Your search keyword '"Monticellite"' showing total 12 results

1. Composition and emplacement of the Benfontein kimberlite sill complex (Kimberley, South Africa): Textural, petrographic and melt inclusion constraints

Author

Adam Abersteiner, Vadim S. Kamenetsky, Karsten Goemann, Montgarri Castillo-Oliver, Jay Thompson, Maya B. Kamenetsky, AR Cherry, Geoffrey H. Howarth, and Andrea Giuliani

Subjects

geography, Olivine, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geochemistry, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Baddeleyite, Petrography, Sill, Geochemistry and Petrology, engineering, Igneous differentiation, Chromite, Monticellite, Kimberlite, 0105 earth and related environmental sciences

Abstract

The Benfontein kimberlite is a renowned example of a sill complex and provides an excellent opportunity to examine the emplacement and evolution of intrusive kimberlite magmas. We have undertaken a detailed petrographic and melt inclusion study of the Benfontein Upper, Middle and Lower sills. These sills range in thickness from 0.25 to 5 m. New perovskite and baddeleyite U/Pb dating produced ages of 85.7 ± 4.4 Ma and 86.5 ± 2.6 Ma, respectively, which are consistent with previous age determinations and indicate emplacement coeval with other kimberlites of the Kimberley cluster. The Benfontein sills are characterised by large variations in texture (e.g., layering) and mineral modal abundance between different sill levels and within individual samples. The Lower Sill is characterised by carbonate-rich diapirs, which intrude into oxide-rich layers from underlying carbonate-rich levels. The general paucity of xenogenic mantle material in the Benfontein sills is attributed to its separation from the host magma during flow differentiation during lateral spreading. The low viscosity is likely responsible for non-explosive emplacement of the Benfontein sills, while the rhythmic layering is attributed to multiple magma injections. The Benfontein sills are marked by the excellent preservation of olivine and groundmass mineralogy, which is composed of monticellite, spinel, perovskite, baddeleyite, ilmenite, apatite, calcite, dolomite along with secondary serpentine and glagolevite [NaMg6[Si3AlO10](OH,O)8•H2O]. This is the first time glagolevite is reported in kimberlites. Groundmass spinel exhibits atoll-textures and is composed of a magnesian ulvospinel – magnetite (MUM) or chromite core, surrounded by occasional pleonaste and a rim of Mg-Al-magnetite. We suggest that pleonaste crystallised as a magmatic phase, but was resorbed back into the residual host melt and/or removed by alteration. Analyses of secondary inclusions in olivine and primary inclusions in monticellite, spinel, perovskite, apatite and interstitial calcite are largely composed of Ca-Mg carbonates and, to a lesser extent, alkali-carbonates and other phases. These inclusions probably represent the entrapment of variably differentiated parental kimberlite melts, which became progressively more enriched in carbonate, alkalis, halogens and sulphur during crystal fractionation. Carbonate-rich diapirs from the Lower Sill contain more exotic phase assemblages (e.g., Ba-Fe titanate, barite, ancylite, pyrochlore), which probably result from the extreme differentiation of residual kimberlite melts followed by physical separation and isolation from the parental carbonate-rich magma. It is likely that any alkali or halogen rich minerals crystallising in the groundmass were removed from the groundmass during syn−/post-magmatic alteration, or in the case of Na, remobilised to form secondary glagolevite. The Benfontein sill complex therefore provides a unique example of how the composition of kimberlites may be modified after magma emplacement in the upper crust.

Published

2019

2. Phlogopite-rich and phlogopite-poor kimberlite intrusions within the Du Toitspan kimberlite pipe, South Africa: Petrogenetic relationships and localised source heterogeneity

Author

Anton P. le Roex, Jock Robey, and Lesego Ramokgaba

Subjects

Calcite, Olivine, 010504 meteorology & atmospheric sciences, Trace element, Geochemistry, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, engineering, Phlogopite, Metasomatism, Monticellite, Kimberlite, 0105 earth and related environmental sciences, Petrogenesis

Abstract

Samples from three petrographically distinct, intrusive kimberlite bodies and associated kimberlite dykes from the eastern lobe of the Du Toitspan kimberlite pipe, Kimberley, South Africa, have been analysed for their bulk rock major and trace element compositions and their olivine and phlogopite compositions. The two dominant intrusive bodies (D13, D14) are distinguished by the one (D13) being phlogopite-rich and best classified as a macrocrystic hypabyssal phlogopite kimberlite, and the other (D14) being phlogopite-poor and best classified as a macrocrystic hypabyssal monticellite kimberlite. The minor D17 intrusive body is classified as a macrocrystic transitional hypabyssal serpentinized phlogopite kimberlite. The associated kimberlite dykes range texturally from aphanitic to macrocrystic and are classified as calcite kimberlites. The major kimberlite intrusions and their associated dykes show no evidence of crustal contamination and are characterised by broadly overlapping geochemistry except for distinctly higher K2O (> 2 wt%) and Al2O3 (>3 wt%) and flattening HREE patterns (Gd/YbN = 6.5–7.0) in the D13 – phlogopite kimberlite compared to the D14 – monticellite kimberlite and the calcite kimberlite dykes (Gd/YbN = 9.6–12.1). These distinguishing geochemical features of the D13 – phlogopite kimberlite are comparable to typical Group II kimberlites in southern Africa. However, their diagnostic incompatible trace element ratios (for example, Th/Nb, La/Nb, Ce/Pb, and Ba/Nb) are instead comparable to other kimberlite intrusions analysed in this study and to southern African Group I kimberlites in general. Semi-quantitative modelling suggests that these kimberlite intrusions could have derived by low (

Published

2021

3. Constraining carbonation freezing and petrography of the carbonated cratonic mantle with natural samples

Author

M.G. Kopylova, F. Ma, and E. Tso

Subjects

Peridotite, Incompatible element, Olivine, Geochemistry, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geochemistry and Petrology, Silicate minerals, Carbonatite, engineering, 010503 geology, Monticellite, Metasomatism, Kimberlite, 0105 earth and related environmental sciences

Abstract

Peridotite xenoliths from the Cretaceous Chidliak kimberlite province (SE Baffin Island, Canada) were recently studied by Kopylova et al. (2019) . Here, we focus on rare textures, with orthopyroxene grains invariably rimmed by 3–20 μm coronas of clinopyroxene, while all clinopyroxenes are rimmed by equally thin monticellite coronas. Thicker, 0.1–0.5 mm texturally equilibrated clinopyroxene also mantles garnet, and there is a gradual transition from micron- to millimeter-thick clinopyroxene mantles. We investigated the origin of these rarely preserved textures using major and trace element zoning in minerals, and measured and reconstructed bulk compositions of xenoliths. Fluxes of major elements were identified based on the conserved element ratios while accounting for the closure effect due to normalization of bulk compositions to 100%. Ca dominates the absolute elemental gain, expressed in moles per 1000 mol of Fe. The observed mineralogical and compositional changes are associated with the significant metasomatic removal of Na (70% of its budget) Al, and Cr (35% loss), minor removal of Si, Mn, Mg and Ni and the gain of Ca (~ 20%), Ti, K and incompatible trace elements. The metasomatic fluid addition beneath Chidliak was likely below 10%. The fluid was very enriched and fractionated resembling volatile-rich low-degree melts like carbonatites or kimberlites. The Chidliak peridotites were affected by “carbonation freezing”, i.e. immobilization of a carbonate-rich metasomatic agent via reactions with pyroxenes. Clinopyroxene and monticellite coronas formed in decarbonation reactions, whereby ephemeral carbonatitic fluid readily gave away Ca to silicate minerals and exsolved CO2. Chidliak peridotites highlight that it would be deceptive to imagine “carbonated peridotites” storing carbon in a normal assemblage of peridotite plus carbonate. “Carbonated peridotites” are coarse peridotites with elevated modes of clinopyroxene, garnet and olivine, and with thin rims of calcic silicate minerals storing incompatible elements. The CO2-rich magmatism on cratons and the match between the temporal Ca addition to the cratonic mantle and the observed fluxes from the carbonate-rich metasomatism underscores the importance of the latter process in shaping up the lithospheric mantle and its melts.

Published

2021

4. Origin and redox conditions of the Rosário-6 alnöite of southern Brazil: Implications for the state of the mantle during Gondwana breakup

Author

Tiago Luis Reis Jalowitzki, Stephan Klemme, Jasper Berndt, Larissa Colombo Carniel, and Rommulo Vieira Conceição

Subjects

Olivine, 010504 meteorology & atmospheric sciences, Subduction, Geochemistry, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), Geochemistry and Petrology, Oceanic crust, Lithosphere, engineering, Metasomatism, Monticellite, Kimberlite, 0105 earth and related environmental sciences

Abstract

The Rosario-6 alnoite is an alkaline occurrence that belongs to the Rosario do Sul kimberlitic field, situated in the south-eastern edge of the Parana Basin, in the South of Brazil, and erupted concomitant or just after the volcanism of the Parana-Etendeka Large Igneous Province (LIP). Following recent published nomenclature, Rosario-6 was classified as a kimberlite from a deep mantle source with a distinctive inequigranular texture resulting from the presence of olivine macrocrysts set in a finer-grained matrix. Trace element compositions of olivine, monticellite, spinel, phlogopite, perovskite and apatite show an enrichment of Nb, Ce, Ta and U, which implies that the Rosario-6 mantle source was enriched by recycled oceanic crust. The positive anomalies of Rb, Ba and Sr, the enrichment in LREE, and the negative anomalies of HREE in the Rosario-6 minerals, are indicative of a metasomatic process in the mantle source that could be caused by fluids from recycled oceanic crust. Temperature, pressure and redox conditions (fO2) of Rosario-6 crystallization are estimated from olivine, spinel, perovskite and monticellite compositions: Rosario-6 crystallization temperatures using olivine-spinel geothermobarometry were around 1390(±56)°C at a pressure of 2 GPa, and 1405(±56)°C at 3 GPa with ΔNNO = 2.8, at pressures constrained by the silica activity limited by the crystallization of monticellite. Using a perovskite oxybarometer, we obtained a larger range of ΔNNO (from −2.8 to 3.4), whereas the monticellite oxybarometer results in fO2 of −2.6 to −0.8 ΔNNO units. The fO2 indicate that the mantle source of Rosario-6 at the time of crystallization was possibly oxidized by materials from ancient subduction, which may be the cause for Rosario-6's low potential to carry and preserve diamonds. Horizontal tomographic images derived from P-wave velocity data constrain the thickness of the lithosphere in this region and the overall information indicates that mantle cooling at depths below 200 km may have resulted of an accumulation of oceanic plate slabs from old subduction. The geochemical data in conjunction with the geophysical characterizes the conditions of Rosario-6 mineral crystallization and also the mantle of this part of South America during Gondwana breakup.

Published

2020

5. Evolution of kimberlite magmas in the crust: A case study of groundmass and mineral-hosted inclusions in the Mark kimberlite (Lac de Gras, Canada)

Author

Kathy Ehrig, Bruce A. Kjarsgaard, Yana Fedortchouk, Karsten Goemann, Adam Abersteiner, Vadim S. Kamenetsky, and Maya B. Kamenetsky

Subjects

Olivine, Mineral, 010504 meteorology & atmospheric sciences, Geochemistry, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geochemistry and Petrology, Mineral redox buffer, engineering, Phlogopite, Fluid inclusions, Monticellite, Kimberlite, 0105 earth and related environmental sciences, Melt inclusions

Abstract

Kimberlites are the surface manifestation of deeply-derived (>150 km) and rapidly ascended magmas. Fresh kimberlite rocks are exceptionally rare, as most of them are invariably modified by pervasive deuteric and/or post-magmatic fluids that overprint the original mineralogy. In this study, we examined fresh archetypal kimberlite from the Mark pipe (Lac de Gras, Canada), which is characterised by well-preserved olivine and groundmass minerals. The sequence of crystallisation of the parental melt and its major compositional features, including oxygen fugacity, were reconstructed using textural relationships between magmatic minerals, their zoning patterns and crystal/melt/fluid inclusions. Crystal and multiphase primary, pseudosecondary and secondary melt/fluid inclusions in olivine, Cr-diopside, spinel, perovskite, phlogopite/kinoshitalite, apatite and calcite preserve a record of different stages of kimberlite melt evolution. Melt/fluid inclusions are generally more depleted in silica and more enriched in alkalis (K, Na), alkali-earth (Ba, Sr) and halogens (Cl, F) relative to the whole-rock composition of the Mark kimberlite. These melt/fluid inclusion compositions, in combination with presence of elevated CaO (up to 1.73 wt%), in Mg-rich olivine rinds, crystallisation of groundmass kinoshitalite, carbonates (calcite, Sr-Ba-bearing) and alkali-enriched rims around apatite suggest that there was progressive enrichment in CO2, alkalis and halogens in the evolving parental melt. The Mark kimberlite groundmass is characterised by the following stages of in-situ crystallisation: (1) olivine rims around xenocrystic cores + Cr-spinel/TIMAC. (2) Mg-rich olivine rinds around olivine rims/cores + MUM-spinel (followed by pleonaste and Mg-magnetite) + monticellite (+ partial resorption of olivine, along with the formation of ferropericlase and CO2 as a result of decarbonation reactions) + perovskite + apatite. (3) Olivine outmost rinds, which are coeval with phlogopite/kinoshitalite + apatite + sulphides + carbonate (calcite, Ba-Sr-Na-bearing varieties). In addition, oxygen fugacity of the Mark kimberlite was constrained by olivine-chromite, perovskite and monticellite oxygen barometry and showed that the parental melt became progressively more oxidised in response to fractional crystallisation. (4) Deuteric (i.e. late-stage magmatic) and/or post-magmatic (i.e. external fluids) alteration of magmatic minerals (e.g., olivine, monticellite, ferropericlase) and crystallisation of mesostasis serpentine, K-bearing chlorite and brucite (i.e. replacement of ferropericlase). The absence of any alkali (Na, K) and halogen (F, Cl) rich groundmass minerals in the Mark kimberlite may be attributed to these elements becoming concentrated in the late-stage melt where they potentially formed unstable, water-soluble carbonates (such as those observed in melt inclusions). Consequently, these minerals were most likely removed from the groundmass by deuteric and/or post-magmatic alteration.

Published

2020

6. A genetic story of olivine crystallisation in the Mark kimberlite (Canada) revealed by zoning and melt inclusions

Author

Bruce A. Kjarsgaard, Adam Abersteiner, Maya B. Kamenetsky, Kathy Ehrig, Thomas Rodemann, Vadim S. Kamenetsky, and Karsten Goemann

Subjects

Olivine, 010504 meteorology & atmospheric sciences, Geochemistry, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geochemistry and Petrology, Carbonatite, engineering, Phenocryst, Phlogopite, Fluid inclusions, Monticellite, Kimberlite, 0105 earth and related environmental sciences, Melt inclusions

Abstract

Elucidating the composition of primary kimberlite melts is essential to understanding the nature of their source, petrogenesis, rheology, transport and ultimately the origin of diamonds. Kimberlite rocks are typically comprised of abundant olivine (~25–60 vol%), which occurs as individual grains of variable size and morphology, and includes xenocrysts and zoned phenocrysts. Zoning patterns and inclusions in olivine can be used to decipher the petrogenetic history of kimberlites, starting from their generation in the mantle through to emplacement in the crust. This study examines well-preserved, euhedral, zoned olivine crystals from the Mark kimberlite (Lac de Gras, Canada). Olivine typically consists of xenocrystic cores, which are homogeneous in composition but vary widely between grains (Fo88.1–93.6). These cores are in turn surrounded by (in order of crystallisation) magmatic rims and Mg-rich rinds (Fo95.3–98.1). In addition, we document a new type of olivine zone (‘outmost rind’) that overgrows Mg-rich rinds. Crystal and melt/fluid inclusions are abundant in olivine and preserve a record of kimberlite melt evolution. For the first time in the studies of kimberlite olivine, we report primary melt inclusions hosted in Mg-rich olivine rinds. In addition, we observe that pseudosecondary melt/fluid inclusions are restricted to interior olivine zones (cores, rims) and are considered to have formed prior to rind formation. Pseudosecondary melt/fluid inclusions are inferred to have been entrapped at depth, as evidenced by measured densities in thermometric experiments of CO2 and decrepitation haloes, indicating a minimum entrapment pressure of ~200–450 MPa (or ~6–15 km). Both primary and pseudosecondary melt inclusions in olivine have daughter minerals dominated by Ca Mg and K-Na-Ba-Sr-bearing carbonates, K-Na-chlorides along with subordinate silicates (e.g., phlogopite, monticellite), Fe-Mg-Al-Ti-spinel, perovskite, phosphates and sulphates/sulphides and periclase. In addition to phases reported in primary melt inclusions, pseudosecondary melt inclusions contain more diverse and exotic daughter mineral assemblages, where they contain phases such as tetraferriphlogopite Ba- or K-sulphates, kalsilite and Na-phosphates. The daughter mineral assemblages are consistent with a silica-poor, alkali dolomitic carbonatite melt. We demonstrate that the different types of inclusions in olivine can assist in constraining the timing of multi-stage olivine growth and the composition of the crystallising melt. The large variance in olivine zoning patterns, morphologies and Ni distribution (i.e. both coupling with and decoupling from Fo) indicates that olivine in the studied Mark kimberlite samples represent an accumulation of olivine, where olivine was derived from successive stages of the ascending magma and/or from multiple, but related pulses of magma. Primary and pseudosecondary melt/fluid inclusions in olivine indicate that a variably differentiated silica-poor, halogen-bearing, alkali-dolomitic melt crystallised and transported olivine in the Mark kimberlite.

Published

2020

7. Fe-monticellite in serpentinites from the Happo ultramafic complex.

Author

Nozaka, Toshio

Subjects

*CHEMICAL potential, *DIOPSIDE, *OLIVINE, *PARAGENESIS, *PERIDOTITE, *ANTIGORITE, *IRON fertilizers

Abstract

The new discovery of Fe-monticellite in serpentinized peridotites of the Happo ultramafic complex, central Japan, shows it replacing olivine and coexisting with antigorite. The monticellite occurs in several forms: as discrete grains; partially disconnected rings or circular ribbons; fringing mantles or in veins cutting olivine; or as aggregates of small equant grains. It shows a textural contrast to the intensely sheared matrix of antigorite. The coexistence with antigorite and diopside, and the Fe-rich compositions of monticellite indicates that it formed at 300–350 °C. This extremely low-temperature for monticellite formation is consistent with the observed textures indicative of its static formation at a stage of serpentinization that followed mylonitization during high-temperature (400–600 °C) serpentinization in the Happo complex. The monticellite contains minute inclusions of awaruite, which indicates formation under reducing conditions, as is characteristic of serpentinization of olivine. The monticellite is richer in Fe and Mn than relict olivine, being commensurate with deficiencies of these elements in coexisting antigorite. There is no evidence of Ca addition from an external source. However, where tremolite is replaced by serpentine, diopside grows at the opposite side of relict olivine that is partly replaced by monticellite. Thus, tremolite is the likely source of Ca for monticellite formation. These textural relationships and the thermodynamic calculations for paragenesis indicate that monticellite formed by reactions between olivine and aqueous fluids, carrying Ca released from tremolite, that were driven by a local gradient of SiO 2 chemical potential during serpentinization. • Fe-monticellite occurs replacing olivine and coexisting with antigorite and diopside in serpentinized peridotites. • Textures indicate the static formation of monticellite following mylonitization of the serpentinite. • The paragenesis and Fe-rich compositions of monticellite indicate its formation at 300–350 °C. • The Fe-monticellite formed by reactions between olivine and aqueous fluids that carried Ca released from tremolite during serpentinization. [ABSTRACT FROM AUTHOR]

Published

2020

8. Tuffisitic kimberlites from the Wesselton Mine, South Africa: Mineralogical characteristics relevant to their formation

Author

E. Michael W. Skinner, Roger H. Mitchell, and Barbara H. Scott Smith

Subjects

geography, Diopside, geography.geographical_feature_category, Olivine, Geochemistry, Geology, engineering.material, Diatreme, Geochemistry and Petrology, visual_art, engineering, visual_art.visual_art_medium, Phlogopite, Phenocryst, Xenolith, Monticellite, Kimberlite

Abstract

Tuffisitic kimberlites from the Wesselton Mine consist, in order of formation, of the following primary components: chloritized olivine macrocrysts and phenocrysts; magmaclasts; cryptocrystalline diopside-phlogopite-rich mantles, and a smectite–chlorite interclast matrix. Magmaclasts consist of one to several crystals of chloritized olivine set in a microcrystalline groundmass of diopside, apatite, perovskite, spinel and chloritized and fresh phlogopite, the latter commonly rimming chloritized olivines. Magmaclasts have some similarities to holocrystalline hypabyssal kimberlite but lack monticellite, carbonate, carbonate-serpentine segregations and atoll spinels. Spinels in the magmaclasts show only a limited compositional evolution relative to spinels in spatially-associated hypabyssal kimberlite. Pre-existing solids, including discrete olivine grains, magmaclasts and most xenoliths, are mantled by acicular diopside and phlogopite. The interclast matrix is now represented by mixed layer phyllosilicates (chlorite–smectites) that are poorer in alumina and iron than chlorite pseudomorphing olivine and microlitic phlogopite and diopside. The interclast chlorite–smectite is considered to represent former phlogopite which has undergone late-stage deuteric hydrothermal-like modification. The interclast matrix crystallized from the volatile-rich remnants of the magma. None of the constituents of tuffisitic kimberlites, including the chlorite or chlorite–smectites, represent material formed from externally-derived fluids. These primary textures are unique to kimberlites and only form in certain circumstances. Tuffisitic kimberlites formed by progressive crystallization and volatile exsolution-induced segregation and/or disruption within a kimberlite magma (magmaclasts, mantles, interclast matrix) during a continuum of rapidly changing conditions in a subsurface (subvolcanic) magmatic system. This continuum represents a transition from a degassing magmatic system to a magmatic-derived hydrothermal-like fluid. Rapid drops in temperature with extensive exsolution of CO 2 and incorporation of large amounts of locally-derived country rock xenoliths resulted in explosive diatreme formation and within-diatreme modification of the crystallization and deuteric replacement sequence of typical kimberlite magma resulting in a distinctive mineralogy and texture.

Published

2009

9. How unique is the Udachnaya-East kimberlite? Comparison with kimberlites from the Slave Craton (Canada) and SW Greenland

Author

Maya B. Kamenetsky, Terrence P. Mernagh, Oded Navon, Troels F.D. Nielsen, Vadim S. Kamenetsky, and Yakov Weiss

Subjects

Calcite, Olivine, Geochemistry, Mineralogy, Geology, engineering.material, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, engineering, Phlogopite, Phenocryst, Nyerereite, Monticellite, Kimberlite, Melt inclusions

Abstract

The origin of alkali carbonates and chlorides in the groundmass of unaltered Udachnaya-East kimberlites in Siberia is still controversial. Contrary to existing dogma that the Udachnaya-East kimberlite was either contaminated by the crustal sediments or platform brines, magmatic origin of the groundmass assemblage has been proposed on the basis of melt immiscibility textures, melt inclusion studies, and strontium and neon isotope compositions. We further tested the idea of alkali- and chlorine enrichment of the kimberlite parental melt by studying olivine-hosted melt inclusions and secondary serpentine in kimberlites from the Slave Craton, Canada (Gahcho Kue, Jericho, Aaron and Leslie pipes) and southern West Greenland (Majuagaa dyke). Host olivine phenocrysts closely resemble groundmass olivine from the Udachnaya-East kimberlite in morphology, compositions (high-Fo, low-Ca), complex zoning with cores of varying shapes and compositions and rims of constant Fo. Melt inclusions in olivine consist of several translucent and opaque daughter phases and vapour bubble(s). The daughter crystals studied in unexposed inclusions by laser Raman spectroscopy and in carefully exposed inclusions by WDS-EDS are represented by Na-K chlorides, calcite, dolomite, magnesite, Ca-Na, Ca-Na-K and Ca-Mg-Ba carbonates, bradleyite Na3Mg(CO3)(PO4), K-bearing nahpoite Na2(HPO4), apatite, phlogopite and tetraferriphlogopite, unidentified sulphates, Fe sulphides, djerfisherite, pyrochlore (Na,Ca)2Nb2O6(OH,F), monticellite, Cr-spinel and Fe-Ti oxides. High abundances of Na, K (e.g., (Na+K)/Ca = 0.15-0.85) and incompatible trace elements in the melt inclusions are confirmed by LA-ICPMS analysis of individual inclusions. Heating experiments show that melting of daughter minerals starts and completes at low temperatures (~ 100oC and 600oC, respectively), further reinforcing the similarity with the Udachnaya-East kimberlite. Serpentine minerals replacing olivine in some of the studied kimberlites demonstrate elevated abundances of chlorine (up to 3-4 wt%), especially in the early generation. Despite heterogeneous distribution of chlorine such abundances are significantly higher than in the serpentine in abyssal and ophiolitic peridotites (

Published

2009

10. Can pyroxenes be liquidus minerals in the kimberlite magma?

Author

Victor V. Sharygin, Nikolai V. Sobolev, Maya B. Kamenetsky, Alexander V. Golovin, Vadim S. Kamenetsky, Nikolai P. Pokhilenko, and Alexander V. Sobolev

Subjects

Peridotite, Olivine, Trace element, Geochemistry, Geology, engineering.material, Mantle (geology), Geochemistry and Petrology, engineering, Phenocryst, Xenolith, Monticellite, Petrology, Kimberlite

Abstract

Clinopyroxene and orthopyroxene are generally rare in kimberlites, and believed to originate from disintegrated mantle and crustal xenoliths. We report occurrence of inclusions of low-Ca and high-Ca pyroxenes in the olivine phenocrysts in the Udachnaya-East hypabyssal kimberlite (Yakutia, Russia), and make inferences on their relationships to the kimberlite magma. Pyroxenes are only found as either resorbed macrocrysts or small inclusions in olivine; both types are being very rare and volumetrically insignificant. All clinopyroxene and majority of orthopyroxene inclusions are hosted in the olivine cores (Fo86-92) that are compositionally similar to olivine macrocrysts. Major and trace element compositions of clinopyroxene inclusions in olivine phenocrysts and macrocrysts are similar, and resemble compositions of clinopyroxene from lherzolite xenoliths hosted in the Udachnaya-East kimberlite. Their high Na2O and Cr2O3 abundances (0.65-2.55 and 0.6-2.8 wt%, respectively) suggest deep mantle origin (>4.5 GPa). The majority of clinopyroxene inclusions have convex-upward trace element patterns that imply kimberlite-like compositions for the hypothetical equilibrium melts. Re-equilibration of clinopyroxene inclusions with the host kimberlite liquid through micro-cracks in olivine is our preferred explanation in this case, however, we cannot exclude their high-pressure crystallisation from the protokimberlite melt. Orthopyroxene inclusions show significant compositional overlap with the low-Al orthopyroxene from the Udachnaya peridotite nodules. Where such inclusions occur in olivine fragments and contact with the kimberlite groundmass, they are strongly resorbed and partially replaced by monticellite. The mantle origin of orthopyroxene and its host olivine and disequilibrium relationships with the kimberlite melt is most likely. Both clinopyroxene and orthopyroxene are completely absent in the kimberlite groundmass. We conclude that the parental melt of the Udachnaya-East kimberlite was not saturated in either clinopyroxene or orthopyroxene at low pressure. This argues against a perceived mafic-ultramafic lineage of the kimberlite primary melt, and provides further support for its essentially carbonate-chloride composition.

Published

2009

11. Characteristics and alteration origins of matrix minerals in volcaniclastic kimberlite of the Muskox pipe (Nunavut, Canada)

Author

Raymond Alexander Fernand Cas, M Johnson, and Patrick Hayman

Subjects

Calcite, Mineral, Geochemistry, Mineralogy, Geology, engineering.material, Petrography, chemistry.chemical_compound, chemistry, Geochemistry and Petrology, Mineral alteration, engineering, Phlogopite, Monticellite, Chlorite, Kimberlite

Abstract

The matrix of volcaniclastic kimberlite (VK) from the Muskox pipe (Northern Slave Province, Nunavut, Canada) is interpreted to represent an overprint of an original clastic matrix. Muskox VK is subdivided into three different matrix mineral assemblages that reflect differences in the proportions of original primary matrix constituents, temperature of formation and nature of the altering fluids. Using whole rock X-ray fluorescence (XRF), whole rock X-ray diffraction (XRD), microprobe analyses, back-scatter electron (BSE) imaging, petrography and core logging, we find that most matrix minerals (serpentine, phlogopite, chlorite, saponite, monticellite, Fe–Ti oxides and calcite) lack either primary igneous or primary clastic textures. The mineralogy and textures are most consistent with formation through alteration overprinting of an original clastic matrix that form by retrograde reactions as the deposit cools, or, in the case of calcite, by precipitation from Ca-bearing fluids into a secondary porosity. The first mineral assemblage consists largely of serpentine, phlogopite, calcite, Fe–Ti oxides and monticellite and occurs in VK with relatively fresh framework clasts. Alteration reactions, driven by deuteric fluids derived from the juvenile constituents, promote the crystallisation of minerals that indicate relatively high temperatures of formation (> 400 °C). Lower-temperature minerals are not present because permeability was occluded before the deposit cooled to low temperatures, thus shielding the facies from further interaction with fluids. The other two matrix mineral assemblages consist largely of serpentine, phlogopite, calcite, +/− diopside, and +/− chlorite. They form in VK that contains more country rock, which may have caused the deposit to be cooler upon emplacement. Most framework components are completely altered, suggesting that larger volumes of fluids drove the alteration reactions. These fluids were likely of meteoric provenance and became heated by the volcaniclastic debris when they percolated into the VK infill. Most alteration reactions ceased at temperatures > 200 °C, as indicated by the absence or paucity of lower-temperature phases in most samples, such as saponite. Recognition that Muskox VK contains an original clastic matrix is a necessary first step for evaluating the textural configuration, which is important for reconstructing the physical processes responsible for the formation of the deposit.

Published

2009

12. Crystallisation of mela-aillikites of the Narsaq region, Gardar alkaline province, south Greenland and relationships to other aillikitic–carbonatitic associations in the province

Author

Linda A. Kirstein, J.A. Craven, and Brian G. J. Upton

Subjects

Olivine, Geochemistry, Geology, engineering.material, Igneous rock, Geochemistry and Petrology, Ultramafic rock, engineering, Carbonatite, Phlogopite, Kaersutite, Monticellite, Metasomatism

Abstract

Aillikites (carbonated, melilite-free ultramafic lamprophyres grading to carbonatites) are minor components of the Gardar alkaline igneous province. They occur principally as minor intrusions and as clasts in diatremes, but more voluminous aillikitic intrusions crop out near the Ilimaussaq Complex, which they predate by a few million years. These larger intrusions were emplaced at 1160 ± 5 Ma. They are essentially carbonate-free and, consisting almost wholly of ferromagnesian silicate and oxide minerals, are mela-aillikites. Typically the mela-aillikites are fine-grained rocks composed largely of olivine, clinopyroxene, phlogopite and magnetite that crystallised in open systems, permitting loss of volatile-rich residues. The petrography is highly complex, involving at least 28 mineral species. Pyroxenitic veins were emplaced while the host-rocks were still at high temperatures and represent channels through which fluorinated silico-carbonatitic residual melts escaped, with exsolving CO 2 as propellant. Precipitation of Ca-rich minerals including monticellite, perovskite, vesuvianite, wollastonite and cuspidine was a result of dissociation of the calcium carbonate in the residual melts. Late-stage crystallisation was in a highly oxidising environment in which the ‘common minerals’ attain extreme compositions (almost pure forsterite, ferrian-diopside, highly magnesian ilmenite, Ba–Ti-rich phlogopite and Sr-rich kaersutite). Spatially associated diatremes may be vents through which CO 2 -rich gases erupted. The whole-rock compositions are considered to be well removed from those of co-existing melts: compaction and expulsion of highly mobile residual melts is inferred to have left the mela-aillikites as aberrant cumulates. The mela-aillikites are a late-Gardar manifestation of the aillikitic magmatism that occurred intermittently in the province for over 120 Ma. Repetitive formation of metasomite vein systems in the deep lithospheric mantle is postulated. These readily fusible metasomites had short residence histories, experiencing either adiabatic melting or thermal melting as a result of plume activity. The abnormally large volumes of ultramafic lamprophyre magma, from which the mela-aillikites crystallised, may denote the culmination of metasomatic processes in the closing stages of the evolution of the Gardar Province.

Published

2006