (6.2) intersects the peridotite solidus, dividing the subsolidus regime into a lower-pressure field of dolomite garnet lherzolite and a higher pressure field of magnesite garnet lherzolite. Low-degree partial melts in experimentally investigated peridotite–CO2 ± H2O systems with natural compositions are generally broadly alkali rich and calcio-dolomitic to dolomitic in composition.Reference Wallace and Green3 Solidus temperatures are considerably lower than those of volatile-free systems, and although experimental studies that include CO2 and H2O are relatively rare, the available evidence suggests solidus temperatures are even lower.Reference Wallace and Green3, Reference Foley53

In the following sections, we apply the experimental and other constraints to infer the existence and behavior of carbonate melts in different tectonic settings.

6.4 Carbonate Melts Associated with Subduction Zones

The mantle is believed to have played a key role in controlling the long-term carbon budget in the exosphere through cycling of carbon from the surface to the mantle and back again.Reference Dasgupta and Hirschmann6, Reference Marty54, Reference Sleep and Zahnle55 The deep carbon cycle is regulated at the surface by the quantity of carbon subducted into the mantle at convergent margins and by volcanic degassing of mantle-derived melts releasing carbon into the exosphere at mid-ocean ridges, ocean islands, and arc volcanoes. A substantial proportion of the mass of carbon drawn into the mantle at subduction zones (anywhere between 20% and 100%) is recycled back to the surface via fore-arc degassing and arc magmatism,Reference Kelemen and Manning56 as discussed in detail in Chapter 10 of this volume. Estimates of the net annual flux of carbon ingassing and outgassing via these processes are difficult to constrain with certainty, and range from negligible values to ~60 Mt/year net recycling.Reference Dasgupta and Hirschmann6, Reference Kelemen and Manning56

Carbon enters the mantle at subduction zones in sediments, altered oceanic crust, and mantle lithosphere, with the total input flux in the range of ~50–100 Mt/year at modern subduction zones.Reference Dasgupta and Hirschmann6, Reference Kelemen and Manning56 Sedimentary carbon includes both biogenic organic carbon and carbonate. In more than a third of studied modern subduction zones, carbonate-rich materials make up a substantial fraction of the downgoing sediment, whereas in others it is absent altogether (e.g. Refs. Reference Plank and Langmuir57, Reference Plank58). However, organic carbon is expected to be at least a minor component in pelagic sediments and turbidites.Reference Kelemen and Manning56

Carbon is deposited during hydrothermal processes at mid-ocean ridges where carbonate (calcite and aragonite) forms during alteration of oceanic crust due to its reaction with CO2 in seawater; biotic organic carbon in oceanic crust is minor relative to abiotic organic compounds and inorganic carbonates. The top few hundred meters of oceanic crust contain an average of ~2.5 wt.% CO2, and at deeper levels the carbon content, mostly in the form of organic hydrocarbon species, drops below 0.2 wt.% throughout the remainder of the crustal section. Altered lithospheric mantle that is exposed to alteration by seawater also carries carbonate, although likely at an overall fraction that is much less than that of oceanic crust.Reference Kelemen and Manning56, Reference Alt and Teagle59

Downgoing slab materials never reach temperatures high enough for “dry” partial melting during blueschist and eclogite facies metamorphism at fore-arc depths (up to ~80 km),Reference Connolly60 and portions of the slab that do not experience pervasive dehydration can effectively transport carbon to greater mantle depths. Nevertheless, at pressures above ~0.5 GPa, carbonate solubility in aqueous fluids increases with temperature,Reference Manning, Shock and Sverjensky61 so fluids produced by metamorphic devolatilization of the slab can be effective at dissolving carbonate minerals and mobilizing carbon.Reference Ague and Nicolescu62 Much of this carbon may be redistributed within the slabReference Piccoli63 or sequestered into serpentinized mantle rock that overlies the slab,Reference Spandler, Hermann, Faure, Mavrogenes and Arculus64Reference Sieber, Hermann and Yaxley66 some of which in turn is dragged down with the descending slab.

At sub-arc depths (80–200 km), slab surface temperatures reach between 600 and 1000°C,Reference Syracuse, van Keken and Abers67 and carbonate mineral dissolution becomes much more efficient due to higher solubilities in hydrous fluidsReference Frezzotti, Selverstone, Sharp and Compagnoni68 and silicate meltsReference Schmidt69 at these depths. In some cases, carbonatite liquids may also form via fluid-flux melting of carbonate-rich metasedimentary rocksReference Korsakov and Hermann70 or carbonate-bearing metagabbros.Reference Poli71 As a consequence, CO2 (± CO32–)-rich fluid phases migrating from the downgoing slab or from buoyantly upwelling slab diapirsReference Marschall and Schumacher72, Reference Tumiati, Fumagalli, Tiraboschi and Poli73 can introduce significant carbon flux from the slab to the overlying mantle wedge. Evidence in support of C-rich fluid phases at the slab surface comes from garnet and clinopyroxene inclusions in diamonds from Dachine, South America, which have major and trace element characteristics indicating growth at the surface of a subducting slab at ~200 km depth, possibly in metalliferous metasediment.Reference Smith74

Slab-derived fluids migrating into the overlying mantle will experience progressive heating as they ascend through the inverted temperature gradient of the mantle wedge (Figure 6.1).Reference Green75 The introduction of C–O–H fluids or melts results in a significant lowering of the wedge peridotite solidus, such that carbonatite liquids can be produced at temperatures below 950°C.Reference Green75 Such carbonatitic liquids (+ H2O) are expected to be highly mobile, but will react with the wedge upon ascent and heating to produce carbonated hydrous silicate melts (>1020°C; Refs. Reference Tumiati, Fumagalli, Tiraboschi and Poli73, Reference Green75). Further ascent will favor further peridotite melting, increasing melt fractions, and diluting dissolved volatile contents. Upwelling from the hot core of the wedge may impart retrograde melt-rock or fluid-rock reactions, locking some carbonate (+ H2O) phases in the mantle lithosphere and lower crust,Reference Kelemen and Manning56 but the most volatile flux from the slab is expected ultimately to be delivered to the upper-arc crust via fractionating and degassing arc magmas.

Figure 6.1 Schematic cross-section of a subduction zone (modified after GreenReference Green75) depicting progressive slab devolatilization during subduction and zones of the mantle wedge containing carbonatitic and silicate-rich partial melts (green and orange fields, respectively).

The unique petrophysical evolution of magmas traversing the mantle wedge means that carbonatitic liquids are unable to be tapped from the mantle to the surface, which explains the lack of carbonatites found in supra-subduction zone settings.Reference Jones, Genge and Carmody76 Further, carbonated sub-arc mantle lithosphere and arc lower crust may eventually be preserved as subcontinental lithosphere through the reaction of volatile-rich melts with the mantleReference Saha, Dasgupta and Tsuno77 or recycled into the convecting mantle, possibly thereafter to undergo melting to produce carbonatites in intraplate settings.

6.5 Melting of Subducted, Carbonated Sediment and Ocean Crust in the Deep Upper Mantle and Transition Zone

While subduction to ~200 km depth can remove a significant fraction of the initial downwelling carbon flux to the mantle wedge, experimental evidence of carbonate stability, modeling of phase equilibria, and slab devolatilization indicate that, in some subduction zones, a substantial portion of subducted carbon or carbonate may make it past the dehydration zone and into the deeper mantle.Reference Gorman, Kerrick and Connolly78, Reference Molina and Poli79 Experiments also suggest that carbonate may be reduced to elemental carbon (graphite or diamond) at depths shallower than 250 km in more reducing eclogitic assemblages, although for oxidation states typical of MORB (e.g. Ref. Reference Kelley and Cottrell80), eclogitic assemblages should remain in the carbonate stability field to at least 250 km.Reference Stagno, Frost, McCammon, Mohseni and Fei28

Inclusions of carbonate minerals in superdeep diamonds provide the strongest direct evidence for a carbonate component subducted past the volcanic front and at least to transition-zone depths.Reference Brenker81Reference Zedgenizov, Kagi, Shatsky and Ragozin84 In addition, the distinctive major and trace element compositions of silicate inclusions in many superdeep diamonds (e.g. majorite garnet, Ca- and Ti-rich perovskite) have been interpreted to preserve a direct record in their origin of a low-degree carbonated melt derived from subducted oceanic crust.Reference Bulanova82, Reference Thomson85, Reference Walter86 Both the carbon isotopic composition of the diamonds and the oxygen isotope composition of the inclusions provide further evidence for a key role of subducted crustal components in the origin of many superdeep diamonds and their inclusions.Reference Burnham87, Reference Ickert, Stachel, Stern and Harris88 Thus, it seems that melting of carbonated sediment and oceanic crust in the deep upper mantle and transition zone may play a key role in the deep carbon cycle.

Figure 6.2 compares the solidus determinations from published studies on the melting behavior of carbonated pelitic sediment and carbonated oceanic crust at upper-mantle and transition-zone conditions. The solidus of carbonated pelitic sediment was determined by Tsuno and DasguptaReference Tsuno and Dasgupta89 at 2.5–3.0 GPa and by Grassi and SchmidtReference Grassi and Schmidt90 at 8–13 GPa, with melts ranging from granitic at low pressures to K-rich carbonatitic at higher pressures. On the basis of solidus determinations in these studies, only in the hottest subduction zones would melting of anhydrous carbonated sediments occur in the sub-arc region. The addition of water reduces the solidus of pelitic sediments, but unless sediments are water saturated, perhaps by fluxing of water-rich fluids from below, carbonated slab sediments may reach the deep upper mantle and transition zone.Reference Mann and Schmidt91 At higher pressures approaching the transition zone, the experiments of Grassi and SchmidtReference Grassi and Schmidt90 indicate that carbonated sediments can melt along warm and hot slab-top geotherms, but colder slabs could transport sedimentary carbonate into the deeper mantle (Figure 6.2).

Figure 6.2 Summary of the experimentally determined solidus curves for carbonated pelitic sediment and basaltic compositions. Solidus curves for carbonated basalt are shown as solid colored curves and are from: Hammouda,Reference Hammouda95 H03; Yaxley and Brey,Reference Yaxley and Brey148 YB04; Dasgupta et al.,Reference Dasgupta, Hirschmann and Withers94 D04; Keshav and Gudfinnsson,Reference Keshav and Gudfinnsson186 KG10; Kiseeva et al.,Reference Kiseeva, Litasov, Yaxley, Ohtani and Kamenetsky12 K13a,b; and Thomson et al.,Reference Thomson, Walter, Kohn and Brooker13 T13. Labels are keyed to the compositions listed in Table 6.1. Solidus curves for carbonated sediment are shown as dashed curves and are from: Tsuno and Dasgupta,Reference Tsuno and Dasgupta89 TD11; and Grassi and Schmidt,Reference Grassi and Schmidt187 GS11. Also shown is the solidus of alkaline carbonatite (Litasov et al.,Reference Litasov, Shatskiy, Ohtani and Yaxley101 L13). The mantle adiabat is from Katsura et al.Reference Katsura, Yoneda, Yamazaki, Yoshino and Ito188 Model geotherms at the top of a subducting slab are extrapolations shown for examples of hot, warm, and cold slabs.Reference Syracuse, van Keken and Abers67

There have been many experimental studies of melting carbonated basaltic compositions, both in simplifiedReference Keshav and Gudfinnsson Gudmundur92, Reference Litasov and Ohtani93 and natural systems.Reference Kiseeva, Litasov, Yaxley, Ohtani and Kamenetsky12, Reference Thomson, Walter, Kohn and Brooker13, Reference Dasgupta, Stalker, Withers and Hirschmann35, Reference Dasgupta, Hirschmann and Withers94Reference Yaxley and Green97 The small number of phases in basaltic compositions hampers studies in simplified compositions, whereas subtle compositional dependencies hamper studies in natural compositions. Indeed, subtle variations in bulk compositions between studies (Table 6.1) likely cause the significant variations in position and shape of the carbonated basalt solidus (e.g. Refs. Reference Thomson, Walter, Kohn and Brooker13, Reference Dasgupta, Hirschmann and Dellas98).

Table 6.1 Bulk compositions (as wt.%) of anhydrous MORB and carbonated MORB used in melting studies

MORB examplesaG12
All MORB
Y94
MAN-7
W99
JB1
H03
OTBCb
D04
SLEC1
K13a
GA1cc
K13b
Volgacc
T16
ATCM1
SiO250.4747.7153.5347.2341.2145.3242.2250.35
TiO21.681.711.442.161.341.431.33
Al2O314.715.6814.8515.3510.8914.8815.9113.66
FeO10.439.367.928.9312.838.859.4611.35
MnO0.180.180.160.120.150.140.21
MgO7.588.437.646.2412.877.157.647.15
CaO11.3911.739.1214.7713.0914.2414.8510.8
Na2O2.792.762.642.911.633.143.362.48
K2O0.160.231.310.020.110.40.420.06
P2O50.180.020.140.150.1
CO24.435.04.44.42.52
Total99.5799.8198.6199.9899.91100.0199.98100
Ca#c0.380.380.380.480.320.460.450.36
Mg#c0.570.620.620.560.640.590.590.53

b OTBC additionally contains 1200 ppm H2O.

c Ca number = Ca/(Ca + Mg + Fe); Mg number = Mg/(Mg + Fe).

In the lower pressure range (e.g. <3–5 GPa), a carbonate phase is not always stable at the solidus depending on the bulk CO2 and SiO2 contents. In those with higher SiO2/CO2 ratios, CO2 and/or silicate melts containing dissolved CO2 define the solidus,Reference Thomson, Walter, Kohn and Brooker13, Reference Hammouda95, Reference Yaxley and Green97 whereas compositions with lower SiO2/CO2 ratios showed carbonate stability and carbonate melt production along the solidus from low pressure.Reference Thomson, Walter, Kohn and Brooker13, Reference Dasgupta, Stalker, Withers and Hirschmann35, Reference Dasgupta, Hirschmann and Dellas98, Reference Gerbode and Dasgupta99 Additionally, near-solidus melts have been identified with a wide range of compositions from mafic to silicic. In some cases silicate melts are observed at the solidus before carbonate melts, whereas in other cases this relationship is reversed, and both kinds of melts have been interpreted to coexist together as immiscible liquids.Reference Kiseeva, Litasov, Yaxley, Ohtani and Kamenetsky12, Reference Gerbode and Dasgupta99, Reference Dasgupta, Hirschmann and Stalker100 The observation of immiscible melts may reflect the maximum CO2 solubility in silicate melts, and the appearance of liquid immiscibility will therefore depend on the CO2 content of the bulk composition.

At higher pressures of the deep upper mantle and transition zone, starting compositions again show remarkable control of melting behavior (Figure 6.2). When comparing the carbonated starting compositions used in the various studies, there are considerable differences, perhaps most notably in SiO2 and CO2 contents and Ca#. Thomson et al.Reference Thomson, Walter, Kohn and Brooker13 observed that the Ca# has an important controlling effect on the stable carbonate phase at the solidus beyond the pressure of dolomite breakdown (>~10 GPa). Phase relations apparently preclude coexistence of magnesite and aragonite in majorite- and clinopyroxene-bearing assemblages, and which of these carbonate phases is stable has an important controlling effect on the solidus shape and melt compositions.

In Ca-rich carbonated basalt bulk compositions, the stable phase is aragonite, which is also a host for sodium.Reference Kiseeva, Litasov, Yaxley, Ohtani and Kamenetsky12 However, in lower Ca# bulk compositions, magnesite is stable, and because sodium is relatively insoluble in magnesite, another Na-rich carbonate stabilizes in the subsolidus assemblage at pressures greater than ~15 GPa. The appearance of a Na-carbonate phase in the subsolidus produces a dramatic lowering of the melting temperature and a deep trough along the solidus between ~10 and 15 GPa that is not observed where aragonite is stable (Figure 6.2). When Na-carbonate occurs on the solidus, it is observed that the melting temperature at pressures >~15 GPa (~1150°C) is indistinguishable from that observed for a simplified Na-carbonate-rich bulk composition at these conditions (Figure 6.2).Reference Litasov, Shatskiy, Ohtani and Yaxley101 As the majority of natural MORB compositions, fresh and altered, fall to the Mg-rich side of the majorite–clinopyroxene join, they should have magnesite and not aragonite as the stable carbonate at high pressures and experience the lowered solidus at transition-zone conditions.Reference Thomson, Walter, Kohn and Brooker13

Figure 6.3 shows melt compositions projected onto a plane differentiating major and minor components of sediment and basalt-derived carbonated melts, demonstrating a generally continuous evolution with increasing pressure and temperature. The lowest-degree melts of carbonated basalt are highly calcic, even when the subsolidus carbonate is magnesite, because magnesite is the liquidus phase in most carbonate systems.Reference Litasov, Shatskiy, Ohtani and Yaxley101 Carbonated melts are enriched in incompatible elements and have high concentrations of TiO2, P2O5, and alkalis (Na2O and K2O), the relative abundances of which will be controlled by the bulk composition of the protolith. Sediment melts are dominated by potassium, whereas melts from carbonated basalt have alkali contents that are dominated by Na2O. Melt Na2O content increases systematically with pressure in basaltic compositions, resulting from the decreasing compatibility of Na2O in the coexisting residual phase assemblage. Thomson et al.Reference Thomson, Walter, Kohn and Brooker13 observed that melt compositions of carbonated basalt in the transition zone remain approximately constant over a wide temperature interval of >300°C above the solidus, and only when temperature exceeds ~1,500°C does the silica content of the melt increase. This behavior is reminiscent of the melting behavior observed in carbonated peridotite assemblages at lower pressures.Reference Gudfinnsson and Presnall102

Figure 6.3 The compositions of partial melts from carbonated natural basalt and sediment from the studies of Hammouda,Reference Hammouda95 Dasgupta et al.,Reference Dasgupta, Hirschmann and Withers94 Kiseeva et al.,Reference Kiseeva, Litasov, Yaxley, Ohtani and Kamenetsky12 Thomson et al.,Reference Thomson, Walter, Kohn and Brooker13 and Grassi and Schmidt.Reference Grassi and Schmidt90 The generalized effects of increasing pressure and temperature are also shown.

6.6 Carbonate Melts and Kimberlites in the Cratonic Lithospheric Mantle

The cratonic mantle lithosphere underlies ancient, continental blocks that have been geologically stable for billions of years. It is chemically depleted, thick, and buoyant. Unlike other tectonic settings, any surface expression of cratonic magmatism is manifested by emplacement of small-volume, rare, exotic, volatile-rich, alkali- and carbonate-rich magmas, such as carbonatites, kimberlites, lamproites, various lamprophyres, and other highly silica-undersaturated magmas,Reference Tappe, Foley, Jenner and Kjarsgaard103, Reference Tappe104 all of which have a deep mantle origin. Describing the detailed petrology of these rocks is beyond the scope of this chapter, and the reader is referred to the work of Jones et al.Reference Jones, Genge and Carmody76 Below, we give a short overview of an important carbonate-bearing silicate volcanic rock found in cratonic settings: kimberlites.

6.6.1 Kimberlites

Kimberlites are volatile (chiefly CO2)-rich, silica-poor alkaline, ultrabasic magmas generally believed to be derived from a depth of ≥150–250 km and almost exclusively emplaced into cratonic crust. Kimberlite magmas are economically significant because of their association with diamonds. They have been subdivided into two major groups on the basis of petrographic and geochemical characteristics: Group 1 kimberlites and Group 2 kimberlites.Reference Sparks105Reference Becker and Le Roex107 Group 1 kimberlites are CO2-rich, potassic, ultrabasic rocks with a typical porphyritic texture, with large phenocrysts of most commonly olivine surrounded by a fine-grained matrix consisting of olivine, phlogopite, spinel, ilmenite, monticellite, calcite, apatite, perovskite, and other phases.Reference Mitchell108 Group 2 kimberlites, or orangeites, are restricted to southern Africa. However, similar rocks have also been identified in Australia, India, Russia, and Finland. They are texturally similar to the Group 1 kimberlites, but have distinct compositional and isotopic differences, manifested mainly by the presence of phlogopite, K–Ba–V titanites, and Zr-bearing minerals, such as kimzeytic garnets,Reference Mitchell108 lower εHf and εNd values, and high radiogenic 87Sr isotope compositions.Reference Nowell109

Similar to carbonatites, kimberlites are volumetrically very minor, but they are widespread throughout the cratonic parts of continents, with the latest discoveries extending the Gondwanan Cretaceous kimberlite province to Antarctica.Reference Yaxley110 The main difference with carbonatites is in their origin in the subcratonic lithospheric or asthenospheric mantle enriched by an ocean island basalt source in the case of Group 1 kimberlites, whereas Group 2 kimberlites are derived from metasomatized lithospheric mantle,Reference Becker and Le Roex107, Reference Novella and Frost111 and their eruption is predominantly through stable parts of cratons.Reference Foley and Fischer112 To our knowledge, there are no reported occurrences of kimberlites in the oceanic crust.Reference Foley and Fischer112, Reference Patterson, Francis and McCandless113

The accurate determination of the kimberlite parental magma composition and its origin is hampered by the ubiquitous presence of a large fraction of foreign materials (mantle and crustal xenocrysts and xenoliths), in particular olivine crystals, collected from lithospheric mantle during their ascent to the surface, and by low-temperature alteration during and after emplacement. Petrological studies of the unaltered Udachnaya kimberlite pipe in the Siberian Craton showed high enrichment in CO2, halogens, and alkalis, resulting in a hypothesis in which genetic links between kimberlites and carbonatites were important.Reference Kamenetsky114, Reference Kamenetsky115 Later, experimental studies concluded that magmas potentially parental to kimberlites originate as dolomitic carbonate liquids in metasomatized, oxidized zones in the deep cratonic lithospheric mantleReference Yaxley, Berry, Rosenthal, Woodland and Paterson23 that segregate and become progressively more silicate-rich due to the assimilation of silicate material (mostly orthopyroxene) during ascent through the refractory lithosphere.Reference Russell, Porritt, Lavallee and Dingwell116

Alternative models are based on high-pressure experimental studies of estimated compositions of melts parental to kimberlites and have attempted to identify pressure, temperature, and volatile conditions at which the melts are multiply saturated in garnet peridotite phases.Reference Girnis, Brey and Ryabchikov117, Reference Girnis, Bulatov and Brey118 Such studies have indicated that the most likely source for kimberlite parental melts is hydrous, carbonate-bearing garnet harzburgite in the deep cratonic lithospheric mantle or sublithospheric asthenosphere.

In either case, kimberlite genesis clearly requires a sufficiently oxidized mantle for crystalline carbonate (Ca-magnesite) to be stable in the peridotitic source,Reference Yaxley, Berry, Rosenthal, Woodland and Paterson23 and the source is constrained to be greater than ~150 km depth in the cratonic lithospheric mantle because of the presence of xenocrystic diamonds.

6.6.2 Redox Constraints on Carbonate Stability in the Cratonic Lithospheric Mantle

In any volume of the cratonic mantle, in the absence of externally derived melts or fluids, the local fO2 is controlled by silicate or oxide mineral exchange equilibria such as reactions (6.6)(6.9), which involve oxidation of Fe2+-bearing components and reduction of Fe3+-bearing components.

6FeSiO3+2Fe3O4=6Fe2SiO4+O2orthopyroxenespinelolivine(6.6)
2Fe3O4+3SiO2=3Fe2SiO4+O2spinelorthopyroxene/olivineolivine(6.7)
2Fe2+3Fe3+2Si3O12=4Fe2SiO4+2FeSiO3+O2garnetolivineorthopyroxene(6.8)
2Ca3Fe2Si3O12+2Mg3Al2Si3O12+4FeSiO3=2Ca3Al2Si3O12+4Fe2SiO4+6MgSiO3+O2garnetgarnetorthopyroxenegarnetolivineopx(6.9)

For example, (6.6)(6.9) have been calibrated experimentally,Reference Stagno, Ojwang, McCammon and Frost21, Reference Gudmundsson and Wood27, Reference Nell and Wood119Reference O’Neill and Wall121 meaning that, in principle, the fO2 of a spinel or garnet peridotite from the upper mantle can be determined if the activities of the Fe-bearing components in the minerals that contain Fe2+ and Fe3+ can be determined, along with other mineral component activities, pressure, and temperature.

These experimental calibrations can be combined with conventional thermobarometry to calculate the variation in fO2 as a function of depth in the peridotite lithospheric upper mantle, as recorded by peridotite xenoliths from kimberlites in the case of cratonic mantle lithosphere, for example. The uppermost cratonic mantle lithosphere based on spinel peridotite xenoliths sampled by kimberlites has fO2 between 0 and –1 log units relative to FMQ for primitive (△logfO2FMQ),Reference Woodland and Koch122 well within the carbonate stability field. In the garnet peridotite facies, fO2 decreases systematically with increasing pressure (depth) through the cratonic lithosphere (Figure 6.4),Reference Yaxley, Berry, Rosenthal, Woodland and Paterson23, Reference Woodland and Koch122, Reference Yaxley, Berry, Kamenetsky, Woodland and Golovin123 although the xenolith record exhibits complications associated with oxidative overprinting associated with metasomatism, particularly at depths >150 km. Decreasing fO2 with increasing depth is expected on a thermodynamic basis, because of the molar volume changes of reactions such as (6.8) and (6.9).Reference Gudmundsson and Wood27, Reference Frost and McCammon124 It is therefore likely that melts with high carbonate activities are unstable relative to graphite or diamond at depths greater than ~90–120 km in the cratonic lithospheric mantle.

Figure 6.4 Highly schematic representation of a section through Earth’s upper mantle modified from figure 2c of Foley and Fischer,Reference Foley and Fischer112 showing fO2 as a function of depth. The dashed white contours are approximate contours of fO2 variation in the cratonic lithosphere based on studies of garnet peridotite xenoliths (references in the text). The dashed yellow line is the graphite–diamond transition for a typical cratonic geotherm (38 mW m–2). The red line (3) represents the path of an erupting kimberlite and the blue zone (2) near the base of the lithosphere represents a local mantle volume metasomatized to higher fO2 by asthenospheric melts derived from the brown field labeled (1).

At depths of ~250–300 km, the fO2–P path is expected intersect the Ni precipitation curve, an FeNi alloy will exsolve from peridotite, and fO2 will be buffered near the iron–wüstite (IW) buffer deeper into the upper mantle. In the presence of metallic FeNi alloy, some reduced carbon will be accommodated as (Fe,Ni) carbides. Rohrbach et al.Reference Rohrbach, Ghosh, Schmidt, Wijbrans and Klemme125 have calculated that, assuming the mantle contains 50–700 ppm FeNi and 50–500 ppm C at 300 km depth, it would contain an assemblage of (Fe,Ni)3C + FeNi alloy + diamond or an Fe–Ni–S–C melt.Reference Tsuno and Dasgupta126

Although the cratonic mantle becomes more reduced with increasing depth, local redox heterogeneities may be introduced, particularly at depths greater than 150 km, by metasomatic fluids such as carbonate-bearing silicate meltsReference Yaxley, Berry, Rosenthal, Woodland and Paterson23, Reference Yaxley, Berry, Kamenetsky, Woodland and Golovin127 with low carbonate activities,Reference Stagno, Ojwang, McCammon and Frost21 possibly derived from the asthenosphere or from oxidized crustal material recycled via subduction. In some cases, the degree of oxidation in the lower part of the cratonic lithospheric upper mantle could be sufficient to stabilize crystallization of carbonates (magnesite in peridotite), which, in the presence of H2O, could melt and produce magmas parental to kimberlites.Reference Girnis, Brey and Ryabchikov117, Reference Girnis, Bulatov and Brey118

6.6.3 The Involvement of Carbonate Melts in Metasomatism of the Deep Cratonic Lithospheric Mantle

Apart from carbonatites and kimberlites that were emplaced into or erupted onto the crust, CO2-rich fluids, carbonate melts, or carbonated silicate melts are often inferred to be major agents of mantle metasomatism and trace element enrichment in the lithospheric mantle. Unlike, for example, alpine massifs, most peridotite and eclogite xenoliths carried to the surface by kimberlites are chemically enriched relative to the depleted lithospheric mantle. It may be that the degree of this enrichment was previously severely underestimatedReference Foley and Fischer112, Reference Foley128 and that CO2-rich metasomatism is a widespread process throughout the cratonic mantle.

It is not always easy to distinguish and characterize the exact nature of a particular metasomatic overprint observed in natural rocks. Given the giga-year ages of the cratonic lithospheric mantle, there is a likelihood of multiple melting (i.e. depletion) and subsequent re-enrichment events. Moreover, the challenge of deciphering a particular metasomatic event in a given mantle xenolith is exacerbated by the possibility of multiple types of percolating fluids. For instance, in addition to the carbonatitic CO2-rich metasomatism, an H2O-rich alkali silicate metasomatism, perhaps of a proto-lamproite type, has been reported.Reference Coltorti, Beccaluva, Bonadiman, Salvini and Siena129Reference Misra, Anand, Taylor and Sobolev131

At the reduced conditions likely to exist in much of the deep cratonic lithospheric mantle and underlying asthenosphere, carbonate phases are not expected to be generally stable and so melts with high carbonate activities such as carbonatites will likely not form, except locally in localized zones already strongly oxidized due to earlier metasomatism.Reference Yaxley, Berry, Rosenthal, Woodland and Paterson23 Carbon transport will likely be as low activity carbonate dissolved in undersaturated silicate meltsReference Stagno, Ojwang, McCammon and Frost21 or as CH4 + H2O fluids.Reference Foley128, Reference Taylor and Green132, Reference Litasov, Shatskiy and Ohtani133 However, it should also be noted that the depth–fO2 profile of the asthenospheric mantle is not necessarily the same as that observed in xenolith studies from the cratonic mantle or inferred from thermodynamic calculations. Based on CO2–Ba–Nb systematics of oceanic basalts, the convecting mantle may in fact be considerably more oxidized at pressures greater than about 3 GPa.Reference Eguchi and Dasgupta134

If undersaturated silicate melts with dissolved carbonate or CO2 at low activities form as a result of adiabatic upwelling in plumes or rifts, segregate from their asthenospheric sources, and percolate upwards into parts of the cooler, deep cratonic lithosphere, they will freeze into the lithospheric mantle as the appropriate peridotite + volatile solidus is locally crossed. Oxidized carbon species will be exsolved from the melt during crystallization and would reduce to C or CH4 (CO2 = C + O2; CO2 + 2H2O = CH4 + 2O2) because of the low ambient fO2 in the deep cratonic lithosphere. Fe2+ in the melt and the wall rock will oxidize to Fe3+ (2FeO + ½O2 = Fe2O3) and be incorporated into garnet and pyroxenes, leading to the observed increase in lithospheric fO2 associated with metasomatism. The increased activity of H2O may cause a decrease in the solidus temperatures of peridotite locally and lead to partial melting in a process known as hydrous redox melting. Only after sufficient oxidation by this type of metasomatic process could the fO2 of the deep cratonic lithospheric mantle be raised sufficiently to allow carbonate stability and the formation of carbonatites, kimberlites, and related rocks at these depths.

6.7 Carbonate Melts beneath Ocean Islands in Intraplate Settings

Observations from natural samples indicate the role of CO2, specifically CO2-rich silicate melts, in the metasomatism of the upper mantle beneath ocean islands in intraplate settings. Carbonate phases, interpreted to be quenched carbonate liquids, have been identified in metasomatized harzburgite xenoliths in the Kerguelen and Canary Islands.Reference Kogarko, Henderson and Pacheco135, Reference Schiano, Clocchiatti, Shimizu, Weis and Mattielli136 These carbonate inclusions are texturally associated with silicate glass inclusions, either as globules within a silicate matrix or as intimate associations with silicate inclusions. Such textural associations between the carbonate-rich phases and the silicate glasses have led to the conclusion that the carbonate-rich phases are products of immiscibility of a single carbonated silicate melt phase that exists at depth, possibly at upper-mantle conditions. Geochemical modeling of rejuvenated Hawaiian lavas also indicates the presence of carbonate-rich liquids in the source of these lavas.Reference Dixon, Clague David, Cousens, Monsalve Maria and Uhl137

6.7.1 How Do CO2-Rich Silicate Melts Form in the Upper Mantle? Can These CO2-Rich Melts Explain the Chemistry of Erupted Magmas in Intraplate Ocean Islands?

Previous experimental studies have demonstrated that CO2-rich silicate melts can be produced in upper-mantle conditions by the following mechanism. Carbon may exist in its oxidized form as carbonate mineral or as liquid in the mantle at fO2 values that are about 2 log units higher than that of the IW buffer (given by equilibrium (6.10)):

2Fe+O2=2FeOironwüstite(6.10)

which corresponds to depths above 150–250 kmReference Stagno, Ojwang, McCammon and Frost21, Reference Rohrbach and Schmidt138 in the oceanic lithosphere. Carbonate may be present deeper in the mantle in locally oxidized regions.Reference Dasgupta139, Reference Eguchi and Dasgupta140 Due to cryoscopic depression of the freezing point, carbonate-bearing lithologies (peridotite and recycled oceanic crust or eclogite) have lower solidus temperatures than nominally anhydrous or carbonate-free lithologies, as demonstrated by experimental studies.Reference Dasgupta and Hirschmann5, Reference Dasgupta, Hirschmann and Smith33, Reference Eggler47, Reference Dasgupta, Hirschmann and Withers94Reference Kiseeva96, Reference Gerbode and Dasgupta99, Reference Dalton and Presnall141Reference Yaxley and Brey148 This implies that in an upwelling mantle partial melting of carbonated lithologies is initiated deeper than in the surrounding carbonate-free lithologies. Near-solidus partial melting of carbonated peridotite and/or carbonated recycled oceanic crust (eclogite) produces carbonatitic liquids (>25 wt.% CO2, <20 wt.% SiO2). These carbonatitic liquids tend to be very mobile owing to their low viscosities and low dihedral angles,Reference Minarik and Watson149 which lead to their escape from the site of generation. These rising liquids can cause flux-based partial melting of peridotite and eclogite in an adiabatically upwelling plume mantle in intraplate settings, which produces CO2-bearing silicate melts (Figure 6.5a).

Figure 6.5 (a) Pressure–temperature plot showing the generation of carbonated silicate melt in Earth’s upper mantle. A parcel of carbon-bearing mantle peridotite with pods of eclogite upwells beneath ocean islands along an adiabat (bold arrow along the dotted line). As it upwells, redox melting takes place when the mantle crosses over from the stippled zone where the carbon is present in reduced form (either as graphite or as diamondReference Stagno, Ojwang, McCammon and Frost21, Reference Rohrbach and Schmidt138) to the overlying zone where carbon is present in its oxidized form (as carbonates or as CO2 vapor at pressures lower than 2 GPa3). At the redox front, reduced carbon present in the eclogite or peridotite oxidizes to form trace to minor amounts of carbonatitic melt (labeled (1)). The carbonatitic melt causes fluxed partial melting of eclogite and peridotite because the carbonated solidi of peridotite and eclogite are at much lower temperatures at the pressure range of the upwelled parcel of mantle (labeled (2)). The fluxed partial melting of eclogite and peridotite produces carbonated silicate melts in the upper mantle. The volatile-free solidi of peridotiteReference Hirschmann189 and eclogite,Reference Yasuda, Fujii and Kurita191 the carbonated solidi of peridotiteReference Dasgupta, Hirschmann and Smith33, Reference Dasgupta142 and eclogite,Reference Yaxley and Brey148 the graphite–diamond transition,Reference Day193 and the range of mantle potential temperatures in Earth’s upper mantle (orange shaded area) from ridgesReference Herzberg and Gazel194 to plumesReference Herzberg195 are plotted for reference. The broken curves for carbonated solidi are only applicable for locally oxidized domains in the mantle where carbonates can exist at depths below the redox-melting front. (b) Geodynamic scenarios involving carbonated eclogite and peridotite in the source of ocean island volcanism in intraplate settings (modified from a previous studyReference Mallik and Dasgupta152). (i) This scenario is applicable for locally oxidized domains in the mantle where deeper carbonatites generated by very-low-degree partial melting of carbonated peridotite and/or eclogite rise upwards and cause fluxed partial melting of volatile-free eclogite at shallower depths in the upper mantle. The carbonated partial melt of eclogite, a basanite, or andesite (a lower eclogite to carbonate ratio produces basanite, while a higher ratio produces andesite) reacts with subsolidus volatile-free peridotite. The melt-rock reaction produces product melts that display similarity in composition with ocean island basalts. (ii) Reduced carbon-bearing eclogite upwells and produces carbonated silicate partial melts of eclogite after crossing the redox-melting front. The carbonated silicate partial melt of eclogite reacts with the surrounding subsolidus volatile-free peridotite, and a similar melt-rock reaction as proposed in (i) takes place.

Peridotite is the dominant lithology of Earth’s mantle. This increases the likelihood of partial melts of CO2-bearing peridotite being the best candidates for explaining the geochemistry of ocean island basalts that commonly erupt in ocean islands in intraplate settings. The next likely candidate for ocean island basalts would be partial melts of CO2-bearing eclogite, given recycled oceanic crust forms the dominant chemical heterogeneity in Earth’s mantle.Reference Helffrich and Wood150 Comparisons of the major element chemistry of partial melts of CO2-bearing peridotite and eclogite with natural, near-primary ocean island basalts indicate that carbonated peridotite-derived partial melts are too TiO2 poor,Reference Dasgupta, Hirschmann and Smith151 while carbonated eclogite-derived partial melts are too depleted in MgO.Reference Gerbode and Dasgupta99 Also, the peridotite-derived partial melts can explain the MgO content very well for the ocean island basalts, while the eclogite-derived partial melts can explain the TiO2 contents. This implies that the source of ocean island basalts would be best explained by a hybrid source involving contributions from both peridotite (high MgO) and eclogite (high TiO2). A previous study indicated a couple of geodynamic scenarios involving CO2-bearing eclogite and peridotite as the source of ocean island basalts (Figure 6.5b).Reference Mallik and Dasgupta152

Deep carbonatites are formed by very-low-degree partial melting of carbonate-bearing eclogites that are present in deep, locally oxidized upper-mantle domains. These carbonatites rise up and cause flux melting of overlying volatile-free eclogites. The flux melting produces eclogite-derived carbonated silicate melts (ranging from basanites to andesites) that are out of chemical equilibrium with their surrounding peridotite and undergo reactive infiltration. The metasomatic process or melt-rock reaction associated with such reactive infiltration forms ocean island basalts.

Deep carbonatites can also be generated by very-low-degree partial melting of graphite/diamond-bearing peridotite or eclogite at the redox front (150–250 km depth, where reduced carbon in the form of diamond/graphite is oxidized to a carbonatitic melt). These carbonatites can cause fluxed melting of volatile-free eclogite and can undergo subsequent reactive infiltration through the peridotite, as described above.

A question arises as to whether the involvement of CO2 in the source is required for all ocean island basalts. Studies have shown that basanitic ocean island basalts can be explained by partial melting of volatile-free peridotite ± eclogite in the source; however, more silica-undersaturated ocean island basalts such as nephelinites and melilitites require the involvement of CO2.Reference Mallik and Dasgupta152, Reference Mallik and Dasgupta153

6.7.2 Effect of CO2 on the Reaction between Eclogite-Derived Partial Melts and Peridotite

CO2 dissolves in silicate melts as both molecular CO2 and CO32– anions. When network-modifying cations (those that depolymerize the silicate network) such as Na+, K+, Ca2+, Mg2+, and Fe2+ are available in the silicate melt, CO32– bonds with these cations.Reference Guillot and Sator154 These carbonate complexes result in the cations being removed from their network-modifying roles. Thus, these carbonate complexes give rise to pockets of polymerized networks in the silicate melt structure.Reference Morizet155

When eclogite-derived melts react with olivine- and orthopyroxene-bearing peridotite, the following equilibrium (6.11) buffers the thermodynamic activity of SiO2 (aSiO2) in the reacted melt:

Mg2SiO4+SiO2=Mg2Si2O6olivinemeltorthopyroxene(6.11)

The localized separation of polymerized silicate networks and carbonate complexes in the silicate melt structure results in the requirement for excess free energy of mixing between the two structural components. This increases the activity coefficient of SiO2 in the melt (γSiO2). Higher γSiO2 when aSiO2 is buffered results in a decrease in the mole fraction of SiO2 (XSiO2) in the melt.Reference Dasgupta, Hirschmann and Smith151 Thus, involvement of CO2 in the melt-rock reaction decreases the SiO2 content of the product melt, driving eclogite-derived basanites and andesites to produce nephelinites and melilitites (depending on the amount of CO2 available in the system).Reference Mallik and Dasgupta152, Reference Mallik and Dasgupta153 A higher γSiO2 and an increased degree of polymerization of the silicate domain of the melt network also imply that saturation of orthopyroxene is preferred over saturation of olivine in the residue of melt-rock reaction. Thus, the stability field of orthopyroxene is enhanced over that of olivine.Reference Eggler47, Reference Dasgupta, Hirschmann and Smith151Reference Mallik and Dasgupta153 Also, cations such as Ca2+, Mg2+, Na+, and K+ prefer to enter the melt structure to form carbonate complexes in the presence of CO2. This enhances the calcium, magnesium, and alkali contents of the product melts.

6.8 Carbonate Melts under Mid-ocean Ridges

Along mid-ocean ridges, where divergent tectonic plates move apart from each other, the rising asthenospheric mantle decompresses and partially melts to create basaltic magma that buoyantly rises to Earth’s surface and solidifies to form new oceanic crust. During decompression melting, volatile-free mantle lithologies melt at ~60 km, producing silicate melts.Reference Langmuir, Klein, Plank, Phipps-Morgan, Blackman and Sinton156 Beneath ridges at shallow depths, carbonate-bearing silicate melts (basalts) are stable.Reference Dasgupta and Hirschmann5, Reference Gudfinnsson and Presnall102, Reference Dasgupta142 Melting in carbonated mantle lithologies may take place at depths of ~300 kmReference Dasgupta142 due to depression of the mantle solidus temperature.Reference Dasgupta and Hirschmann5, Reference Stagno and Frost29, Reference Ghosh, Ohtani, Litasov and Terasaki157

Figure 6.6 shows the stability fields of carbonates and carbonate and silicate melts in an adiabatically upwelling mantle and is compared with the fO2 of the asthenospheric mantle. The fO2 determined using reaction (6.10) suggests that carbonatitic melts are unstable at depths greater than 300 km due to the increased activity of Fe3+-rich components in mantle minerals.Reference Rohrbach and Schmidt138, Reference Frost158, Reference Rohrbach159 At the lower end of carbon concentrations in the mantle (30 ppm C for a MORB source mantleReference Marty54 and an initial Fe3+/∑Fe content of 4%), graphite would transform to diamond at depths of ~160 km (Figure 6.2) and diamond would be the stable phase instead of carbonates or carbonatitic melts.Reference Stagno and Frost29, Reference Woodland and Koch122, Reference Yaxley, Berry, Kamenetsky, Woodland and Golovin123 If the mantle is reduced below ~250 km depth and becomes metal saturated, then carbonatitic melts would be stable only to a depth of 150 km. During adiabatic upwelling of the upper mantle, reduction of Fe3+ locked in mantle silicates to Fe2+ results in concomitant oxidation of diamond or graphite and carbonatitic melting.Reference Rohrbach and Schmidt138 This redox process can be explained by reaction (6.12):

C+2Fe2O3=CO2+4FeOgraphite/diamondsilicatecarbonatitic meltsilicate(6.12)

As soon as 30 ppm of graphite in the upper mantle is oxidized, the Fe3+/∑Fe content of the remaining mantle drops from 4% to 3%. After such redox melting, the fO2 of the upper mantle increases again and finally reaches the level of mid-ocean ridge basalts at around FMQ (Figure 6.6).

Figure 6.6 A simplified model for the extraction of carbonatitic/carbonated silicate melts from the mantle based on Stagno et al.Reference Stagno, Frost, McCammon, Mohseni and Fei28 If carbonates are present in the adiabatically upwelling mantle beneath mid-ocean ridges, they will lower the melting temperature of the mantle rocks and melting will take place at ~300 km depth if the adiabat has a potential temperature of 1400°C. The left-hand panel shows that the solidus of peridotite and eclogite is depressed by several hundred degrees compared to the volatile-free solidus. The central panel shows the focusing of deeply derived carbonate melts (red triangle) formed by redox melting at about 1.5 GPa lower pressures than the carbonate peridotite solidus for oxidized mantle. The right-hand panel shows estimated Fe3+/∑Fe in peridotite buffered at about 0.1 at depths below about 290 km, and buffered by FeNi alloy (≈IW) to higher values at greater depths.

6.9 Crustally Emplaced Carbonatites

Natural carbonate melts represent a tiny proportion of the magmatic rocks of Earth’s crust, but nonetheless provide important insights into mantle-to-crust carbon transfer over geological time. Carbonate melts primarily refer to carbonatites, but could also include kimberlites and various other alkaline mafic–ultramafic silicate magma series (e.g. lamprophyres). All of these magma types have indisputable mantle origins, as revealed by stable and radiogenic isotope signatures, as well as a common association with mantle-derived alkaline silicate magmas.Reference Jones, Genge and Carmody76

Carbonatites (magmatic rocks with >50% carbonate minerals) are variably classified into a number of groups based on their chemistry, with most researchers agreeing on at least five groups; calcio-carbonatite, dolomite carbonatite, ferro-carbonatite, natro- (or alkali-) carbonatite, and rare earth carbonatites.Reference Jones, Genge and Carmody76 The Ca–Mg–Fe-rich carbonatites are primarily found as intrusive complexes that may to some extent represent crystal cumulates from carbonatite magma,Reference Harmer and Gittins160 or as melt inclusions in igneous and mantle minerals.Reference Nielsen, Solovova and Veksler161, Reference Guzmics162 Extrusive carbonatites are relatively rare in the rock recordReference Woolley and Church163 and include the only known active carbonatite volcano, Oldoinyo Lengai (Tanzania), which erupts natrocarbonatite. Other occurrences of natrocarbonatite are found only very rarely as melt inclusions within igneous minerals from alkaline rocksReference Nielsen, Solovova and Veksler161, Reference Guzmics164 and kimberlites.Reference Golovin, Sharygin, Kamenetsky, Korsakov and Yaxley11 The lack of natrocarbonatite from the rock record is often ascribed to its extreme instability under atmospheric and most geological conditions.Reference Zaitsev and Keller165 Rare earth carbonatites (with >1 wt.% REE) also tend to be enriched in other incompatible trace elements (e.g. U, Th, Nb, Ta) and are regarded to be products of fractional crystallization of parental carbonatite magma.Reference Mitchell166 This carbonatite class is of significant economic importance as a source of the critical metals needed for many technological applications that support modern societies.Reference Weng, Jowitt, Mudd and Haque167

Despite consensus regarding their mantle origins, there are differing opinions on carbonatite evolution. Some researchers assert that carbonatites are primary magmas derived directly by low-degree melting of CO2-rich mantle sources,Reference Harmer and Gittins168 whereas experimental work by Watkinson and WyllieReference Watkinson and Wyllie169 demonstrated that carbonate liquids could be formed as residua of fractionation from carbonated peralkaline silicate magmas; this latter origin would be consistent with the classification as “carbothermal residua” of Mitchell.Reference Mitchell166 Supporting a primary mantle origin are studies of mantle xenoliths of distinctive petrological and geochemical character formed via metasomatism by carbonatitic melts.Reference Yaxley, Green and Kamenetsky8, Reference Jones, Genge and Carmody76, Reference Neumann, Wulff-Pedersen, Pearson and Spencer170 Carbonatitic melt inclusions within diamond represent further unequivocal evidence of a mantle origin.Reference Jones, Genge and Carmody76, Reference Klein-BenDavid171

A third origin proposed for carbonatite genesis is via liquid immiscibility from evolving CO2-bearing alkaline silicate melts at crustal pressures.Reference Jones, Genge and Carmody76 Support for this model comes not only from experimental evidence and the common field association between carbonatite and alkaline silicate magmatic rocks, but crucially from a growing number of textural, petrological, and geochemical studies of carbonatites.Reference Guzmics164, Reference Kjarsgaard and Peterson172Reference Weidendorfer, Schmidt and Mattsson174 Given the compelling evidence for their primary mantle and immiscibility origins, it is likely that carbonatite magmas may be formed in a range of geological environments, from shallow crustal down to lower-mantle conditions.

Carbonatites and other mantle-derived CO2-rich magmas, such as kimberlites, are found across all continents, although over half are in Africa.Reference Woolley and Kjarsgaard175 They are most commonly found within Precambrian cratons despite the fact that most are of Phanerozoic age.Reference Jelsma, Barnett, Richards and Lister176, Reference Woolley and Bailey177 These settings would be consistent with formation via low-degree (and hence relatively low-temperature) melting of fertile mantle sources, such as thick mantle lithosphere beneath stable cratons. There tends to be an increasing frequency of their formation toward younger ages, which is not easily explained as an artefact of preservation,Reference Woolley and Bailey177 but rather may reflect more favorable conditions for the production of mantle-derived alkaline magmatism in the modern Earth. This would be consistent with more effective recycling of crustal material into the mantle via modern-style subduction processes, allowing the production of the re-fertilized mantle domains that are requisite sources of these magmas.

There are diverse views on the tectonic settings in which carbonatites and other CO2-bearing magmas form and are emplaced into the crust. Carbonatite magmatism is a distinctive feature of the recent igneous activity of the East African Rift, demonstrating a link to intracontinental rifting, and potentially mantle plumes.Reference Bell and Tilton178 Many older carbonatite complexes have also been linked to continental rifting, mantle plumes, or large igneous provinces.Reference Bailey179Reference Ernst and Bell181 However, Woolley and BaileyReference Woolley and Bailey177 argue that ephemeral mantle controls, such as mantle plumes, do not account for the episodic and repeated nature of carbonatitic (and kimberlitic) magmatism within restricted areas, sometimes over billions of years. Instead, these authors argue for reactivation of lithospheric-scale structures or lineaments due to far-field plate reorganization (e.g. due to rift initiation or continental assemblyReference Jelsma, Barnett, Richards and Lister182), which allows for low-degree melting of the fertile cratonic mantle lithosphere to produce carbonatites or kimberlites, as well as efficient tapping of the melts to the surface.

Carbonatites in oceanic settings have only been described from the hot spot volcanos of Cape Verde and the Canary Islands.Reference Hoernle, Tilton, Le Bas, Duggen and Garbe-Schonberg183, Reference Holm184 In these settings, the degree of mantle melting is expected to be too high to produce carbonatites directly; rather, the carbonatites are interpreted to be products of fractionation and unmixing from alkali-rich primitive basanite melts.Reference Schmidt and Weidendorfer185 In this case, the rarity of oceanic carbonatites may reflect a lack of preservation and exposure rather than unsuitable petrogenesis conditions.

6.10 Concluding Remarks

The existence of carbonate-rich melts in Earth is likely limited in P–T–fO2 space to the crust, to the uppermost part of the upper mantle including oceanic and continental lithosphere, to the mantle wedge above subducting slabs, to locally strongly metasomatized regions of the deep cratonic lithospheric mantle and asthenosphere, and to local regions of the deep upper mantle, mantle transition zone, and uppermost lower mantle associated with deep subduction of the carbonate-bearing oceanic lithosphere. Much of the deep Earth is too reduced for carbonate or carbonate-rich melts to be stable, where carbon will exist in reduced forms, such as diamond, methane, and other alkanes or volatile organic molecules, as well as Fe-carbides.

Despite this, carbonate melts are of tremendous importance as agents of mass transport and metasomatic enrichment in Earth’s interior. They are also the primary source of almost all commercially viable REE resources, and they may contain other critical metals in extractable quantities as well. Although crustally emplaced carbonatites are small in volume, they are likely to be much more abundant as broadly alkali-rich calcio-dolomitic to dolomitic melts in the upper mantle and mantle transition zone, where they contribute significantly to the carbon fluxes to the surface.

6.11 Limits to Knowledge and Unknowns

Key areas relating to carbonate or CO2-bearing melts in Earth in which current knowledge is limited include the solubility of CO2 in hydrous fluids and partial melts derived from subducting oceanic crust, particularly in the sub-arc environment. These melts may play a critically important role in metasomatizing the mantle wedge and flux melting, ultimately leading to arc volcanism and continental crust formation. They are agents by which subducted carbon is recycled on relatively short timescales of tens of Ma from the subducted slab in the sub-arc environment (blueschist or eclogite facies conditions) back to the atmosphere and hydrosphere. We cannot quantify carbon fluxes in this relatively shallow part of Earth’s deep carbon cycle unless we understand the magnitude of volatile fluxes from slab to arc volcanism. This will require high-pressure experimental studies as well as field studies of high-grade, carbonated metamorphic rocks in orogenic zones.

This in turn bears on estimates of carbon fluxes via subduction into the deeper mantle, and ultimately to the mantle transition zone or lower mantle. These estimates currently vary from 0 to 15 Mt/year.Reference Kelemen and Manning56 It appears likely that some carbon does escape relatively shallow recycling during subduction to sub-arc conditions based on studies of sublithospheric diamonds and their inclusions. If so, it may then be transported as part of the oceanic lithosphere to the deeper mantle. However, it remains unclear how the fO2 of the oceanic crustal components being subducted as part of the lithospheric package varies along the prograde path. This will be a critical control on the ultimate fate of carbon in the oceanic crust. For example, as has been shown recently by Kiseeva et al.Reference Kiseeva, Litasov, Yaxley, Ohtani and Kamenetsky12 and Thomson et al.,Reference Thomson, Walter, Kohn and Brooker13 carbonate in the mafic crust is unlikely to be subducted beyond the mantle transition zone, as it will melt to form carbonate liquids, which will segregate from their source and undergo redox freezing on contact with reduced peridotite wall-rock.Reference Rohrbach and Schmidt138 However, if carbonate is reduced to diamond on the prograde path, melting will not occur, and in those cases where slabs enter the lower mantle, carbon will likely also be transported beyond the mantle transition zone.

Finally, we currently lack understanding of aspects of the return cycle of carbon from the deep upper mantle, mantle transition zone, or lower mantle to the surface. In particular, some sublithospheric diamonds originate from these very deep parts of the upper and lower mantle based on their mineral inclusions. However, it is unclear exactly how and where the kimberlites formed that host these diamonds and transported them to the surface. Did they form at deep upper-mantle, transition-zone, or lower-mantle pressures, or were the sublithospheric diamonds first transported from great depths during mantle convection and then entrained in kimberlites formed at depths just below the cratonic lithospheric mantle? Answering these questions will require careful high-pressure experimental studies in order to deepen understanding of the role of C–O–H volatiles in causing melting at depths in and around the transition zone.

Acknowledgments

We gratefully thank the editorial team for this book, Beth Orcutt, Isabelle Daniel, and Raj Dasgupta, for their encouragement and immense patience in the development of this chapter and for their expert editorial handling. We also thank Raj Dasgupta and an anonymous reviewer for two constructive formal reviews.

Questions for the Classroom

1 Describe the different forms in which carbon is believed to exist in Earth’s mantle. In which parts of the mantle are these different carbon-bearing species located and what is the evidence for their presence?

2 Explain how pressure, temperature, and fO2 in Earth’s mantle influence the species present in different parts of the mantle (lower mantle, mantle transition zone, upper mantle) and different tectonic settings.

3 What are some of the reasons that carbonate melts inferred to exist in parts of the subcontinental lithosphere are considered to be highly effective metasomatic agents?

4 Carbonate is a widespread component of oceanic crust hydrothermally altered near mid-ocean ridges. When transported by plate tectonics to subduction zones, this carbonate may be recycled back into the mantle. Describe some of the processes that may influence the fate and redistribution of this subducted carbon in the fore-arc, sub-arc, and deeper environments.

5 How does fO2 vary within Earth’s mantle? What are the major controls on this variation and why is it important in understanding Earth’s deep carbon cycle?

6 Sublithospheric diamonds are believed to have formed at depths greater than the lithosphere–asthenosphere boundary (i.e. they did not form within the cratonic mantle lithosphere like the majority of kimberlite-borne diamonds). From where are they derived and how are they likely to have formed? What is the evidence for this?

7 The only currently active carbonatite volcano on Earth is Oldoinyo Lengai in Tanzania. How are the carbonatites erupted by this volcano different from all other known crustally emplaced carbonatites? Do some literature research to understand some of the hypotheses for the formation of Oldoinyo Lengai’s lavas and the possible reasons that they are so anomalous relative to other older carbonatites.

8 What are the likely reasons for the absence of crustally emplaced carbonatite melts in subduction zones?

9 Describe ways in which CO2-rich silicate melts can form in Earth’s upper mantle. In what sorts of tectonic settings are these melts likely to erupt?

10 Draw a cross-section of Earth showing the main tectonic settings (e.g. mid-ocean ridge, subduction zone, intraplate volcanic setting, continental and cratonic setting, etc.) and illustrate the locations of major carbon reservoirs and the nature of the carbon-bearing species that may be present in each. Discuss processes by which carbon may move between these reservoirs.

References

Dawson, J. B. Sodium carbonate lavas from Oldoinyo Lengai, Tanganyika. Nature 195, 1075 (1962).Google Scholar
Wyllie, P. J., Baker, M. B. & White, B. S. Experimental boundaries for the origin and evolution of carbonatites. Lithos 26, 319 (1990).Google Scholar
Wallace, M. E. & Green, D. H. An experimental-determination of primary carbonatite magma composition. Nature 335, 343346 (1988).Google Scholar
Yaxley, G. & Brey, G. Phase relations of carbonate-bearing eclogite assemblages from 2.5 to 5.5 GPa: implications for petrogenesis of carbonatites. Contrib Mineral Petrol 146, 606619 (2004).Google Scholar
Dasgupta, R. & Hirschmann, M. M. Melting in the Earth’s deep upper mantle caused by carbon dioxide. Nature 440, 659662 (2006).Google Scholar
Dasgupta, R. & Hirschmann, M. M. The deep carbon cycle and melting in Earth’s interior. Earth Planet Sci Lett 298, 113 (2010).Google Scholar
Yaxley, G., Crawford, A. & Green, D. Evidence for carbonatite metasomatism in spinel peridotite xenoliths from western Victoria, Australia. Earth Planet Sci Lett 107, 305317 (1991).Google Scholar
Yaxley, G., Green, D. & Kamenetsky, V. Carbonatite metasomatism in the southeastern Australian lithosphere. J Petrol 39, 19171930 (1998).Google Scholar
Rudnick, R. L., Mcdonough, W. F. & Chappell, B. W. Carbonatite metasomatism in the northern Tanzanian mantle – petrographic and geochemical characteristics. Earth Planet Sci Lett 114, 463475 (1993).Google Scholar
Weiss, Y., McNeill, J., Pearson, D. G., Nowell, G. M. & Ottley, C. J. Highly saline fluids from a subducting slab as the source for fluid-rich diamonds. Nature 524, 339342 (2015).Google Scholar
Golovin, A. V., Sharygin, I. S., Kamenetsky, V. S., Korsakov, A. V. & Yaxley, G. M. Alkali-carbonate melts from the base of cratonic lithospheric mantle: links to kimberlites. Chem Geol 483, 261274 (2018).Google Scholar
Kiseeva, E. S., Litasov, K. D., Yaxley, G. M., Ohtani, E. & Kamenetsky, V. S. Melting and phase relations of carbonated eclogite at 9-21 GPa and the petrogenesis of alkali-rich melts in the deep mantle. J Petrol 54, 15551583 (2013).Google Scholar
Thomson, A. R., Walter, M. J., Kohn, S. C. & Brooker, R. A. Slab melting as a barrier to deep carbon subduction. Nature 529, 7679 (2016).Google Scholar
Litasov, K. & Ohtani, E. Solidus of carbonate eclogite in the system CaO–Al2O3–MgO–SiO2–Na2O–CO2 to 32 GPa and carbonatite liquid in the deep mantle. Earth Planet Sci Lett 295 , 115126 (2010).Google Scholar
Kaminsky, F. Mineralogy of the lower mantle: a review of “super-deep” mineral inclusions in diamond. Earth Sci Rev 110, 127147 (2012).Google Scholar
Hunter, R. H. & Mckenzie, D. The equilibrium geometry of carbonate melts in rocks of mantle composition. Earth Planet Sci Lett 92, 347356 (1989).Google Scholar
Hammouda, T. & Laporte, D. Ultrafast mantle impregnation by carbonatite melts. Geology 28, 283285 (2000).Google Scholar
Shatskiy, A. et al. Silicate diffusion in alkali-carbonatite and hydrous melts at 16.5 and 24 GPa: implication for the melt transport by dissolution–precipitation in the transition zone and uppermost lower mantle. Phys Earth Planet Int 225, 111 (2013).Google Scholar
Taylor, W. R. & Green, D. H. The petrogenic role of methane: effect on liquidus phase relations and the solubility mechanism of reduced C–H volatiles. The Geochemical Society Special Publication No. 1, 121–137 (1987).Google Scholar
Luth, R. W. Diamonds, eclogites, and the oxidation-state of the Earth’s mantle. Science 261, 6668 (1993).Google Scholar
Stagno, V., Ojwang, D. O., McCammon, C. A. & Frost, D. J. The oxidation state of the mantle and the extraction of carbon from Earth’s interior. Nature 493, 8488 (2013).Google Scholar
Kennedy, C. S. & Kennedy, G. C. The equilibrium boundary between graphite and diamond. J Geophys Res 81, 24672470 (1976).Google Scholar
Yaxley, G. M., Berry, A. J., Rosenthal, A., Woodland, A. B. & Paterson, D. Redox preconditioning deep cratonic lithopshere for kimberlite genesis – evidence from the central Slave Craton. Nat Sci Rep 7 , 30 (2017).Google Scholar
Kiseeva, E. S. et al. Oxidized iron in garnets from the mantle transition zone. Nat Geosci 11 , 144147 (2018).Google Scholar
Cottrell, E. & Kelley, K. A. The oxidation state of Fe in MORB glasses and the oxygen fugacity of the upper mantle. Earth Planet Sci Lett 305, 270282, (2011).Google Scholar
Berry, A. J., Stewart, G. A., O’Neill, H. S. C., Mallmann, G. & Mosselmans, J. F. W. A re-assessment of the oxidation state of iron in MORB glasses. Earth Planet Sci Lett 483, 114123 (2018).Google Scholar
Gudmundsson, G. & Wood, B. J. Experimental tests of garnet peridotite oxygen barometry. Contrib Mineral Petrol 119, 5667 (1995).Google Scholar
Stagno, V., Frost, D. J., McCammon, C. A., Mohseni, H. & Fei, Y. The oxygen fugacity at which graphite or diamond forms from carbonate-bearing melts in eclogitic rocks. Contrib Mineral Petrol 169, 16 (2015).Google Scholar
Stagno, V. & Frost, D. J. Carbon speciation in the asthenosphere: experimental measurements of the redox conditions at which carbonate-bearing melts coexist with graphite or diamond in peridotite assemblages. Earth Planet Sci Lett 300, 7284 (2010).Google Scholar
Falloon, T. J. & Green, D. H. The solidus of carbonated, fertile peridotite. Earth Planet Sci Lett 94, 364370 (1989).Google Scholar
Falloon, T. J. & Green, D. H. Solidus of carbonated fertile peridotite under fluid-saturated conditions. Geology 18, 195199 (1990).Google Scholar
Dasgupta, R. & Hirschmann, M. M. Effect of variable carbonate concentration on the solidus of mantle peridotite. Am Mineral 92, 370379 (2007).Google Scholar
Dasgupta, R., Hirschmann, M. M. & Smith, N. D. Partial melting experiments of peridotite + CO2 at 3 GPa and genesis of alkalic ocean island basalts. J. Petrol 48, 20932124 (2007).Google Scholar
Dasgupta, R., Hirschmann, M. M. & Smith, N. D. Water follows carbon: CO2 incites deep silicate melting and dehydration beneath mid-ocean ridges. Geology 35, 135138 (2007).Google Scholar
Dasgupta, R., Stalker, K., Withers, A. C. & Hirschmann, M. M. The transition from carbonate-rich to silicate-rich melts in eclogite: partial melting experiments of carbonated eclogite at 3 GPa. Lithos 73, S23 (2004).Google Scholar
Lee, W. J. & Wyllie, P. J. Petrogenesis of carbonatite magmas from mantle to crust, constrained by the system CaO–(MgO+FeO*)(Na2O+K2O)–(SiO2+Al2O3+TiO2)–CO2. J Petrol 39, 495517 (1998).Google Scholar
Ryabchikov, I. D., Edgar, A. D. & Wyllie, P. J. Partial melting in the systen carbonate phosphate peridotite at 30 kbar. Geokhimiya 2, 163168 (1991).Google Scholar
White, B. S. & Wyllie, P. J. Solidus reactions in synthetic lherzolite–H2O–CO2 from 20–30kbar, with applications to melting and metasomatism. J Volcanol Geoth Res 50, 117130 (1992).Google Scholar
Wyllie, P. J. Peridotite–CO2–H2O and carbonatitic liquids in upper asthenosphere. Nature 266, 4547 (1977).Google Scholar
Wyllie, P. J. Mantle fluid compositions buffered in peridotite–CO2–H2O by carbonates, amphibole, and phlogopite. J Geol 86, 687713 (1978).Google Scholar
Wyllie, P. J. Fusion of peridotite–H2O–CO2 in system peridotite–H–C–O at upper mantle pressures. Eos Trans Am Geophysl Union 59, 398398 (1978).Google Scholar
Newton, R. C. & Sharp, W. E. Stability of forsterite + CO2 and its bearing on the role of CO2 in the mantle. Earth Planet Sci Lett 26, 239244 (1975).Google Scholar
Haselton, H. T., Sharp, W. E. & Newton, R. C. CO2 fugacity at high temeratures and pressures from experimental decarbonation reactions. Geophys Res Lett 5, 753 (1978).Google Scholar
Eggler, D. H., Kushiro, J. & Holloway, J. R. Free energies of decarbonation reactions at mantle pressures, I. Stability of the assemblage forsterite-enstatite-magnesite in the system MgO–SiO2–CO2–H2O to 60 kbar. Am Mineral 64, 288 (1979).Google Scholar
Johannes, W. An experimental investigation of the system MgO–SiO2–H2O–CO2. Am J Sci 267, 1083 (1969).Google Scholar
Wyllie, P. J. Magmass and volatile components. Am Mineral 64, 469500 (1979).Google Scholar
Eggler, D. H. The effect of CO2 on partial melting of peridotite in the system Na2O–CaO–Al2O3–MgO–SiO2–CO2 to 35 kbar, with an analysis of melting in a peridotite–H2O–CO2 system. Am J Sci 278, 305 (1978).Google Scholar
Kushiro, I. Carbonate–silicate reactions at high presures and possible presence of dolomite and magnesite in the upper mantle. Earth Planet Sci Lett 28, 116120(1975).Google Scholar
Brey, G. et al. Pyroxene–carbonate reactions in the upper mantle. Earth Planet Sci Lett 62, 6374 (1983).Google Scholar
Yaxley, G. M., Crawford, A. J. & Green, D. H. Evidence for carbonatite metasomatism in spinel peridotite xenoliths from Western Victoria, Australia. Earth Planet Sci Lett 107, 305317 (1991).Google Scholar
Rudnick, R. L., McDonough, W. F. & Chappell, B. W. Carbonatite metasomatism in the northern Tanzanian mantle: petrographic and geochemical characteristics. Earth Planet Sci Lett 114, 463475 (1993).Google Scholar
Dalton, J. A. & Wood, B. J. The compositions of primary carbonate melts and their evolution through wallrock reaction in the mantle. Earth Planet Sci Lett 119, 511525 (1993).Google Scholar
Foley, S. F. et al. The composition of near-solidus melts of peridotite in the presence of CO2 and H2O between 40 and 60 kbar. Lithos 112, 274283 (2009).Google Scholar
Marty, B. The origins and concentrations of water, carbon, nitrogen and noble gases on Earth. Earth Planet Sci Lett 313 –314, 5666 (2012).Google Scholar
Sleep, N. H. & Zahnle, K. Carbon dioxide cycling and implications for climate on ancient Earth. J Geophys Res Planets 106, 13731399 (2001).Google Scholar
Kelemen, P. B. & Manning, C. E. Reevaluating carbon fluxes in subduction zones, what goes down, mostly comes up. Proc Natl Acad Sci 112, E3997E4006 (2015).Google Scholar
Plank, T. & Langmuir, C. H. The chemical composition of subducting sediment and its consequences for the crust and mantle. Chem Geol 145, 325394 (1998).Google Scholar
Plank, T. The chemical composition of subducting sediments. Treatise Geochem 4, 607629 (2014).Google Scholar
Alt, J. C. & Teagle, D. A. H. The uptake of carbon during alteration of ocean crust. Geochim Cosmochim Acta 63, 15271535 (1999).Google Scholar
Connolly, J. A. D. Computation of phase equilibria by linear programming; a tool for geodynamic modelling and its application to subduction zone decarbonation. Earth Planet Sci Lett 236, 524541 (2005).Google Scholar
Manning, C. E., Shock, E. L. & Sverjensky, D. A. The chemistry of carbon in aqueous fluids at crustal and upper-mantle conditions: experimental and theoretical constraints. Rev Mineral Geochem 75, 109148 (2013).Google Scholar
Ague, J. J. & Nicolescu, S. Carbon dioxide released from subduction zones by fluid-mediated reactions. Nat Geosci 7, 355 (2014).Google Scholar
Piccoli, F. et al. Carbonation by fluid–rock interactions at high-pressure conditions: implications for carbon cycling in subduction zones. Earth Planet Sci Lett 445, 146159 (2016).Google Scholar
Spandler, C., Hermann, J., Faure, K., Mavrogenes, J. A. & Arculus, R. J. The importance of talc and chlorite “hybrid” rocks for volatile recycling through subduction zones; evidence from the high-pressure subduction mélange of New Caledonia. Contrib Mineral Petrol 155, 181198 (2008).Google Scholar
Scambelluri, M. et al. Carbonation of subduction-zone serpentinite (high-pressure ophicarbonate; Ligurian Western Alps) and implications for the deep carbon cycling. Earth Planet Sci Lett 441, 155166 (2016).Google Scholar
Sieber, M. J., Hermann, J. & Yaxley, G. M. An experimental investigation of C–O–H fluid-driven carbonation of serpentinites under forearc conditions. Earth Planet Sci Lett 496, 178188 (2018).Google Scholar
Syracuse, E. M., van Keken, P. E. & Abers, G. A. The global range of subduction zone thermal models. Phys Earth Planet Interiors 183, 7390 (2010).Google Scholar
Frezzotti, M. L., Selverstone, J., Sharp, Z. D. & Compagnoni, R. Carbonate dissolution during subduction revealed by diamond-bearing rocks from the Alps. Nat Geosci 4, 703 (2011).Google Scholar
Schmidt, M. W. Melting of pelitic sediments at subarc depths: 2. Melt chemistry, viscosities and a parameterization of melt composition. Chem Geol 404, 168182 (2015).Google Scholar
Korsakov, A. V. & Hermann, J. Silicate and carbonate melt inclusions associated with diamonds in deeply subducted carbonate rocks. Earth Planet Sci Lett 241, 104118 (2006).Google Scholar
Poli, S. Carbon mobilized at shallow depths in subduction zones by carbonatitic liquids. Nat Geosci 8, 633 (2015).Google Scholar
Marschall, H. R. & Schumacher, J. C. Arc magmas sourced from melange diapirs in subduction zones. Nat Geosci 5, 862867 (2012).Google Scholar
Tumiati, S., Fumagalli, P., Tiraboschi, C. & Poli, S. An experimental study on COH-bearing peridotite up to 3.2 GPa and implications for crust–mantle recycling. J Petrol 54, 453479 (2013).Google Scholar
Smith, C. B. et al. Diamonds from Dachine, French Guiana: a unique record of early Proterozoic subduction. Lithos 265, 8295 (2016).Google Scholar
Green, D. H. Experimental petrology of peridotites, including effects of water and carbon on melting in the Earth’s upper mantle. Phys Chem Mineral 42, 95122 (2015).Google Scholar
Jones, A. P., Genge, M. & Carmody, L. Carbonate melts and carbonatites. Rev Mineral Geochem 75, 289322 (2013).Google Scholar
Saha, S., Dasgupta, R. & Tsuno, K. High pressure phase relations of a depleted peridotite fluxed by CO2–H2O‐bearing siliceous melts and the origin of Mid‐Lithospheric Discontinuity. Geochem Geophys Geosyst 19, 595620 (2018).Google Scholar
Gorman, P. J., Kerrick, D. M. & Connolly, J. A. D. Modeling open system metamorphic decarbonation of subducting slabs. Geochem Geophys Geosyst 7, 121 (2006).Google Scholar
Molina, J. F. & Poli, S. Carbonate stability and fluid composition in subducted oceanic crust: an experimental study on H2O–CO2-bearing basalts. Earth Planet Sci Lett 176, 295310 (2000).Google Scholar
Kelley, K. A. & Cottrell, E. The influence of magmatic differentiation on the oxidation state of Fe in a basaltic arc magma. Earth Planet Sci Lett 329 –330, 109121 (2012).Google Scholar
Brenker, F. E. et al. Carbonates from the lower part of transition zone or even the lower mantle. Earth Planet Sci Lett 260, 19 (2007).Google Scholar
Bulanova, G. P. et al. Mineral inclusions in sublithospheric diamonds from Collier 4 kimberlite pipe, Juina, Brazil: subducted protoliths, carbonated melts and primary kimberlite magmatism. Contrib Mineral Petrol 160, 489510 (2010).Google Scholar
Thomson, A. R. et al. Origin of sub-lithospheric diamonds from the Juina-5 kimberlite (Brazil): constraints from carbon isotopes and inclusion compositions. Contrib Mineral Petrol 168, 1081 (2014).Google Scholar
Zedgenizov, D. A., Kagi, H., Shatsky, V. S. & Ragozin, A. L. Local variations of carbon isotope composition in diamonds from Sao-Luis (Brazil): evidence for heterogenous carbon reservoir in sublithospheric mantle. Chem Geol 363, 114124 (2010).Google Scholar
Thomson, A. R. et al. Trace element composition of silicate inclusions in sub-lithospheric diamonds from the Juina-5 kimberlite: evidence for diamond growth from slab melts. Lithos 265, 108124 (2016).Google Scholar
Walter, M. J. et al. Primary carbonatite melt from deeply subducted oceanic crust. Nature 454, 622 (2008).Google Scholar
Burnham, A. D. et al. Stable isotope evidence for crustal recycling as recorded by superdeep diamonds. Earth Planet Sci Lett 432, 374380 (2015).Google Scholar
Ickert, R. B., Stachel, T., Stern, R. A. & Harris, J. W. Diamond from recycled crustal carbon documented by coupled δ18O–δ13C measurements of diamonds and theirinclusions. Earth Planet Sci Lett 364, 8597 (2013).Google Scholar
Tsuno, K. & Dasgupta, R. Melting phase relation of nominally anhydrous, carbonated pelitic-eclogite at 2.5–3.0 GPa and deep cycling of sedimentary carbon. Contrib Mineral Petrol 161, 743763 (2011).Google Scholar
Grassi, D. & Schmidt, M. W. Melting of carbonated pelites at 8-13 GPa: generating K-rich carbonatites for mantle metasomatism. Contrib Mineral Petrol 162, 169191 (2011).Google Scholar
Mann, U. & Schmidt, M. W. Melting of pelitic sediments at subarc depths: 1. Flux vs. fluid-absent melting and a parameterization of melt productivity. Chem Geol 404, 150167 (2015).Google Scholar
Keshav, S. & Gudfinnsson Gudmundur, H. Experimentally dictated stability of carbonated oceanic crust to moderately great depths in the Earth: results from the solidus determination in the system CaO–MgO–Al2O3–SiO2–CO2. J Geophys Res Solid Earth 115, B05205 (2010).Google Scholar
Litasov, K. & Ohtani, E. The solidus of carbonated eclogite in the system CaO–Al2O3–MgO–SiO2–Na2O–CO2 to 32GPa and carbonatite liquid in the deep mantle. Earth Planet Sci Lett 295, 115126 (2010).Google Scholar
Dasgupta, R., Hirschmann, M. M. & Withers, A. C. Deep global cycling of carbon constrained by the solidus of anhydrous, carbonated eclogite under upper mantle conditions. Earth Planet Sci Lett 227, 7385 (2004).Google Scholar
Hammouda, T. High-pressure melting of carbonated eclogite and experimental constraints on carbon recycling and storage in the mantle. Earth Planet Sci Lett 214, 357368 (2003).Google Scholar
Kiseeva, E. S. et al. An experimental study of carbonated eclogite at 3.5–5.5 GPa – implications for silicate and carbonate metasomatism in the cratonic mantle. J Petrol 53, 727759 (2012).Google Scholar
Yaxley, G. M. & Green, D. H. Experimental demonstration of refractory carbonate-bearing eclogite and siliceous melt in the subduction regime. Earth Planet Sci Lett 128, 313325 (1994).Google Scholar
Dasgupta, R., Hirschmann, M. M. & Dellas, N. The effect of bulk composition on the solidus of carbonated eclogite from partial melting experiments at 3 GPa. Contrib Mineral Petrol 149, 288305 (2005).Google Scholar
Gerbode, C. & Dasgupta, R. Carbonate-fluxed melting of MORB-like pyroxenite at 2.9 GPa and genesis of HIMU ocean island basalts. J Petrol 51, 20672088 (2010).Google Scholar
Dasgupta, R., Hirschmann, M. M. & Stalker, K. Immiscible transition from carbonate-rich to silicate-rich melts in the 3 GPa melting interval of eclogite + CO2 and genesis of silica-undersaturated ocean island lavas. J Petrol 47, 647671 (2006).Google Scholar
Litasov, K. D., Shatskiy, A., Ohtani, E. & Yaxley, G. M. Solidus of alkaline carbonatite in the deep mantle. Geology 41, 7982 (2013).Google Scholar
Gudfinnsson, G. H. & Presnall, D. C. Continuous gradations among primary carbonatitic, kimberlitic, melilititic, basaltic, picritic, and komatiitic melts in equilibrium with garnet lherzolite at 3–8GPa. J Petrol 46, 16451659 (2005).Google Scholar
Tappe, S., Foley, S. F., Jenner, G. A. & Kjarsgaard, B. A. Integrating ultramafic lamprophyres into the IUGS classification of igneous rocks: rationale and implications. J Petrol 46, 18931900 (2005).Google Scholar
Tappe, S. et al. Between carbonatite and lamproite – diamondiferous Torngat ultramafic lamprophyres formed by carbonate-fluxed melting of cratonic MARID-type metasomes. Geochim Cosmochim Acta 72, 32583286 (2008).Google Scholar
Sparks, R. S. J. Kimberlite volcanism. Ann Rev Earth Planet Sci 41, 497528 (2013).Google Scholar
Mitchell, R. H. Kimberlites, Orangeites, and Related Pocks (Plenum Press, 1995).Google Scholar
Becker, M. & Le Roex, A. P. Geochemistry of South African on- and off-craton, Group I and Group II kimberlites: petrogenesis and source region evolution. J Petrol 47, 673703 (2006).Google Scholar
Mitchell, R. H. Kimberlites and lamproites – primary sources of diamond. Geosci Canada 18, 116 (1991).Google Scholar
Nowell, G. M. et al. Hf isotope systematics of kimberlites and their megacrysts: new constraints on their source regions. J Petrol 45, 15831612 (2004).Google Scholar
Yaxley, G. M. et al. The discovery of kimberlites in Antarctica extends the vast Gondwanan Cretaceous province. Nat Commun 4, 2921 (2013).Google Scholar
Novella, D. & Frost, D. J. The composition of hydrous partial melts of garnet peridotite at 6 GPa: implications for the origin of Group II kimberlites. J Petrol 55, 20972124 (2014).Google Scholar
Foley, S. F. & Fischer, T. P. An essential role for continental rifts and lithosphere in the deep carbon cycle. Nat Geosci 10, 897902 (2017).Google Scholar
Patterson, M., Francis, D. & McCandless, T. Kimberlites: magmas or mixtures? Lithos 112, 191200 (2009).Google Scholar
Kamenetsky, M. B. et al. Kimberlite melts rich in alkali chlorides and carbonates: a potent metasomatic agent in the mantle. Geology 32, 845848 (2004).Google Scholar
Kamenetsky, V. S. et al. Olivine in the Udachnaya-East kimberlite (Yakutia, Russia): types, compositions and origins. J Petrol 49, 823839 (2008).Google Scholar
Russell, J. K., Porritt, L. A., Lavallee, Y. & Dingwell, D. B. Kimberlite ascent by assimilation-fuelled buoyancy. Nature 481, 352356 (2012).Google Scholar
Girnis, A. V., Brey, G. P. & Ryabchikov, I. D. Origin of Group 1A kimberlites: fluid-saturated melting experiments at 45–55 kbar. Earth Planet Sci Lett 134, 283296 (1995).Google Scholar
Girnis, A. V., Bulatov, V. K. & Brey, G. P. Formation of primary kimberlite melts – constraints from experiments at 6–12GPa and variable CO2/H2O. Lithos 127, 401413 (2011).Google Scholar
Nell, J. & Wood, B. J. High-temperature electrical measurements and thermodynamic properties of Fe3O4–FeCr2O4–MgCr2O4–FeAl2O4 spinels. Am Mineral 76, 405426 (1991).Google Scholar
Ballhaus, C., Berry, R. F. & Green, D. H. High-pressure experimental calibration of the olivine–ortho-pyroxene–spinel oxygen geobarometer – implications for the oxidation-state of the upper mantle. Contrib Mineral Petrol 107, 2740 (1991).Google Scholar
O’Neill, H. S. C. & Wall, V. J. The olivine–orthopyroxene–spinel oxygen geobarometer, the nickel precipitation curve, and the oxygen fugacity of the Earth’s upper mantle. J Petrol 28, 11691191 (1987).Google Scholar
Woodland, A. B. & Koch, M. Variation in oxygen fugacity with depth in the upper mantle beneath the Kaapvaal craton, Southern Africa. Earth Planet Sci Lett 214, 295310 (2003).Google Scholar
Yaxley, G. M., Berry, A. J., Kamenetsky, V. S., Woodland, A. B. & Golovin, A. V. An oxygen fugacity profile through the Siberian Craton–Fe K-edge XANES determinations of Fe3+/∑ Fe in garnets in peridotite xenoliths from the Udachnaya East kimberlite. Lithos 140, 142151 (2012).Google Scholar
Frost, D. J. & McCammon, C. A. The redox state of Earth’s mantle. Ann Rev Earth Planet Sci 36, 389420 (2008).Google Scholar
Rohrbach, A., Ghosh, S., Schmidt, M. W., Wijbrans, C. H. & Klemme, S. The stability of Fe–Ni carbides in the Earth’s mantle: evidence for a low Fe–Ni–C melt fraction in the deep mantle. Earth Planet Sci Lett 388, 211221 (2014).Google Scholar
Tsuno, K. & Dasgupta, R. Fe–Ni–Cu–C–S phase relations at high pressures and temperatures – the role of sulfur in carbon storage and diamond stability at mid- to deep-upper mantle. Earth Planet Sci Lett 412, 132142 (2015).Google Scholar
Yaxley, G. M., Berry, A. J., Kamenetsky, V. S., Woodland, A. B. & Golovin, A. V. An oxygen fugacity profile through the Siberian Craton; Fe K-edge XANES determinations of Fe3+/∑Fe in garnets in peridotite xenoliths from the Udachnaya East kimberlite. Lithos 140 –141, 142151 (2012).Google Scholar
Foley, S. F. Rejuvenation and erosion of the cratonic lithosphere. Nat Geosci 1, 503510 (2008).Google Scholar
Coltorti, M., Beccaluva, L., Bonadiman, C., Salvini, L. & Siena, F. Glasses in mantle xenoliths as geochemical indicators of metasomatic agents. Earth Planet Sci Lett 183, 303320 (2000).Google Scholar
Delpech, G. et al. Feldspar from carbonate-rich silicate metasomatism in the shallow oceanic mantle under Kerguelen Islands (South Indian Ocean). Lithos 75, 209237 (2004).Google Scholar
Misra, K. C., Anand, M., Taylor, L. A. & Sobolev, N. V. Multi-stage metasomatism of diamondiferous eclogite xenoliths from the Udachnaya kimberlite pipe, Yakutia, Siberia. Contrib Mineral Petrol 146, 696714 (2004).Google Scholar
Taylor, W. R. & Green, D. H. Measurement of reduced peridotite–C–O–H solidus and implications for redox melting of the mantle. Nature 332, 349352 (1988).Google Scholar
Litasov, K. D., Shatskiy, A. & Ohtani, E. Melting and subsolidus phase relations in peridotite and eclogite systems with reduced COH fluid at 3–16 GPa. Earth Planet Sci Lett 391, 8799 (2014).Google Scholar
Eguchi, J. & Dasgupta, R. Redox state of the convective mantle from CO2-trace element systematics of oceanic basalts. Geochem Perspect Lett 8, 721 (2018).Google Scholar
Kogarko, L. N., Henderson, C. M. B. & Pacheco, H. Primary Ca-rich carbonatite magma and carbonate–silicate–sulfide liquid immiscibility in the upper-mantle. Contrib Mineral Petrol 121, 267274 (1995).Google Scholar
Schiano, P., Clocchiatti, R., Shimizu, N., Weis, D. & Mattielli, N. Cogenetic silica-rich and carbonate-rich melts trapped in mantle minerals in Kerguelen ultramafic xenoliths – implications for metasomatism in the oceanic upper-mantle. Earth Planet Sci Lett 123, 167178 (1994).Google Scholar
Dixon, J., Clague David, A., Cousens, B., Monsalve Maria, L. & Uhl, J. Carbonatite and silicate melt metasomatism of the mantle surrounding the Hawaiian plume: evidence from volatiles, trace elements, and radiogenic isotopes in rejuvenated‐stage lavas from Niihau, Hawaii. Geochem Geophys Geosyst 9, 9 (2008).Google Scholar
Rohrbach, A. & Schmidt, M. W. Redox freezing and melting in the Earth’s deep mantle resulting from carbon-iron redox coupling. Nature 472, 209212, (2011).Google Scholar
Dasgupta, R. Volatile-bearing partial melts beneath oceans and continents – where, how much and of what compositions. Am J Sci 318, 141165 (2018).Google Scholar
Eguchi, J. & Dasgupta, R. CO2 content of andesitic melts at graphite-saturated upper mantle conditions with implications for redox state of oceanic basalt source regions and remobilization of reduced carbon from subducted eclogite. Contrib Mineral Petrol 172, 12 (2017).Google Scholar
Dalton, J. A. & Presnall, D. C. Carbonatitic melts along the solidus of model lherzolite in the system CaO–MgO–Al2O3–SiO2–CO2 from 3 to 7 GPa. Contrib Mineral Petrol 131, 123135 (1998).Google Scholar
Dasgupta, R. et al. Carbon-dioxide-rich silicate melt in the Earth’s upper mantle. Nature 493, 211215 (2013).Google Scholar
Green, D. H. & Wallace, M. E. Mantle metasomatism by ephemeral carbonatite melts. Nature 336, 459462 (1988).Google Scholar
Keshav, S. & Gudfinnsson, G. H. Melting phase equilibria of model carbonated peridotite from 8 to 12 GPa in the system CaO–MgO–Al2O3–SiO2–CO2 and kimberlitic liquids in the Earth’s upper mantle. Am Mineral 99, 11191126 (2014).Google Scholar
Mysen, B. O. & Boettcher, A. L. Melting of a hydrous mantle: I. Phase relations of natural peridotite at high pressures and temperatures with controlled activities of water, carbon dioxide, and hydrogen. J Petrol 16, 520548 (1975).Google Scholar
Wendlandt, R. F. & Mysen, B. O. Melting relations of natural peridotite+CO2 as a function of degree of partial melting at 15 and 30 kbar. Am Mineral 65, 3744 (1980).Google Scholar
Wyllie, P. J. & Huang, W. L. Carbonation and melting reactions in system CaO–MgO–SiO2–CO2 at mantle pressures with geophysical and petrological applications. Contrib Mineral Petrol 54, 79107 (1976).Google Scholar
Yaxley, G. M. & Brey, G. P. Phase relations of carbonate-bearing eclogite assemblages from 2.5 to 5.5 GPa: implications for petrogenesis of carbonatites. Contrib Mineral Petrol 146, 606619 (2004).Google Scholar
Minarik, W. G. & Watson, E. B. Interconnectivity of carbonate melt at low melt fraction. Earth Planet Sci Lett 133, 423437 (1995).Google Scholar
Helffrich, G. R. & Wood, B. J. The Earth’s mantle. Nature 412, 501 (2001).Google Scholar
Dasgupta, R., Hirschmann, M. M. & Smith, N. D. Partial melting experiments of peridotite + CO2 at 3 GPa and genesis of alkalic ocean island basalts. J Petrol 48, 20932124 (2007).Google Scholar
Mallik, A. & Dasgupta, R. Reactive infiltration of MORB-eclogite-derived carbonated silicate melt into fertile peridotite at 3 GPa and genesis of alkalic magmas. J Petrol 54, 22672300 (2013).Google Scholar
Mallik, A. & Dasgupta, R. Effect of variable CO2 on eclogite‐derived andesite and lherzolite reaction at 3 GPa – implications for mantle source characteristics of alkalic ocean island basalts. Geochem Geophys Geosyst 15, 15331557 (2014).Google Scholar
Guillot, B. & Sator, N. Carbon dioxide in silicate melts: a molecular dynamics simulation study. Geochim Cosmochim Acta 75, 18291857 (2011).Google Scholar
Morizet, Y. et al. Towards the reconciliation of viscosity change and CO2-induced polymerization in silicate melts. Chem Geol 458, 3847 (2017).Google Scholar
Langmuir, C., Klein, E. M. & Plank, T. Petrological systematics of mid-ocean ridge basalts: contraints on melt generation beneath ocean ridges. In: Mantle Flow and Melt Generation at Mid-ocean Ridges, Geophysical Monograph Series (eds. Phipps-Morgan, J., Blackman, D. K., & Sinton, J. M.), 183280 (American Geophysical Union, 1992).Google Scholar
Ghosh, S., Ohtani, E., Litasov, K. D. & Terasaki, H. Solidus of carbonated peridotite from 10 to 20 GPa and origin of magnesiocarbonatite melt in the Earth’s deep mantle. Chem Geol 262, 1728 (2009).Google Scholar
Frost, D. J. et al. Experimental evidence for the existence of iron-rich metal in the Earth’s lower mantle. Nature 428, 409412 (2004).Google Scholar
Rohrbach, A. et al. Metal saturation in the upper mantle. Nature 449, 456458 (2007).Google Scholar
Harmer, R. E. & Gittins, J. The origin of dolomitic carbonatites: field and experimental constraints. J African Earth Sci 25, 528 (1997).Google Scholar
Nielsen, T. F. D., Solovova, I. P. & Veksler, I. V. Parental melts of melilitolite and origin of alkaline carbonatite: evidence from crystallised melt inclusions, Gardiner complex. Contrib Mineral Petrol 126, 331344 (1997).Google Scholar
Guzmics, T. et al. Primary carbonatite melt inclusions in apatite and in K-feldspar of clinopyroxene-rich mantle xenoliths hosted in lamprophyre dikes (Hungary). Mineral Petrol 94, 225 (2008).Google Scholar
Woolley, A. R. & Church, A. A. Extrusive carbonatites: a brief review. Lithos 85, 114 (2005).Google Scholar
Guzmics, T. et al. Carbonatite melt inclusions in coexisting magnetite, apatite and monticellite in Kerimasi calciocarbonatite, Tanzania: melt evolution and petrogenesis. Contrib Mineral Petrol 161, 177196 (2011).Google Scholar
Zaitsev, A. N. & Keller, J. Mineralogical and chemical transformation of Oldoinyo Lengai natrocarbonatites, Tanzania. Lithos 91, 191207 (2006).Google Scholar
Mitchell, R. H. Carbonatites and carbonatites and carbonatites. Can Mineral 43, 20492068 (2005).Google Scholar
Weng, Z., Jowitt, S. M., Mudd, G. M. & Haque, N. A detailed assessment of global rare earth element resources: opportunities and challenges. Econ Geol 110, 19251952 (2015).Google Scholar
Harmer, R. E. & Gittins, J. The case for primary, mantle-derived carbonatite magma. J Petrol 39, 18951903 (1998).Google Scholar
Watkinson, D. H. & Wyllie, P. J. Experimental study of the composition join NaAlSiO4–CaCO3–H2O and the genesis of alkalic rock–carbonatite complexes. J Petrol 12, 357378 (1971).Google Scholar
Neumann, E. R., Wulff-Pedersen, E., Pearson, N. J. & Spencer, E. A. Mantle xenoliths from Tenerife (Canary Islands): evidence for reactions between mantle peridotites and silicic carbonatite melts inducing Ca metasomatism. J Petrol 43, 825857 (2002).Google Scholar
Klein-BenDavid, O. et al. High-Mg carbonatitic microinclusions in some Yakutian diamonds – a new type of diamond-forming fluid. Lithos 112, 648659 (2009).Google Scholar
Kjarsgaard, B. & Peterson, T. Nephelinite–carbonatite liquid immiscibility at Shombole volcano, East Africa: petrographic and experimental evidence. Miner Petrol 43, 293314 (1991).Google Scholar
Guzmics, T., Zajacz, Z., Mitchell, R. H., Szabó, C. & Wälle, M. The role of liquid–liquid immiscibility and crystal fractionation in the genesis of carbonatite magmas: insights from Kerimasi melt inclusions. Contrib Mineral Petrol 169, 17 (2015).Google Scholar
Weidendorfer, D., Schmidt, M. W. & Mattsson, H. B. Fractional crystallization of Si-undersaturated alkaline magmas leading to unmixing of carbonatites on Brava Island (Cape Verde) and a general model of carbonatite genesis in alkaline magma suites. Contrib Mineral Petrol 171, 43 (2016).Google Scholar
Woolley, A. R. & Kjarsgaard, B. Carbonatite Occurrences of the World: Map and Database (Geological Survey of Canada, 2008).Google Scholar
Jelsma, H., Barnett, W., Richards, S. & Lister, G. Tectonic setting of kimberlites. Lithos 112, 155165 (2009).Google Scholar
Woolley, A. R. & Bailey, D. K. The crucial role of lithospheric structure in the generation and release of carbonatites: geological evidence. Mineral Mag 76, 259270 (2012).Google Scholar
Bell, K. & Tilton, G. R. Nd, Pb and Sr isotopic compositions of east African carbonatites: evidence for mantle mixing and plume inhomogeneity. J Petrol 42, 19271945 (2001).Google Scholar
Bailey, D. K. Episodic alkaline igneous activity across Africa: implications for the causes of continental break-up. Geol Soc Lond Spec Publ 68, 9198 (1992).Google Scholar
Bell, K. Carbonatites: relationships to mantle-plume activity. Geol Soc Am Special Paper, 352, 267290 (2001).Google Scholar
Ernst, R. E. & Bell, K. Large igneous provinces (LIPSs) and carbonatites. Mineral Petrol 98, 5576 (2010).Google Scholar
Jelsma, H., Barnett, W., Richards, S. & Lister, G. Tectonic setting of kimberlites. Lithos 112, 155165 (2009).Google Scholar
Hoernle, K., Tilton, G., Le Bas, M. J., Duggen, S. & Garbe-Schonberg, D. Geochemistry of oceanic carbonatites compared with continental carbonatites: mantle recycling of oceanic crustal carbonate. Contrib Mineral Petrol 142, 520542 (2002).Google Scholar
Holm, P. M. et al. Sampling the cape verde mantle plume: evolution of melt compositions on Santo Antao, Cape Verde Islands. J Petrol 47, 145189 (2006).Google Scholar
Schmidt, M. W. & Weidendorfer, D. Carbonatites in oceanic hotspots. Geology 46, 435438 (2018).Google Scholar
Keshav, S. & Gudfinnsson, G. H. Experimentally dictated stability of carbonated oceanic crust to moderately great depths in the Earth: results from the solidus determination in the system CaO–MgO–Al2O3–SiO2–CO2. J Geophys Res B Solid Earth 115, B05205 (2010).Google Scholar
Grassi, D. & Schmidt, M. W. The melting of carbonated pelites from 70 to 700 km depth. J Petrol 52, 765789 (2011).Google Scholar
Katsura, T., Yoneda, A., Yamazaki, D., Yoshino, T. & Ito, E. Adiabatic temperature profile in the mantle. Phys Earth Planet Interiors 183, 212218 (2010).Google Scholar
Hirschmann, M. M. Mantle solidus: experimental constraints and the effects of peridotite composition. Geochem Geophys Geosyst 24, 126 (2000).Google Scholar
Gale, A., Dalton, C. A., Langmuir, C. H., Su, Y. & Schilling, J.-G. The mean composition of ocean ridge basalts. Geochem Geophys Geosyst 14, 489518 (2012).Google Scholar
Yasuda, A., Fujii, T. & Kurita, K. Melting relations of an anhydrous mid-ocean ridge basalt from 3 to 20 GPa: implications for the behviour of subducted oceanic crust in the mantle. J Geophys Res 99, 94019414 (1994).Google Scholar
Wang, W. & Takahashi, E. Subsolidus and melting experiments of a K-rich basaltic composition to 27 GPa: implication for the behaviour of potassium in the mantle. Am Mineral 84, 357361 (1999).Google Scholar
Day, H. W. A revised diamond–graphite transition curve. Am Mineral 97, 5262 (2012).Google Scholar
Herzberg, C. & Gazel, E. Petrological evidence for secular cooling in mantle plumes. Nature 458, 619 (2009).Google Scholar
Herzberg, C. et al. Temperatures in ambient mantle and plumes: constraints from basalts, picrites, and komatiites. Geochem Geophys Geosyst 8, 2 (2007).Google Scholar
Figure 0

Figure 6.1 Schematic cross-section of a subduction zone (modified after Green75) depicting progressive slab devolatilization during subduction and zones of the mantle wedge containing carbonatitic and silicate-rich partial melts (green and orange fields, respectively).

Figure 1

Figure 6.2 Summary of the experimentally determined solidus curves for carbonated pelitic sediment and basaltic compositions. Solidus curves for carbonated basalt are shown as solid colored curves and are from: Hammouda,95 H03; Yaxley and Brey,148 YB04; Dasgupta et al.,94 D04; Keshav and Gudfinnsson,186 KG10; Kiseeva et al.,12 K13a,b; and Thomson et al.,13 T13. Labels are keyed to the compositions listed in Table 6.1. Solidus curves for carbonated sediment are shown as dashed curves and are from: Tsuno and Dasgupta,89 TD11; and Grassi and Schmidt,187 GS11. Also shown is the solidus of alkaline carbonatite (Litasov et al.,101 L13). The mantle adiabat is from Katsura et al.188 Model geotherms at the top of a subducting slab are extrapolations shown for examples of hot, warm, and cold slabs.67

Figure 2

Table 6.1 Bulk compositions (as wt.%) of anhydrous MORB and carbonated MORB used in melting studies

Figure 3

Figure 6.3 The compositions of partial melts from carbonated natural basalt and sediment from the studies of Hammouda,95 Dasgupta et al.,94 Kiseeva et al.,12 Thomson et al.,13 and Grassi and Schmidt.90 The generalized effects of increasing pressure and temperature are also shown.

Figure 4

Figure 6.4 Highly schematic representation of a section through Earth’s upper mantle modified from figure 2c of Foley and Fischer,112 showing fO2 as a function of depth. The dashed white contours are approximate contours of fO2 variation in the cratonic lithosphere based on studies of garnet peridotite xenoliths (references in the text). The dashed yellow line is the graphite–diamond transition for a typical cratonic geotherm (38 mW m–2). The red line (3) represents the path of an erupting kimberlite and the blue zone (2) near the base of the lithosphere represents a local mantle volume metasomatized to higher fO2 by asthenospheric melts derived from the brown field labeled (1).

Figure 5

Figure 6.5 (a) Pressure–temperature plot showing the generation of carbonated silicate melt in Earth’s upper mantle. A parcel of carbon-bearing mantle peridotite with pods of eclogite upwells beneath ocean islands along an adiabat (bold arrow along the dotted line). As it upwells, redox melting takes place when the mantle crosses over from the stippled zone where the carbon is present in reduced form (either as graphite or as diamond21,138) to the overlying zone where carbon is present in its oxidized form (as carbonates or as CO2 vapor at pressures lower than 2 GPa3). At the redox front, reduced carbon present in the eclogite or peridotite oxidizes to form trace to minor amounts of carbonatitic melt (labeled (1)). The carbonatitic melt causes fluxed partial melting of eclogite and peridotite because the carbonated solidi of peridotite and eclogite are at much lower temperatures at the pressure range of the upwelled parcel of mantle (labeled (2)). The fluxed partial melting of eclogite and peridotite produces carbonated silicate melts in the upper mantle. The volatile-free solidi of peridotite189 and eclogite,191 the carbonated solidi of peridotite33,142 and eclogite,148 the graphite–diamond transition,193 and the range of mantle potential temperatures in Earth’s upper mantle (orange shaded area) from ridges194 to plumes195 are plotted for reference. The broken curves for carbonated solidi are only applicable for locally oxidized domains in the mantle where carbonates can exist at depths below the redox-melting front. (b) Geodynamic scenarios involving carbonated eclogite and peridotite in the source of ocean island volcanism in intraplate settings (modified from a previous study152). (i) This scenario is applicable for locally oxidized domains in the mantle where deeper carbonatites generated by very-low-degree partial melting of carbonated peridotite and/or eclogite rise upwards and cause fluxed partial melting of volatile-free eclogite at shallower depths in the upper mantle. The carbonated partial melt of eclogite, a basanite, or andesite (a lower eclogite to carbonate ratio produces basanite, while a higher ratio produces andesite) reacts with subsolidus volatile-free peridotite. The melt-rock reaction produces product melts that display similarity in composition with ocean island basalts. (ii) Reduced carbon-bearing eclogite upwells and produces carbonated silicate partial melts of eclogite after crossing the redox-melting front. The carbonated silicate partial melt of eclogite reacts with the surrounding subsolidus volatile-free peridotite, and a similar melt-rock reaction as proposed in (i) takes place.

Figure 6

Figure 6.6 A simplified model for the extraction of carbonatitic/carbonated silicate melts from the mantle based on Stagno et al.28 If carbonates are present in the adiabatically upwelling mantle beneath mid-ocean ridges, they will lower the melting temperature of the mantle rocks and melting will take place at ~300 km depth if the adiabat has a potential temperature of 1400°C. The left-hand panel shows that the solidus of peridotite and eclogite is depressed by several hundred degrees compared to the volatile-free solidus. The central panel shows the focusing of deeply derived carbonate melts (red triangle) formed by redox melting at about 1.5 GPa lower pressures than the carbonate peridotite solidus for oxidized mantle. The right-hand panel shows estimated Fe3+/∑Fe in peridotite buffered at about 0.1 at depths below about 290 km, and buffered by FeNi alloy (≈IW) to higher values at greater depths.

Save book to Kindle

To save this book to your Kindle, first ensure [email protected] is added to your Approved Personal Document E-mail List under your Personal Document Settings on the Manage Your Content and Devices page of your Amazon account. Then enter the ‘name’ part of your Kindle email address below. Find out more about saving to your Kindle.

Note you can select to save to either the @free.kindle.com or @kindle.com variations. ‘@free.kindle.com’ emails are free but can only be saved to your device when it is connected to wi-fi. ‘@kindle.com’ emails can be delivered even when you are not connected to wi-fi, but note that service fees apply.

Find out more about the Kindle Personal Document Service.

Available formats
×

Save book to Dropbox

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Dropbox.

Available formats
×

Save book to Google Drive

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Google Drive.

Available formats
×