Your search keyword '"Omphacite"' showing total 715 results

1. Simulation of microtextural evolution in omphacite: Ordering transformation kinetics as unexplored archives of slab eclogitization.

Author

Fukushima, Ryo, Tsujimori, Tatsuki, and Miyajima, Nobuyoshi

Subjects

*PRECIPITATION (Chemistry) kinetics, *CHEMICAL kinetics, *SUBDUCTION, *METAMORPHIC rocks, *RECRYSTALLIZATION (Geology)

Abstract

Earth's subduction zone processes and surface environments are intricately governed by mass transfer phenomena at plate convergent boundaries. The determination of their rates and timings from high-pressure metamorphic rocks (e.g., eclogite), or remnants of ancient convergent boundaries, remains an ongoing challenge. Here, we proposed the potential and versatility of ordering transformation kinetics of omphacite, an essential mineral found in eclogite, as a dynamic recorder of the metamorphic history. Through macroscopic phase-field simulation, we explored the growth of antiphase domains (APDs) in metastable disordered omphacite, discussing the feasibility of constraining metamorphic reaction kinetics based on the size and morphology of omphacite APDs in eclogitized oceanic crust. Our simulation corroborated that omphacite nucleating later during the prograde metamorphism can exhibit an incompletely ordered state with sparsely distributed ordered domains, which suggests their usefulness in estimating the recrystallization timing of the omphacite. Additionally, we confirmed that the APD formation dynamics are significantly influenced by the initial cation configuration of the disordered matrix. This implies the APD morphology in natural omphacite under slab-surface conditions may reflect their precipitation kinetics. These findings provide valuable insights into the microtextural evolution of omphacite due to its ordering transformation, thereby enhancing our ability to interpret morphological features. [Display omitted] • The growth of antiphase domains in omphacite was explored with phase-field modeling. • Incompletely ordered omphacite may allow to resolve short-span geological events. • The morphology of ordered domains should reflect the recrystallization kinetics. [ABSTRACT FROM AUTHOR]

Published

2024

2. Electrical Conductivity of Eclogitic Omphacite and Garnet at Water-Rich Conditions

Author

Hanyong Liu and Xiaozhi Yang

Subjects

water, electrical conductivity, omphacite, garnet, eclogite, crust subduction, Science

Abstract

Electrical conductivity of water-rich omphacite and garnet in eclogite was measured at 1 GPa and 200–800°C in a piston cylinder press and by a Solartron-1260 impedance/gain-phase analyzer at 106-1 Hz frequency. The water content of pre-annealed omphacite and garnet was 775–2,000 and 705–1,460 ppm H2O, respectively. Sample chemistry and water contents remained unchanged during conductivity runs. At otherwise identical conditions, the conductivity of both minerals increases with both temperature and water content, and the water content exponent is ∼1.45 and 1.12 for omphacite and garnet, respectively. The activation enthalpy is ∼70 kJ/mol for omphacite and 84 kJ/mol for garnet and is broadly independent of sample water content. Combining with previous work, the conductivity dependence of omphacite on water content differs between water-rich and water-poor conditions, due to different types and mobility of water in samples that are closely related to its incorporation mechanism; in contrast, the conductivity dependence of garnet with a similar type of water is comparable over a wide range of water contents. The estimated bulk conductivity of eclogite at water-rich conditions is very high, up to ∼0.01–0.1 S/m at 600–900°C. Geophysically resolved high resistivity of subducting crusts at 70–120 km depth suggests extremely low water contents of omphacite and garnet in the eclogitized slab. The data provide support to the model based on omphacite and garnet conductivity at water-poor conditions that the amount of water recycled by crust subduction to the deep mantle is probably limited.

Published

2022

3. H2O in omphacite of quartz and coesite eclogite from Erzgebirge and Fichtelgebirge, Germany.

Author

Gose, Jürgen and Schmädicke, Esther

Subjects

*ECLOGITE, *QUARTZ, *DEHYDRATION reactions, *TRACE elements, *AMPHIBOLES, *SUBDUCTION

Abstract

Major and trace elements in omphacite, including hydrogen, were determined in eclogites from two Variscan basement complexes in Germany: Erzgebirge (EG) and Fichtelgebirge (FG). Erzgebirge eclogite is derived from three units, showing different peak pressure (P) and temperature (T) conditions (Unit 1: 840–920°C/≥30 kbar, Unit 2: 670–730°C/24–26 kbar, Unit 3: 600–650°C/20–22 kbar). The peak conditions of FG eclogite (690–750°C/25–28 kbar) resemble those of EG Unit 2. Coesite eclogite occurs in EG Unit 1, and quartz eclogite in all other units. Omphacite from all samples shows four infrared (IR) absorption bands. Two prominent, sharp bands occur at 3,455 ± 10 cm−1 (band II) and 3,522 ± 10 cm−1 (band III). Band II is usually more prominent than band III, except for few samples with low jadeite content. A further, broad band is centred between 3,270 and 3,370 cm−1 (band I) and a fourth, minor band at 3,611–3,635 cm−1 (band IV). Bands II and III are due to hydrogen bound as structural OH− ions in omphacite. In most cases, this also applies to band IV. However, some spectra with extremely large type IV bands reflect phengite inclusions. The ambiguous band I may be due to different H2O species (molecular water, structural OH, and water in phengite). Omphacite of quartz eclogite has lower contents of TiO2, Zr, Hf, and REE, compared with that from coesite eclogite. By contrast, omphacite in quartz eclogite from both EG (H2O sample averages: 465–852 ppm) and FG (546–1,089 ppm) contains the same amount of structural OH (concentrations given in wt.‐ppm H2O) as omphacite in coesite eclogite (492–1,140 ppm). The obtained difference in the garnet‐omphacite H2O partition coefficient between quartz (0.01–0.03) and coesite eclogite (0.08–0.11) results from different H2O contents in garnet (coesite eclogite: 50–150 ppm; quartz eclogite: <2–50 ppm; Gose & Schmädicke, 2018). The total content of structural OH in omphacite is unrelated to its major and trace element composition. However, treating the individual IR bands separately, a relation between OH and mineral composition is observed. The OH amount defined by band II is positively correlated to Ti and tetrahedral Al, and that of band III shows a positive correlation with Ca and a negative one with Na (and jadeite). Both the total OH content of omphacite and the partial contents deduced from individual IR bands are unrelated to PT conditions. This implies that omphacite incorporated its structural H2O mainly in the quartz stability field, presumably during initial omphacite growth. Conversely, most OH in garnet was derived from the final breakdown of the last remaining calcic amphibole close to or within the coesite stability field. Our data suggest that coesite eclogite is able to transport a significant amount of H2O (average 550 ppm, maximum 730 ppm), corresponding to that in 3–4 vol.% calcic amphibole, via subduction to depths beyond 100 km. However, the majority of water liberated by dehydration reactions during subduction, including the breakdown of 5–10 vol.% eclogite facies and >10 vol.% pre‐eclogitic hydrous minerals, is not preserved in eclogite but liberated to the mantle wedge. [ABSTRACT FROM AUTHOR]

Published

2022

4. Discovery of eclogites in Jinsha River suture zone, Gonjo County, eastern Tibet and its restriction on Paleo-Tethyan evolution

Author

Yuan Tang, Ya-dong Qin, Xiao-dong Gong, Yao-yao Duan, Gang Chen, Hong-you Yao, Jun-xiong Liao, Shi-yong Liao, Dong-bing Wang, and Bao-di Wang

Subjects

Eclogite, Omphacite, Jinsha River suture zone, Geological survey engineering, Qinghai-Tibet plateau, Eastern Tibet, Engineering (General). Civil engineering (General), TA1-2040, Geology, QE1-996.5

Abstract

ABSTRACT: As the important component of the eastern Tethys tectonic region, the Jinsha River-Ailao Mountain suture zone is often considered to be an ophiolitic mélange belt. However, the P-T-t path and chronological framework of the metamorphic evolution in the collisional orogenetic process of this zone are still poorly understood owing to the lack of metamorphism research of symbolic high-pressure rocks. During a regional geological survey on a scale of 1 : 50000 in Gonjo County, Tibet Autonomous Region involved in this paper, (retrograde) eclogites lenses of different scales were found in Jinsha River suture zone, eastern Tibet for the first time. The (retrograde) eclogites can be divided into garnet-albite-chlorite-actinolite schists and eclogites according to retrograde degrees. The mainly mineral components of eclogites include garnet (45%–50%), clinopyroxene (about 25%), and hornblende (5%–10%) primarily, and biotite, quartz, rutile, and muscovite secondarily. According to the data of electron probe micro analysis (EPMA), clinopyroxenes feature high content of Na2O (5.6%–6%) and corresponding jadeite (Jd) molecules of 37%–44%, and they fall within the omphacite region in Quad-Jd-Ae diagram. The temperature and pressure of the metamorphism at peak are P≈2.2–2.34 GPa and T≈622–688 °C respectively as measured with geobarometry Grt-Omp-Phe and geothermometer Grt-Omp. This will provide a new reference for the understanding of Paleo-Tethyan evolution. In this paper, two samples of eclogites were chosen for LA-ICP-MS zircon U-Pb dating and their 206Pb/238U ages obtained are 240 ± 3 Ma and 244 ± 1 Ma respectively. Furthermore, the zircons feature extremely low Th/U ratio (

Published

2020

5. Various antiphase domains in garnet-hosted omphacite in low-temperature eclogite: A FIB-TEM study on heterogeneous ordering processes.

Author

RYO FUKUSHIMA, TATSUKI TSUJIMORI1, and NOBUYOSHI MIYAJIMA

Subjects

*GARNET, *ECLOGITE, *FOCUSED ion beams, *ORDER picking systems, *TRANSMISSION electron microscopes, *THERMODYNAMIC equilibrium

Abstract

Low-temperature omphacite has peculiar microstructures called "antiphase domains (APDs)," which can be formed via phase transition from disordered C2/c to ordered P2/n structure during cooling. Hence morphological analyses of the APDs of undeformed omphacite have a potential to unravel the temperature-time (T-t) histories of the eclogite. We investigated five omphacite inclusions in a euhedral garnet porphyroblast obtained from low-temperature eclogite in Syros. The garnet (~6 µm in size) exhibits a distinct prograde chemical zoning and contains abundant mineral inclusions. Transmission electron microscope (TEM) observations of the focused ion beam (FIB) foils confirmed a heterogeneous distribution of equiaxed APDs (10-280 nm in diameter) and columnar APDs. Size distributions of the equiaxed APDs are characterized by kurtosis values of -0.45-3.91, which are larger than those in the matrix omphacite. The columnar APDs are subdivided into two types: dislocation-related (Type I) and inclusion-host interfacial (Type II). The presence of Type I APDs may suggest the inclusions were deformed prior to the host garnet growth. In contrast, Type II APDs, which are characterized by a bundle of stripe-like APDs (~40 nm in width) aligned perpendicular to the host garnet, imply the simultaneous growth of omphacite and garnet in a non-deformation state. The presence of these two contrasting APDs of omphacite inclusions in the single prograde-zoned garnet prevents a simple application of geospeedometry based on APD sizes. Nevertheless, our observations demonstrate that APDs are keys to understanding thermodynamic equilibrium states and the mineral growth kinetics during eclogitization. [ABSTRACT FROM AUTHOR]

Published

2021

6. Seismic Visibility of Eclogite in the Earth's Upper Mantle—Implications From High Pressure‐Temperature Single‐Crystal Elastic Properties of Omphacite.

Author

Hao, Ming, Zhang, Jin S., Zhou, Wen‐Yi, and Wang, Qin

Subjects

*ECLOGITE, *SEISMIC anisotropy, *ELASTICITY, *SEISMIC wave velocity, *SUBDUCTION

Abstract

Identifying and locating the geochemical and geophysical heterogeneities in the Earth's interior is one of the most important and challenging tasks for the deep Earth scientists. Subducted oceanic crust metamorphizes into the dense eclogite in the upper mantle and is considered as a major cause of geochemical and geophysical heterogeneities in the deep Earth. In order to detect eclogitic materials inside the Earth, precise measurements of the high pressure‐temperature single‐crystal elasticity of major minerals in eclogite are thus exceedingly important. Omphacite, a Na,Al‐bearing clinopyroxene, constitutes up to 75 vol% of eclogite. In the present study, we performed the first high pressure‐temperature single‐crystal elasticity measurements of omphacite using Brillouin spectroscopy. Utilizing the finite‐strain approach, we obtained the following thermoelastic parameters for omphacite: KS0' = 4.5(1), G0' = 1.53(5), ∂KS0/∂T = −0.029(5) GPa/K, ∂G0/∂T = −0.013(5) GPa/K, with KS0 = 123(3) GPa, G0 = 74(2) GPa, and ρ0 = 3.34(1) g/cm3. We found that the seismic velocities of undeformed eclogite are similar to pyrolite at the depths of 200–300 and 410–500 km, thus eclogite is seismically invisible at these depths. Combined with the lattice‐preferred orientations of the omphacite in naturally deformed eclogites, we also modeled seismic anisotropy of eclogite at various pressure‐temperature conditions. A 10 km thick subducted eclogitic crust can result in ∼0.2 s shear wave splitting in the Earth's upper mantle. Plain Language Summary: Omphacite, as a type of clinopyroxene, is one of the main mineral phases in the deeply sinking basaltic materials recycled to the deep Earth. To better constrain seismic properties of the subducted oceanic crust, we experimentally measured elastic properties of omphacite under high pressure‐temperature conditions. Using our results, the calculated seismic anisotropy of deformed basaltic oceanic crust is on the level of 4%–5% in the uppermost mantle. If the subducted basaltic materials remained undeformed, their isotropic seismic velocities are identical to the ambient mantle at depths between 200–300 and 410–500 km. Key Points: Single‐crystal elastic properties of omphacite were measured for the first time at high P‐T conditionsUndeformed eclogite is seismically invisible at 210–300 and 400–500 km depth rangeModeled seismic anisotropy of deformed eclogite can be as high as 4%–5% in the uppermost mantle [ABSTRACT FROM AUTHOR]

Published

2021

7. Reply to Skublov et al. Comment on 'Volodichev et al. Archean Zircons with Omphacite Inclusions from Eclogites of the Belomorian Province, Fennoscandian Shield: The First Finding. Minerals 2021, 11, 1029'

Author

Oleg I. Volodichev, Oleg A. Maksimov, Tatiana I. Kuzenko, and Alexander I. Slabunov

Subjects

Archean, eclogite, zircon, omphacite, geochronology, geochemistry, Mineralogy, QE351-399.2

Abstract

Early Precambrian retrogressed eclogites are abundant in the Archean Belomorian Province of the Fennoscandian Shield. Archean zircons with inclusions of omphacite have been found in these eclogites. Similar Archean zircons from the retrogressed eclogites also contain garnet inclusions. The Archean zircons display no negative Eu anomaly, which indicates their crystallization in plagioclase-free rock. Garnet, omphacite and clinopyroxene-plagioclase symplectite as a proxy of omphacite compose ≥75% of the studied rocks, with garnet and omphacite being major constituents and associating with rutile and quartz. These data strongly suggest that the studied rock is eclogite. In the majority of petrogenetic grids, P-T parameters calculated for these rocks fall in the eclogite-facies field. Thus, these findings and data provide evidence that eclogite-facies metamorphism occurred in the Neoarchean.

Published

2022

8. Comment on Volodichev et al. Archean Zircons with Omphacite Inclusions from Eclogites of the Belomorian Province, Fennoscandian Shield: The First Finding. Minerals 2021, 11, 1029

Author

Sergey G. Skublov, Aleksey V. Berezin, and Laysan I. Salimgaraeva

Subjects

eclogite, zircon, omphacite, geochronology, geochemistry, mineral inclusion, Mineralogy, QE351-399.2

Abstract

Volodichev et al. (Volodichev et al., 2021) reported on the first finding of omphacite (23%–25% Jd) inclusions in 2.68 Ga metamorphic zircons from Gridino eclogites and presented it as evidence for Archean eclogite-facies metamorphism in the Belomorian Mobile Belt. We believe that the Archean age of the garnets referred to by the above authors was estimated incorrectly. Our interpretation is that omphacite origin is related to Archean high-pressure granulite-facies metamorphism.

Published

2022

9. Microstructures and Phase Transition in Omphacite: Constraints on the P-T Path of Shuanghe Eclogite (Dabie Orogen).

Author

Xie, Zhanjun, Liu, Xiangwen, Jin, Zhenmin, and Li, Zhuoyue

Subjects

*ECLOGITE, *GARNET, *PHASE transitions, *TRANSMISSION electron microscopy, *SPACE groups

Abstract

Omphacite microstructures are important to decipher the metamorphic pressuretemperature (P-T) conditions of eclogite during subduction and exhumation processes. Here we present a systematic microstructural investigation of omphacite using transmission electron microscopy (TEM) in an ultrahigh-pressure (UHP) eclogite sample from Shuanghe, Dabie orogen, China. The omphacite can be divided into two phases: (1) Omp-1, exhibits as the main part of omphacite with P2/n space group containing small amount of dislocations and numerous antiphase domains (APDs). (2) Omp-2, shows as banded subgrains with C2/c space group containing large amount of dislocations. These two phases of omphacite have almost the same crystallography orientation and bounded by dislocation walls. Along these dislocation walls, we found some barroisite and albite microcrystals. The barroisite microcrystals contain large amount of dislocations and show a topological relation with host omphacite. While the albite microcrystals contain small amount of dislocations and does not show topological relation with host. These microstructures could give us the following metamorphic information to constrain the P-T path of eclogite: Firstly, this two omphacite space groups should be evolved from the same precursor C2/c omphacite, which had been underwent strongly plastic deformation during the syn- to late-peak metamorphic stage. Secondly, the precursor C2/c omphacite began to be retrograded and altered by small amount of barroisite microcrystals along its dislocation walls under the P-T condition of 2.2–2.6 GPa and 650–700 °C at the early amphibole eclogite stage. Thirdly, large amount of Na and other elements were exsolved from some precursor C2/c omphacite subgrains and crystallized numerous albite microcrystals at their boundaries, which is the necessary for the space group of C2/c surviving under the lower P-T conditions (1.7–1.9 GPa and 630–690 C) during the middle amphibole eclogite stage. Lastly, the rest of precursor C2/c omphacite subgrains were transformed into P2/n polymorph and formed the APDs structures under the P-T condition of ~1.5 GPa and 650–680 °C during the late amphibole eclogite stage. [ABSTRACT FROM AUTHOR]

Published

2020

10. Archean Zircons with Omphacite Inclusions from Eclogites of the Belomorian Province, Fennoscandian Shield: The First Finding

Author

Oleg I. Volodichev, Oleg A. Maksimov, Tatiana I. Kuzenko, and Alexander I. Slabunov

Subjects

Archean, eclogite, zircon, omphacite, geochronology, geochemistry, Mineralogy, QE351-399.2

Abstract

Early Precambrian retrogressed eclogites are abundant in the central and northern parts of the Belomorian Province of the Fennoscandian Shield (Gridino + Keret and Salma + Kuru-Vaara study areas, respectively). Older and younger eclogites are recognized and their Archean and Paleoproterozoic ages are argued. Archean eclogites are intensely retrogressed and occur in amphibolite boudins in the tonalite-trondhjemite-granodiorite (TTG) gneiss matrix of the Archean Gridino eclogite-bearing mélange. Less retrogressed Paleoproterozoic eclogites form patches in mafic dikes and some amphibolite boudins; their Paleoproterozoic age is supported by U-Pb/SIMS data on zircons depleted in heavy rare earth elements (REE) with omphacite, garnet, and kyanite inclusions, and Sm-Nd and Lu-Hf mineral isochrons. Archean eclogites contain Archean heavy rare-earth elements (REE)-depleted zircons with garnet and zoisite inclusions and Archean garnets. No omphacite inclusions were found in these zircons, and this fact was considered as evidence against the existence of Archean eclogites. This study reports on the first finding of omphacite (23–25% Jd) inclusions in 2.68 Ga metamorphic zircons from eclogites from the Gridino eclogite-bearing mélange. The zircons are poorly enriched in heavy REE and display a weak negative Eu-anomaly but a poor positive Ce-anomaly typical of eclogitic zircons. Thus, zircons with these decisive features provide evidence for an Archean eclogite-facies metamorphism.

Published

2021

11. High‐Pressure Single‐Crystal Elasticity and Thermal Equation of State of Omphacite and Their Implications for the Seismic Properties of Eclogite in the Earth's Interior.

Author

Hao, Ming, Zhang, Jin S., Pierotti, Caroline E., Ren, Zhiyuan, and Zhang, D.

Subjects

*HIGH pressure geosciences, *INTERNAL structure of the Earth, *ELASTICITY, *ECLOGITE, *CRYSTALS, THERMAL properties of solids

Abstract

Omphacite is a major mineral phase of eclogite, which provides the main driving force for the slab subduction into the Earth's interior. We have measured the single‐crystal elastic moduli of omphacite at high pressures for the first time up to 18 GPa at ambient temperature using Brillouin spectroscopy. A least squares fit of the velocity‐pressure data to the third‐order finite strain equation of state yields KS0′ = 4.5 (3), G0′ = 1.6 (1) with ρ0 = 3.34 (1) g/cm3, KS0 = 123 (3) GPa, and G0 = 74 (2) GPa. In addition, the synchrotron single‐crystal X‐ray diffraction data have been collected up to 18 GPa and 700 K. The fitting to Holland‐Powell thermal‐pressure equation of state yields KT0′ = 4.6 (5) and α0 = 2.7 (8) × 10−5 K−1. Based on the obtained thermoelastic parameters of omphacite, the anisotropic seismic velocities of eclogite are modeled and compared with pyrolite between 200 and 500 km. The largest contrast between the eclogite and pyrolite in terms of seismic properties is observed between ~310 and 410 km. Key Points: Thermal equation of state and single‐crystal elasticity measurements is performed on omphacite crystalsWith the newly obtained thermoelastic parameters of omphacite, anisotropic seismic properties of eclogite are modeledThe maximum Vp, Vs, and anisotropy contrast between pyrolite and eclogite is between 310 and 410 km [ABSTRACT FROM AUTHOR]

Published

2019

12. Solidus of carbonated phlogopite eclogite at 3–6 GPa: Implications for mantle metasomatism and ultra-high pressure metamorphism

Author

Altyna Bekhtenova, Ivan V. Podborodnikov, Anton Shatskiy, Konstantin D. Litasov, Yulia Vinogradova, and Anton V. Arefiev

Subjects

Grossular, Geochemistry, Partial melting, Geology, Solidus, engineering.material, Pyrope, Ultra-high-pressure metamorphism, visual_art, engineering, visual_art.visual_art_medium, Phlogopite, Omphacite, Eclogite

Abstract

The interaction of natural eclogite (Ecl) with synthetic hydrous carbonate melts with Na:K = 0:1 (KH2) and 1:1 (NKH2) was studied in multianvil experiments at 3-6 GPa and 850-1250 °C. The interaction with KH2 consumes garnet and clinopyroxene producing phlogopite and calcite-dolomite solid solution. Besides, the interaction yields a decrease in the jadeite component of clinopyroxene, evolving eclogite toward pyroxenite. This is consistent with a metasomatic alteration of eclogite xenoliths, manifested as Na-poor “spongy” clinopyroxene, replacing primary omphacite, and kelyphitic rims around garnet, containing phlogopite and carbonates. The interaction with NKH2 also produces phlogopite and carbonate, but the latter is more magnesian and represented by magnesite, above the solidus, and magnesite + dolomite below the solidus. The interaction with NKH2 increases the jadeite component in clinopyroxene and grossular component in garnet, evolving eclogite Group A to eclogite Group B. The studied systems have H2O/K2O = 2, like that in phlogopite, and therefore correspond to carbonated phlogopite eclogite under fluid-absent conditions. Based on the obtained results its solidus is situated near 1050 °C at 3 GPa and decreases to 950 °C at 6 GPa. Thus, hydrous K- and Na-K-carbonatite melts can coexist with eclogite in SCLM at depths exceeding 120-170 km, and solidify as temperature decreases below 950-1050 °C according to the following solidus reactions: pyrope + diopside + melt → phlogopite + dolomite, below 6 GPa, and pyrope + diopside + melt → phlogopite + magnesite + grossular, at 6 GPa. The melting reaction, involving phlogopite and dolomite, suggests the partial melting at the peak of ultrahigh-pressure metamorphism (UHPM) during continent-continent plate collision. The prograde P-T path of UHPM crosses the solidus of clinopyroxene + garnet + phlogopite + dolomite assemblage at 4.7-5.2 GPa and 970-990 °C and yields the formation of hydrous K-carbonatite melt-fluid in situ. This melt could be responsible for the formation of K-bearing clinopyroxenes and microdiamonds in the UHPM marbles in the Kokchetav massif, Kazakhstan. The retrograde P-T path intersects the solidus that has a negative Clapeyron slope in the diamond stability field. Thus, the hydrous K-carbonatite melt should disappear soon after the peak of metamorphism reacting with garnet to produce Ca-Mg carbonates and phlogopite.

Published

2022

13. Microfabrics of omphacite and garnet in eclogite from the Lanterman Range, northern Victoria Land, Antarctica.

Author

Kim, Daeyeong, Kim, Taehwan, Lee, Jeongmin, Kim, Yoonsup, Kim, Hyeoncheol, and Lee, Jong Ik

Subjects

*MICROFABRICATION, *GARNET, *SEISMIC anisotropy, *CRYSTALS, *ANISOTROPY

Abstract

We examined the microfabrics of omphacite and garnet in foliated eclogite to determine the influence of the layered structure on seismic observations in subduction zone. The analyzed eclogite, from the Lanterman Range, northern Victoria Land, Antarctica, is characterized by layering in which the modal abundances of garnet and omphacite vary. For garnet, the low aspect ratios, similar angular distribution of long axes relative to the foliation in both layers, uniform grain size distribution, near-random crystallographic preferred orientations (CPOs), and misorientation angle distributions are indicative of passive behavior during deformation. In contrast, omphacite shows relatively high aspect ratios, a low angle between the long axes of crystals and the foliation, a wide grain-size distribution, and distinctive CPOs, suggesting dislocation creep as the main deformation mechanism. The results of fabric analyses are consistent with strain localization into omphacite or omphacite-rich layers rather than garnet or garnet- rich layers. The single-crystal seismic anisotropy of garnet is very weak (AVP = 0.2%, AVS = 0.5-0.6%), whereas that of omphacite is much stronger (AVP = 3.7-5.9% and AVS = 2.9-3.8%). Seismic anisotropy of the omphacite-rich layers shows an increase of 329% for AVP and 146% for AVS relative to the garnet-rich layers. Our results demonstrate the importance of the layered structure in strain localization and in the development of the seismic anisotropies of subducting oceanic crust. [ABSTRACT FROM AUTHOR]

Published

2018

14. Omphacite breakdown, symplectite formation and carbonate metasomatism in a retrograded continental eclogite: Implications for the exhumation of the Tso Morari Crystalline Complex (Trans-Himalaya, NW India).

Author

Dey, Alosree, Sen, Koushik, Sen, Aranya, and Choudhary, Shubham

Subjects

*METASOMATISM, *ECLOGITE, *PETROLOGY, *PLAGIOCLASE, *RAMAN spectroscopy, *CARBONATES

Abstract

The India-Eurasia collision zone in eastern Ladakh, India, is marked by the Tso Morari Crystalline Complex (TMCC), which underwent continental subduction, eclogite grade metamorphism, and rapid exhumation during the Himalayan orogeny. The TMCC is characterized by eclogitic enclaves, metamorphic evolution of which has been extensively studied in the past. Detailed petrography, mineral chemistry, Raman spectroscopy, and P-T-X pseudosection modelling of two such eclogite samples from the core and western margin of TMCC were carried out to address the differences and discrepancies from previous studies. Our study suggests peak metamorphism at ∼2.75 ± 0.1 GPa and ∼550 ± 50 °C, followed by a decompression stage at ∼1.50 ± 0.1 GPa and ∼580 ± 50 °C and subsequent high-temperature overprint at ∼0.85 ± 0.1 GPa and ∼680 ± 50 °C. Fine-grained grain boundary omphacite + garnet + amphibole symplectite colonies indicate exhumation along with fluid infiltration. The transition of omphacite into a more calcic variety and its subsequent replacement with amphibole are also observed. Presence of diopside + plagioclase symplectite indicates post-peak decompression and fluid infiltration. Carbonates in the matrix as veins and within fractures indicate late-stage fluid infiltration and metasomatism. Our study shows that lawsonite and/or Na-amphibole have not played any significant role in the metamorphic evolution of TMCC. In contrast to most of the previous studies carried out in TMCC, we opine that omphacite breakdown and metasomatism through externally derived carbonaceous fluids played a vital role in the exhumation and retrogression. We further opine that our mineral chemistry data and metamorphic modelling resemble a continental eclogite and mark differences from oceanic eclogites. • Mineral chemistry, Raman spectroscopy and P-T pseudosection modelling of Tso Morari eclogite of trans-Himalaya carried out. • Tso Morari eclogite are of continental subduction setting with no role of lawsonite or Na-amphibole in its evolution. • Exhumation is characterized by omphacite breakdown, Na-Ca amphibole to Ca-amphibole transition and symplectite formation. • Majority of Carbonates of Tso Morari eclogite are metasomatic formed by fluid infiltration from Zildat Ophiolitic Mélange. [ABSTRACT FROM AUTHOR]

Published

2023

15. Water in omphacite fingerprints the thermal history of eclogites

Author

Xiaozhi Yang, Henrik Skogby, Peilin Jiang, Ren-Xu Chen, and Hanyong Liu

Subjects

Thermal, Geochemistry, engineering, Geology, Omphacite, engineering.material, Eclogite

Abstract

Omphacite is a diagnostic mineral of high- and ultrahigh-pressure rocks, and its association with garnet is characteristic of eclogites from subduction-related massifs and volcano-entrained xenoliths. Omphacite can accommodate significant amounts of water as structurally bound hydroxyl (OH) groups, and is able to convey water into Earth's interior. We show, for the first time, experimental evidence that the infrared absorption patterns of water in omphacite are temperature sensitive. This provides a new framework for discriminating water in natural omphacite equilibrated at different temperatures. We also demonstrate that in low-temperature omphacite, the integral absorbance ratio between the infrared OH absorption bands at 3620 cm−1 and 3450 cm−1 is linearly related to temperature. Water in omphacite of massif eclogites records the temperature of OH equilibrium, allowing reconstruction of the fluid-involved thermal history and tectonics of rock evolution.

Published

2021

16. Comment on 'Petrology, geochemistry and Sm-Nd systematics of the Paleoproterozoic Itaguara retroeclogite from Sao Francisco/Congo Craton: One of the oldest records of the modern-style plate tectonics'

Author

Kathryn Cutts

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Schist, Geochemistry, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Phengite, Petrography, Gondwana, Craton, engineering, Omphacite, Eclogite, Petrology, Metamorphic facies, 0105 earth and related environmental sciences

Abstract

The recent paper by Chaves and Porcher published in Gondwana Research (2020, v.87, 224–237) asserts the presence of 2.2 Ga eclogite facies rocks in the Itaguara Sequence, Sao Francisco craton (SFC), Brazil. They present images in which the diagnostic high-pressure minerals either occur on cracks (rutile), or as fragmentary matrix grains with unclear mineral relationships (omphacite and phengite). Here I discuss the sample petrology in order to identify the equilibrium assemblage, and utilise a P-T phase modelling approach, integrating the major mineral compositions, to show that these rocks are not retrogressed eclogites. The modelling presented here indicates that peak conditions were likely in the amphibolite facies, reaching maximum pressures of no more than 8 kbar and peak temperatures of ca. 700 °C (at 5 kbar). This result is consistent with that found by Massonne (2020, JSAMES, v.99, 102495) who suggested that mica schists from Itaguara reached maximum pressures of 13–14 kbar, and possibly lower than 10 kbar at 600 °C (i.e. within the medium to high-pressure amphibolite facies). This work shows that declarations of eclogite facies conditions, particularly from Paleoproterozoic terrains, should be accompanied by carefully evaluated petrography and thermodynamic investigations based on minerals (or mineral replacement textures) that indicate equilibrium relationships.

Published

2021

17. Various antiphase domains in garnet-hosted omphacite in low-temperature eclogite: A FIB-TEM study on heterogeneous ordering processes

Author

Tatsuki Tsujimori, Ryo Fukushima, and Nobuyoshi Miyajima

Subjects

Geophysics, Geochemistry and Petrology, engineering, Omphacite, engineering.material, Eclogite, Petrology, Geology

Abstract

Low-temperature omphacite has peculiar microstructures called “antiphase domains (APDs),” which can be formed via phase transition from disordered C2/c to ordered P2/n structure during cooling. Hence morphological analyses of the APDs of undeformed omphacite have a potential to unravel the temperature-time (T-t) histories of the eclogite. We investigated five omphacite inclusions in a euhedral garnet porphyroblast obtained from low-temperature eclogite in Syros. The garnet (~6 mm in size) exhibits a distinct prograde chemical zoning and contains abundant mineral inclusions. Transmission electron microscope (TEM) observations of the focused ion beam (FIB) foils confirmed a heterogeneous distribution of equiaxed APDs (10–280 nm in diameter) and columnar APDs. Size distributions of the equiaxed APDs are characterized by kurtosis values of –0.45–3.91, which are larger than those in the matrix omphacite. The columnar APDs are subdivided into two types: dislocation-related (Type I) and inclusion–host interfacial (Type II). The presence of Type I APDs may suggest the inclusions were deformed prior to the host garnet growth. In contrast, Type II APDs, which are characterized by a bundle of stripe-like APDs (~40 nm in width) aligned perpendicular to the host garnet, imply the simultaneous growth of omphacite and garnet in a non-deformation state. The presence of these two contrasting APDs of omphacite inclusions in the single prograde-zoned garnet prevents a simple application of geospeedometry based on APD sizes. Nevertheless, our observations demonstrate that APDs are keys to understanding thermodynamic equilibrium states and the mineral growth kinetics during eclogitization.

Published

2021

18. COMMENTS ON THE ARTICLE AUTHORED BY M.V. MINTS AND K.A. DOKUKINA – THE BELOMORIAN ECLOGITE PROVINCE (EASTERN FENNOSCANDIAN SHIELD, RUSSIA): MESO-NEOARCHEAN OR LATE PALEOPROTEROZOIC?

Author

S. G. Skublov, A. V. Berezin, and L. I. Salimgaraeva

Subjects

white sea mobile belt, Science, Archean, Geochemistry, Metamorphism, zircon, engineering.material, isotope age, lu-hf method, petrochronology, Precambrian, sm-nd method, Geophysics, eclogite, precambrian, engineering, Paragenesis, u-pb method, Omphacite, Eclogite, Protolith, Geology, Earth-Surface Processes, Zircon

Abstract

The comments are given on the article authored by M.V. Mints and K.A. Dokukina – The Belomorian Eclogite Province (Eastern Fennoscandian Shield, Russia): Meso-Neoarchean or Late Paleoproterozoic? (Geodynamics & Tectonophysics 2020, 11 (1), 151–200). The Belomorian (White Sea) province of the Fennoscandia Shield is a key site for studying the tectonics of the early periods because numerous Precambrian eclogites have been found there. It was not anticipated, but the problem of age determinations of the eclogite metamorphism of gabbroids in the White Sea mobile belt has turned out to be extremely relevant not only for this region, but also for the Precambrian geology in general. The reason is that a number of authors determine the age of eclogites as Archean (2.7–2.8 Ga), which makes the White Sea mobile belt the only example of the Archean eclogite metamorphism in the world and, therefore, the only dated evidence in support of the plate tectonic model of the evolution of the Earth’s crust at the earliest stage of its formation. The article consistently provides a critical analysis of the arguments put forward by the supporters of the Archean age of the eclogites of the White Sea mobile belt. Special emphasis is made on the isotope geochronological and geochemical features of the composition of zircons from eclogite samples, as well as on the phase and chemical compositions and distribution patterns of mineral inclusions. Considering the age of eclogite metamorphism that led to the formation of eclogites in the White Sea mobile belt, we propose our interpretation based on a set of independent isotope geochemical dating methods, including the local U- Pb method for heterogeneous zircons with magmatic cores and eclogite rims, the Lu-Hf and Sm-Nd methods for the minerals of eclogite paragenesis (garnet and omphacite). And this age interpretation is fundamentally different from the one described in the commented article: all the three methods independently determine the eclogite metamorphism as Paleoproterozoic and yield the same age of circa 1.9 Ga. According to our data, the eclogites of the White Sea mobile belt are among the most ancient high-pressure rocks, their reliably established age of metamorphism is circa 1.9 Ga, and the age of the magmatic protolith is the range of 2.2–2.9 Ga.

Published

2021

19. Metamorphism and geochronology of high-pressure mafic granulites (retrograded eclogites?) in East Cathaysia terrane of South China: Implications for Mesozoic tectonic evolution

Author

Changqing Yin, Yanfei Xia, Shangjing Wu, Jian Zhang, Jiahui Qian, Shoufa Lin, and Jingna Liu

Subjects

Metamorphic rock, engineering, Geochemistry, Metamorphism, Geology, Omphacite, engineering.material, Eclogite, Granulite, Gneiss, Hornblende, Zircon

Abstract

High-pressure mafic granulites (retrograded eclogites?) were discovered as minor lenses enclosed in garnet-kyanite-cordierite gneiss from the Badu Complex of the East Cathaysia terrane in South China. These rocks consist mainly of garnet, clinopyroxene, hornblende, quartz, and rutile/ilmenite with or without omphacite pseudomorphs that are indicated by clinopyroxene + sodic plagioclase symplectic intergrowths. Mineral textures and reaction relationships suggest three metamorphic stages: (1) an eclogite-facies stage (M1) characterized by the mineral assemblage of garnet + clinopyroxene (omphacite) + hornblende + rutile + quartz; (2) a high-pressure granulite-facies (M2) stage mainly represented by garnet + clinopyroxene + plagioclase + hornblende + rutile + quartz in the matrix; and (3) an amphibolite retrograde stage (M3) defined by hornblende + plagioclase + ilmenite + quartz symplectites surrounding garnet porphyroblasts. Conventional geothermometers and geobarometers in combination with phase equilibria modeling constrain metamorphic P–T conditions of 15.8–18.2 kbar/625–690 °C (M1), 11.8–14.5 kbar/788–806 °C (M2), and 5.4–6.4 kbar/613–668 °C (M3), respectively. Two-staged decompression processes are defined after the peak pressure, which suggests a two-staged exhumation of these deeply buried rocks. Secondary ion mass spectrometry (SIMS) zircon U-Pb dating and trace element analysis show that the high-pressure metamorphism occurred at 240–244 Ma. Complete early Mesozoic orogenic processes characterized by initial subduction and/or crustal thickening and subsequent exhumation followed by rapid uplift are reconstructed for this part of the East Cathaysia terrane, South China.

Published

2021

20. Native Gold and Au-Pt Alloy in Eclogite Xenoliths of Kalyandurg KL-2 Kimberlite, Anantapur District, South India

Author

E. V. S. S. K. Babu, Abhijeet Mukherjee, C. B. Verma, Pankaj Kumar Tiwari, and Jena Partha Sarathi

Subjects

Alloy, Geochemistry, Geology, 010501 environmental sciences, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Kyanite, Petrography, Homogeneous, visual_art, visual_art.visual_art_medium, engineering, Xenolith, Omphacite, Eclogite, Kimberlite, 0105 earth and related environmental sciences

Abstract

The paper pertains to the studies carried out on the eclogitic xenoliths of KL-2 kimberlite of Kalyandurg kimberlite cluster in south India. Petrographic studies revealed bi-mineralic and kyanite-bearing eclogitic xenoliths in KL-2 kimberlite. The bimineralic and kyanite-bearing eclogites of Kalyandurg KL-2 kimberlite pipe show variation in modal proportion of garnet, omphacite, clinopyroxene and kyanite. The paper reports discovery of native gold grains and Au-Pt alloy in the kyanite-bearing eclogite xenoliths of KL-2 kimberlite. The flaky gold grains occurring in the matrix of kyanite-bearing eclogite are homogeneous and two grains of Au-Pt alloy with Au and Pt in the proportion of 9.8:1.2 are also present. This is the first report of gold and gold-platinum alloy specs from eclogitic xenoliths of Indian kimberlites.

Published

2021

21. Metabasic rocks from the Variscan Schwarzwald (SW Germany): metamorphic evolution and igneous protoliths

Author

Stefan Hepp, Michael Hanel, Rainer Altherr, and Hans Klein

Subjects

010504 meteorology & atmospheric sciences, Metamorphic rock, Geochemistry, Metamorphism, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Kyanite, Prehnite, visual_art, engineering, visual_art.visual_art_medium, General Earth and Planetary Sciences, Omphacite, Eclogite, Geology, Amphibole, 0105 earth and related environmental sciences, Gneiss

Abstract

In the Variscan Schwarzwald metabasic rocks form small bodies included within anatectic plagioclase-biotite gneisses. Many metabasites first underwent an eclogite-facies metamorphism at about 2.0 GPa and 670–700 °C, resulting in the assemblage garnet + omphacite + rutile + quartz ± epidote ± amphibole ± kyanite. Since these eclogites are nearly free of an OH-bearing phase, they underwent almost complete dehydration during subduction, suggesting formation along an average to warm top-of-the-slab geotherm of 10–13 °C/km. The age of the Variscan high-P/high-T metamorphism is > 333 Ma. After partial exhumation from ~ 65 to ~ 15 km depth, the eclogites were overprinted under increasing activity of H2O by a number of retrograde reactions. The degree of this overprint under amphibolite-facies conditions (0.4–0.5 GPa/675–690 °C) was very different. Up to now, only retrograde eclogites have been found, but some samples still contain omphacite. Kyanite is at least partially transformed to aggregates of plagioclase + spinel ± corundum ± sapphirine. On the other hand, there are amphibolites that are extensively recrystallized and show the assemblage amphibole + plagioclase + ilmenite/titanite ± biotite ± quartz ± sulphides. The last relic phase that can be found in such otherwise completely recrystallized amphibolites is rutile. After the amphibolite-facies metamorphism at ~ 333 Ma, the metabasites underwent a number of low-temperature transformations, such as sericitization of plagioclase, chloritization of amphibole, and formation of prehnite. The intimate association of metabasite bodies with gneisses of dominantly meta-greywacke compositions suggests derivation from an active plate margin. This view is corroborated by bulk-rock geochemical data. Excluding elements that were mobile during metamorphism (Cs, Rb, Ba, K, Pb, Sr, U), the concentrations of the remaining elements in most of the metabasites are compatible with a derivation from island-arc tholeiites, back-arc basin basalts or calc-alkaline basalts. Only some samples have MORB precursor rocks.

Published

2021

22. Hydrogen Effect on the Sound Velocities of Upper Mantle Omphacite

Author

Wade Mans, Jin S. Zhang, Ming Hao, Joseph R. Smyth, Dongzhou Zhang, Gregory J. Finkelstein, and Przemyslaw Dera

Subjects

elasticity, omphacite, clinopyroxene, eclogite, structural water, nominally hydrous minerals, seismic velocities, Mineralogy, QE351-399.2

Abstract

Clinopyroxene (Cpx) is commonly believed to be the best structural water (hydrogen) carrier among all major upper mantle nominally anhydrous minerals (NAMs). In this study, we have measured the single-crystal elastic properties of a Cpx, a natural omphacite with ~710 ppm water at ambient pressure (P) and temperature (T) conditions. Utilizing the single-crystal X-ray diffraction (XRD) and electron microprobe data, the unit cell parameters and density were determined as a = 9.603(9) Å, b = 8.774(3) Å, c = 5.250(2) Å, β = 106.76(5)o, V = 255.1(4) Å3, and ρ = 3.340(6) g/cm3. We performed Brillouin spectroscopy experiments on four single crystals along a total of 52 different crystallographic directions. The best-fit single-crystal elastic moduli (Cijs), bulk and shear moduli were determined as: C11 = 245(1) GPa, C22 = 210(2) GPa, C33 = 249.6(9) GPa, C44 = 75.7(9) GPa, C55 = 71.2(5) GPa, C66 = 76(1) GPa, C12 = 85(2) GPa, C13 = 70(1) GPa, C23 = 66(2) GPa, C15 = 8.0(6) GPa, C25 = 6(1) GPa, C35 = 34.7(6) GPa, and C46 = 8.7(7) GPa, KS0 = 125(3) GPa, and G0 = 75(2) GPa, respectively. Compared with the anticipated elastic properties of an anhydrous omphacite with the same chemical composition, our results indicate that the incorporation of ~710 ppm structural water has no resolvable effect on the aggregate elastic properties of omphacite, although small differences (up to ~9 GPa) were observed in C13, C25, C44, and C66.

Published

2019

23. Petrology and metamorphism of glaucophane eclogites in Changning-Menglian suture zone, Bangbing area, southeast Tibetan Plateau: A evidence for Paleo-Tethyan subduction

Author

Jing-feng Hu, Ji Zhang, Bao-di Wang, Yun-he Liu, Guo-zhi Wang, Zhang Zhang, Yu-zhen Fu, Jun-lei Guan, Zhi-ming Peng, and Zou Hao

Subjects

Blueschist, Greenschist, Glaucophane, Materials Chemistry, engineering, Metamorphism, Suture (geology), engineering.material, Omphacite, Eclogite, Petrology, Geology, Metamorphic facies

Abstract

High/ultrahigh-pressure (HP/UHP) metamorphic complexes, such as eclogite and blueschist, are generally regarded as significant signature of paleo-subduction zones and paleo-suture zones. Glaucophane eclogites have been recently identified within the Lancang Group characterized by accretionary melange in the Changning-Menglian suture zone, at Bangbing in the Shuangjiang area of southeastern Tibetan Plateau. The authors report the result of petrological, mineralogical and metamorphism investigations of these rocks, and discuss their tectonic implications. The eclogites are located within the Suyi blueschist belt and occur as tectonic lenses in coarse-grained garnet muscovite schists. The major mineral assemblage of the eclogites includes garnet, omphacite, glaucophane, phengite, clinozoisite and rutile. Eclogitic garnet contains numerous inclusions, such as omphacite, glaucophane, rutile, and quartz with radial cracks around. Glaucophane and clinozoisite in the matrix have apparent optical and compositional zonation. Four stages of metamorphic evolution can be determined: The prograde blueschist facies (M1), the peak eclogite facies (M2), the decompression blueschist facies (M3) and retrograde greenschist facies (M4). Using the Grt-Omp-Phn geothermobarometer, a peak eclogite facies metamorphic P-T condition of 3000–3270 MPa and 617–658°C was determined, which is typical of low-temperature ultrahigh-pressure metamorphism. The comparison of the geological characteristics of the Bangbing glaucophane eclogites and the Mengku lawsonite-bearing retrograde eclogites indicates that two suites of eclogites may have formed from significantly different depths or localities to create the tectonic melange in a subduction channel during subduction of the Triassic Changning-Menglian Ocean. The discovery of the Bangbing glaucophane eclogites may represent a new oceanic HP/UHP metamorphic belt in the Changning-Menglian suture zone. ©2021 China Geology Editorial Office.

Published

2021

24. Eclogite inclusions from subducted metaigneous continental crust (Malpica-Tui Allochthonous Complex, NW Spain): Petrofabric, geochronology, and calculated seismic properties.

Author

Puelles, P., Beranoaguirre, A., Ábalos, B., Gil Ibarguchi, J. I., García de Madinabeitia, S., Rodríguez, J., and Fernández-Armas, S.

Abstract

This study describes the strain geometry, crystal-plastic deformational features, isotopic age of metamorphism, and calculated seismic properties of two medium-temperature eclogite types from the Malpica-Tui Allochthonous Complex of Variscan NW Iberia. The eclogite types are eclogites with coronitic garnets and eclogites with a planolinear fabric. Both of them were buried, deformed and recrystallized under maximum pressure and temperature of 2.6 GPa and 610-640°C, and subsequently exhumed in a late Devonian subduction channel. The metamorphic peak of the subduction-exhumation cycle occurred ~375 Ma ago. Omphacite petrofabric ties eclogites with coronitic garnet to noncoaxial constrictional strain and eclogites with planolinear fabrics to noncoaxial flattening strain and stretching along the lineation. We also used omphacite crystallographic preferred orientations to calculate and constrain the seismic properties of the eclogites. The slight variations in petrophysical properties observed are interpreted to result from variations in the strain regime recorded by pristine eclogites, or from variations in the modal proportions of the constituent high-pressure minerals. We foresee that eclogite in subduction metamorphic complexes might be either seismically undetectable or detected as planar features with high impedance contrasts relative to their host rocks. [ABSTRACT FROM AUTHOR]

Published

2017

25. Water transport by subduction: Clues from garnet of Erzgebirge UHP eclogite.

Author

SCHMäDICKE, ESTHER and GOSE, JüRGEN

Subjects

*GARNET, *WATER

Abstract

A key question concerning the water budget of Earth's mantle is how much water is actually recycled into the mantle by the subduction of eclogitized oceanic crust. Hydrous phases are stable only in quartz eclogite not coesite eclogite so that water transport to greater depths is mainly governed by structural water in omphacite and garnet. Here we explore if garnet can be used as a proxy to assess the amount of this water. Available data on the water contents of garnet in coesite eclogite vary over orders of magnitude, from a few up to ca. 2000 ppm. By implication, the maximum bulk-rock water contents are unrealistically high (wt% level). New data from the Erzgebirge indicate moderate amounts of structural H2O stored in garnet (43-84 ppm), omphacite (400-820 ppm), and in the bulk coesite eclogite (ca. 280-460 ppm). Higher garnet water contents occur, but these are not primary features. They are related to molecular water in fluid inclusions that can be attributed to eclogite-facies fluid influx postdating the metamorphic peak. Fluid influx also caused the uptake of additional structural water in garnet domains close to fluid inclusions. Such secondary H2O incorporation is only possible in the case of primary water-deficiency indicating that garnet hosted less water than it was able to store. This is insofar astonishing as comparably high H2O amounts are liberated by the breakdown of prograde eclogite-facies hydrous minerals as a result of ultrahigh-pressure (UHP) metamorphism. Judging from Erzgebirge quartz eclogite, dehydration of 5-10% hydrous minerals (±equal portions of zoisite+calcic amphibole) produces 1500-3000 ppm water. We infer that the largest part of the liberated water escaped, probably due to kinetic reasons, and hydrated exhuming UHP slices in the hanging-wall. Depending on the physical conditions, water influx in eclogite during exhumation (1) produces fluid inclusions and simultaneously enhances the structural water content of nominally anhydrous minerals--as in the Erzgebirge--and/or (2) it may give rise to retrograde hydrous minerals. We conclude that eclogite transports moderate quantities of water (several hundred parts per million) to mantle depths beyond 100 km, an amount equivalent to that in ca. 1% calcic amphibole. [ABSTRACT FROM AUTHOR]

Published

2017

26. Water transport in continental subduction zones: Constraints from eclogite from the Dabie orogen, east-central China.

Author

Wang, Zhi-Min, Chen, Ren-Xu, Zheng, Yong-Fei, Li, Shuning, Zhu, Lin, Gong, Bing, Zha, Xiang-Ping, and Li, Wan-Cai

Subjects

*ECLOGITE, *OROGENIC belts, *FLUID inclusions, *SUBDUCTION zones, *GARNET, *WATER depth, *HYDROUS

Abstract

[Display omitted] • Garnet contains both structural hydroxyl and molecular H 2 O in tiny fluid inclusions. • Molecular H 2 O can be either intrinsic or external origin in eclogitic garnet. • Inter-transformation between structural hydroxyl and molecular H 2 O in garnet. • Hydroxyl at higher wavenumber in garnet are more stable and more enriched in D. Water in nominally anhydrous minerals may exist as structural hydroxyl and molecular H 2 O, and their inter-transformation can occur during subduction zone metamorphism. This issue is examined here by a systematic study on water in garnet and omphacite for ultrahigh-pressure metamorphic eclogites from the Dabie orogen. IR spectra of garnet at different preheating temperatures imply that the broad absorption band at 3400–3450 cm−1 mainly represents molecular H 2 O. Molecular H 2 O in garnet can be intrinsic origin, but is mainly originated from external fluid during exhumation. The positive correlation between molecular H 2 O and structural hydroxyl in garnet suggests their inter-transformation. Molecular H 2 O that was formerly included in garnet or derived from decomposition of hydrous minerals was transformed gradually to structural hydroxyl in garnet during subduction. OH− modes at higher wavenumber in garnet are more stable and more enriched in D, and d -poor molecular H 2 O is preferentially lost during dehydration. Hydroxyl in both anhydrous and hydrous minerals would be transformed to molecular H 2 O during exhumation and redistributed into garnet or retrograde minerals. The addition of molecular H 2 O into garnet during exhumation causes increase of structural hydroxyl but decrease of δD value, and affects accurate estimate of water content in peak garnet. Different from the large variation of garnet water contents, omphacite tends to be water-saturated at high-pressure conditions and its water content is mainly controlled by Ca-Eskola. The subducting mafic crust can transport a considerable amount of water to subarc depths to result in the formation of relatively water-rich mantle regions. [ABSTRACT FROM AUTHOR]

Published

2023

27. Petrology, geochemistry and Sm-Nd systematics of the Paleoproterozoic Itaguara retroeclogite from São Francisco/Congo Craton: One of the oldest records of the modern-style plate tectonics

Author

Carla Cristine Porcher and Alexandre de Oliveira Chaves

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Continental collision, Geochemistry, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Craton, Symplectite, engineering, Eclogite, Omphacite, Petrology, Eclogitization, Protolith, Metamorphic facies, 0105 earth and related environmental sciences

Abstract

Paleoproterozoic retrogressed eclogite (retroeclogite) occurs in the Itaguara Sequence included in the suture zone formed by collision between the Archean Divinopolis and Campo Belo/Bonfim Complexes in the southern Sao Francisco Craton, which represents the South American counterpart of the African Congo Craton. The Itaguara retroeclogite contains scarce omphacite and phengite but abundant garnet porphyroblasts embedded in a fine-grained, amphibole, biotite and quartz-bearing matrix. The 2.20 ± 0.05 Ga eclogitization event (garnet and whole rock Sm-Nd isochronic age) of the E-MORB protolith (TDM ~ 2.47 Ga) is recorded by omphacite formation during high-pressure prograde stage in amphibole eclogite facies due to ~70 km depth subduction process. Amphibole eclogite facies metamorphic peak stage of 17–20 kbar and 600–700 °C occurred during ~2.1 Ga continental collision. Tectonic exhumation-related decompression during collision probably triggered partial melting of the eclogitic rock. Finally, decompression late stage estimated between 5 and 8 kbar and 550–650 °C under amphibolite facies overprint during orogenic collapse was responsible for appearance of kelyphitic reaction rims (symplectite) around garnet crystals. As its Paleoproterozoic contemporary analogues from Congo Craton, the Itaguara retroeclogite is one of the oldest records of the modern-style plate tectonics.

Published

2020

28. Carboniferous eclogite and garnet–omphacite granulite from northeastern Hainan Island, South China: Implications for the evolution of the eastern Palaeo‐Tethys

Author

Yi Chen, Xiaochun Liu, Biao Song, Daogong Hu, Wei- Wang, Mengmeng Xia, Juan Hu, and Yibing Li

Subjects

South china, Geochemistry and Petrology, Carboniferous, engineering, Geochemistry, Geology, Eclogite, Omphacite, engineering.material, Granulite

Published

2020

29. Partial melting of zoisite eclogite from the Sanddal area, North-East Greenland Caledonides

Author

Jane A. Gilotti, Hans-Joachim Massonne, and Wentao Cao

Subjects

Materials science, 05 social sciences, Partial melting, Mineralogy, Zoisite, engineering.material, Kyanite, Paragonite, Phengite, Albite, visual_art, 0502 economics and business, visual_art.visual_art_medium, engineering, 050211 marketing, Eclogite, Omphacite, 050203 business & management, QE351-399.2

Abstract

Metamorphic textures and a pressure–temperature (P–T) path of zoisite eclogite are presented to better understand the metamorphic evolution of the North-East Greenland eclogite province and this particular type of eclogite. The eclogite contained the mineral assemblage garnet, omphacite, kyanite, phengite, quartz and rutile at peak pressure. Partial melting occurred via breakdown of hydrous phases, paragonite, phengite and zoisite, based on (1) polymineralic inclusions of albite and K-feldspar with cusps into host garnet, (2) small euhedral garnet with straight boundaries against plagioclase, (3) cusps of plagioclase into surrounding phases (such as garnet), and (4) graphic intergrowth of plagioclase and amphibole next to anhedral zoisite grains. Isochemical phase equilibrium modeling of a melt-reintegrated composition, along with XNa-in-omphacite and Si-in-phengite isopleths, yields a peak pressure of 2.4±0.1 GPa at 830±30 ∘C. A peak temperature of 900±50 ∘C at 1.9±0.2 GPa is determined using the rim composition of small euhedral garnet, as predicted by modeling a crystallized melt pocket. Zoisite growth at the expense of kyanite suggests that the P–T path crossed the fields of zoisite growth at ∼1.9 GPa, 800–900 ∘C on the modeled phase diagram of the bulk rock. A point on the exhumation path at ∼1.3 GPa and 750 ∘C is derived from hornblende-plagioclase thermometry and Al-in-hornblende barometry. The study demonstrates that paragonite, phengite and zoisite could contribute to partial melting of eclogite at near-peak P and during exhumation.

Published

2020

30. Extremely light K in subducted low-T altered oceanic crust: Implications for K recycling in subduction zone

Author

Brenna Tuller-Ross, Haiyang Liu, Yilin Xiao, Ying-Yu Xue, Kun Wang, and Weidong Sun

Subjects

Basalt, 010504 meteorology & atmospheric sciences, Mantle wedge, Chemistry, Geochemistry, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), Phengite, Geochemistry and Petrology, Oceanic crust, engineering, Omphacite, Eclogite, Amphibole, 0105 earth and related environmental sciences

Abstract

In order to investigate the behavior of potassium (K) isotopes during metamorphic dehydration and to further constrain its implications for K recycling in the subduction zone, we measured K isotopic compositions of whole-rocks and separated minerals (phengite, omphacite, amphibole) from Sumdo eclogites, Tibet, using a recently established high-precision analysis method. Our data reveal that the δ41K (‰) of the whole-rock eclogites (−1.64 to −0.24) displays dramatically lower values than observed in fresh mid-ocean ridge basalts (MORB) (−0.43 ± 0.17) and altered MORB (−0.76 to −0.11). In addition, the δ41K values of eclogites show a positive correlation with both K2O contents and K/Nb ratios, which suggests that the low δ41K values were most likely caused by dehydration during subduction. Thus, isotopically heavy K may be released into the mantle wedge, while the light component is subducted into the deep mantle. Therefore, the K isotope systems have the potential to trace subducted crustal materials and to create heterogeneity within the mantle. Mineral separates from Sumdo eclogites are highly heterogeneous in K isotopic compositions, ranging from −0.98 to +0.23 in phengite, from −1.25 to −1.10 in omphacite and from −1.16 to −0.09 in amphibole. The K isotope fractionations between amphibole and phengite and between amphibole and omphacite vary from −0.30 to +0.25 and from −0.04 to +0.63, respectively, indicating K isotopic disequilibrium between amphibole and omphacite/phengite, which might result from the multistage growth of minerals during subduction metamorphism. However, generally phengites show heavier K isotopic compositions than the coexisting omphacite (Δ41Kphengite-amphibole = +0.25) and amphibole (Δ41Kphengite-amphibole = +0.03 ∼ +0.30, except TB193 is −0.25), which may imply that the K isotopic fractionation is controlled by the difference in coordination numbers of K between phengite (6) and omphacite (7 to 8)/amphibole (8).

Published

2020

31. Pre-Alpine high-pressure metamorphism in the Gemer unit: mineral textures and their geodynamic implications for Variscan Orogeny in the Western Carpathians

Author

Shah Wali Faryad, Peter Ivan, and Radim Jedlicka

Subjects

Blueschist, 010504 meteorology & atmospheric sciences, Metamorphic rock, Geochemistry, Metamorphism, Orogeny, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, engineering, General Earth and Planetary Sciences, Omphacite, Eclogite, Structural geology, Geology, 0105 earth and related environmental sciences, Gneiss

Abstract

We report mineral textures of retrogressed eclogites from the gneiss–amphibolite complex, which is represented by a series of isolated bodies that were thrusted over the greenschist-facies Rakovec group in the Gemer unit (Western Carpathians). Peak pressure and temperature conditions of about 2.0 GPa and 650 °C are estimated for the eclogite-facies assemblage (omphacite, garnet and rutile). The eclogites show strong amphibolite-facies re-equilibration that is characteristic for the rest of gneiss–amphibolite complex rocks. Pressure and temperature conditions for both eclogite and subsequent amphibolite-facies stages are comparable with those reported from the retrogressed eclogites in the Vepor and Tatra units. The underlying Rakovec group rocks indicate greenschist-facies conditions, but relicts of high-pressure (blueschist facies) metamorphism are also preserved. The Pre-Alpine age of the eclogite-facies metamorphism in the gneiss–amphibolite complex and blueschist-facies metamorphism in the Rakovec group is confirmed by the presence of their pebbles in the overlaying upper Carboniferous conglomerates. The origin of eclogites and blueschists in the Gemer unit and their relationship to eclogites in the Vepor and Tatra units are discussed with respect to the subduction zone along which they originated, but also in relation to the high-pressure rocks occurring along the European Variscan Belt. As the whole Gemer unit underwent Alpine metamorphism, the retrogressed eclogites and associated gneisses were also studied to clarify possible degree of this metamorphic overprint in the gneiss–amphibolite complex rocks.

Published

2020

32. Microstructures and Phase Transition in Omphacite: Constraints on the P-T Path of Shuanghe Eclogite (Dabie Orogen)

Author

Xiangwen Liu, Zhanjun Xie, Zhuoyue Li, and Zhenmin Jin

Subjects

020209 energy, Metamorphic rock, Space group, 02 engineering and technology, engineering.material, 010502 geochemistry & geophysics, Microstructure, 01 natural sciences, Crystallography, Albite, 0202 electrical engineering, electronic engineering, information engineering, engineering, General Earth and Planetary Sciences, Dislocation, Eclogite, Omphacite, Geology, Amphibole, 0105 earth and related environmental sciences

Abstract

Omphacite microstructures are important to decipher the metamorphic pressuretemperature (P-T) conditions of eclogite during subduction and exhumation processes. Here we present a systematic microstructural investigation of omphacite using transmission electron microscopy (TEM) in an ultrahigh-pressure (UHP) eclogite sample from Shuanghe, Dabie orogen, China. The omphacite can be divided into two phases: (1) Omp-1, exhibits as the main part of omphacite with P2/n space group containing small amount of dislocations and numerous antiphase domains (APDs). (2) Omp-2, shows as banded subgrains with C2/c space group containing large amount of dislocations. These two phases of omphacite have almost the same crystallography orientation and bounded by dislocation walls. Along these dislocation walls, we found some barroisite and albite microcrystals. The barroisite microcrystals contain large amount of dislocations and show a topological relation with host omphacite. While the albite microcrystals contain small amount of dislocations and does not show topological relation with host. These microstructures could give us the following metamorphic information to constrain the P-T path of eclogite: Firstly, this two omphacite space groups should be evolved from the same precursor C2/c omphacite, which had been underwent strongly plastic deformation during the syn- to late-peak metamorphic stage. Secondly, the precursor C2/c omphacite began to be retrograded and altered by small amount of barroisite microcrystals along its dislocation walls under the P-T condition of 2.2–2.6 GPa and 650–700 °C at the early amphibole eclogite stage. Thirdly, large amount of Na and other elements were exsolved from some precursor C2/c omphacite subgrains and crystallized numerous albite microcrystals at their boundaries, which is the necessary for the space group of C2/c surviving under the lower P-T conditions (1.7–1.9 GPa and 630–690 C) during the middle amphibole eclogite stage. Lastly, the rest of precursor C2/c omphacite subgrains were transformed into P2/n polymorph and formed the APDs structures under the P-T condition of ~1.5 GPa and 650–680 °C during the late amphibole eclogite stage.

Published

2020

33. Discovery of eclogites in Jinsha River suture zone, Gonjo County, eastern Tibet and its restriction on Paleo-Tethyan evolution

Author

Gang Chen, Hong-you Yao, Ya-dong Qin, Dong-bing Wang, Shiyong Liao, Xiao-dong Gong, Yuan Tang, Jun-xiong Liao, Yao-yao Duan, and Bao-di Wang

Subjects

Metamorphic rock, Geochemistry, Schist, Paleontology, Metamorphism, Geology, engineering.material, Geotechnical Engineering and Engineering Geology, Oceanography, Geochemistry and Petrology, engineering, Economic Geology, Suture (geology), Computers in Earth Sciences, Omphacite, Eclogite, Earth-Surface Processes, Zircon, Hornblende

Abstract

As the important component of the eastern Tethys tectonic region, the Jinsha River-Ailao Mountain suture zone is often considered to be an ophiolitic melange belt. However, the P-T-t path and chronological framework of the metamorphic evolution in the collisional orogenetic process of this zone are still poorly understood owing to the lack of metamorphism research of symbolic high-pressure rocks. During a regional geological survey on a scale of 1 : 50000 in Gonjo County, Tibet Autonomous Region involved in this paper, (retrograde) eclogites lenses of different scales were found in Jinsha River suture zone, eastern Tibet for the first time. The (retrograde) eclogites can be divided into garnet-albite-chlorite-actinolite schists and eclogites according to retrograde degrees. The mainly mineral components of eclogites include garnet (45%–50%), clinopyroxene (about 25%), and hornblende (5%–10%) primarily, and biotite, quartz, rutile, and muscovite secondarily. According to the data of electron probe micro analysis (EPMA), clinopyroxenes feature high content of Na2O (5.6%–6%) and corresponding jadeite (Jd) molecules of 37%–44%, and they fall within the omphacite region in Quad-Jd-Ae diagram. The temperature and pressure of the metamorphism at peak are P≈2.2–2.34 GPa and T≈622–688 °C respectively as measured with geobarometry Grt-Omp-Phe and geothermometer Grt-Omp. This will provide a new reference for the understanding of Paleo-Tethyan evolution. In this paper, two samples of eclogites were chosen for LA-ICP-MS zircon U-Pb dating and their 206Pb/238U ages obtained are 240 ± 3 Ma and 244 ± 1 Ma respectively. Furthermore, the zircons feature extremely low Th/U ratio (

Published

2020

34. Electrical Conductivity of Omphacite as a Function of Water Content and Implications for High Conductivity Anomalies in the Dabie‐Sulu UHPM Belts and Tibet

Author

Takashi Yoshino, Baohua Zhang, Jianhua Ge, and Chengcheng Zhao

Subjects

geography, Plateau, geography.geographical_feature_category, Continental collision, Metamorphic rock, Crust, Conductivity, engineering.material, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Electrical resistivity and conductivity, Earth and Planetary Sciences (miscellaneous), engineering, Eclogite, Omphacite, Petrology, Geology

Abstract

Magnetotelluric surveys revealed high‐conductivity layers in the lower crust beneath Tibet and in the shallow part of the upper mantle relevant to continental collision extending to the Dabie‐Sulu ultrahigh‐pressure metamorphic (UHPM) belts of eastern China, which have been interpreted by the presence of aqueous fluids/partial melts or hydrous phases. However, these explanations are not consistent with their petrological features and seismic properties. Hydrogen‐bearing omphacite could be a probable candidate to explain such high‐conductivity anomalies due to its high water‐partitioning coefficient versus coexisting garnet in eclogite. In this study, we investigated electrical conductivities of Fe‐free and Fe‐bearing omphacite as a function of water content (0.005–0.122 wt.%) at 3 GPa and 500–1300 K. Our results show that water significantly enhances the electrical conductivity of omphacite, while iron facilitates conductivity by accelerating hydrogen diffusivity and lowering its activation enthalpy. Assuming a heat flow of 70 mW/m2, the high electrical anomalies observed beneath the Dabie‐Sulu UHPM belts and the Tibetan Plateau can be reasonably explained by omphacite containing 0.07 wt.% water since water content higher than 0.07 wt.% in omphacite was frequently reported in naturally collected eclogite.

Published

2019

35. Timanide (Ediacaran-Early Cambrian) Metamorphism at the Transition from Eclogite to Amphibolite Facies in the Beloretsk Complex, SW-Urals, Russia

Author

Johannes Glodny, Michael Gopon, Hans-Peter Schertl, V. N. Puchkov, and Arne P. Willner

Subjects

Isochron, 020209 energy, Metamorphic rock, Geochemistry, Metamorphism, 02 engineering and technology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Phengite, 0202 electrical engineering, electronic engineering, information engineering, engineering, General Earth and Planetary Sciences, Eclogite, Omphacite, Geology, Metamorphic facies, 0105 earth and related environmental sciences, Gneiss

Abstract

The Beloretsk Metamorphic Complex in the SW Urals formed at a convergent eastern margin of Baltica during the Neoproterozoic-Early Cambrian Timanide orogeny. It comprises three major units with lenses of facies-critical metabasites within metasedimentary rocks: A lowermost eclogite unit, an intermediate garnet amphibolite unit and an upper amphibolite-greenschist unit. Pressure (P)-temperature (T)-paths of four rocks from the two lowermost units were determined mainly by PT pseudosection techniques showing similar clockwise loops at different peak metamorphic, water-saturated conditions: A phengite-bearing eclogite shows peak PT conditions of 16.5–18.5 kbar/525–550 °C (stage I) followed by stage II at 11.5–13.0 kbar/585–615 °C. A garnet amphibolite from the intermediate unit yields lower peak conditions of 11.7–14.5 kbar/480–510 °C (stage I) followed by stage II at 9.5–11.0 kbar/535–560 °C. However, a granite gneiss in the eclogite unit shows similar maximum pressures as the eclogite, but higher temperatures at 15.6–16.2 kbar/660–675 °C, whereas a garnet micaschist contains comparable high pressure relicts, but underwent an advanced midcrustal reequilibration at 7.5–9.0 kbar/555–610 °C. We dated the eclogite by a 7-point Rb/Sr mineral isochron (phengite, omphacite, apatite) at 532.2±9.1 Ma interpreted as age of crystallisation of the eclogitic peak PT assemblage. This age is the youngest compared to the known Timanide metamorphic and magmatic ages.

Published

2019

36. H2O in omphacite of quartz and coesite eclogite from Erzgebirge and Fichtelgebirge, Germany

Author

Gose, Jürgen, Schmädicke, Esther, and 1 Geozentrum Nordbayern University Erlangen‐Nürnberg Erlangen Germany

Subjects

Subduction, Geochemistry, Geology, engineering.material, ddc:549, ddc:552.4, Geochemistry and Petrology, Coesite, engineering, ddc:550, Eclogite, Omphacite, Quartz

Abstract

Major and trace elements in omphacite, including hydrogen, were determined in eclogites from two Variscan basement complexes in Germany: Erzgebirge (EG) and Fichtelgebirge (FG). Erzgebirge eclogite is derived from three units, showing different peak pressure (P) and temperature (T) conditions (Unit 1: 840–920°C/≥30 kbar, Unit 2: 670–730°C/24–26 kbar, Unit 3: 600–650°C/20–22 kbar). The peak conditions of FG eclogite (690–750°C/25–28 kbar) resemble those of EG Unit 2. Coesite eclogite occurs in EG Unit 1, and quartz eclogite in all other units. Omphacite from all samples shows four infrared (IR) absorption bands. Two prominent, sharp bands occur at 3,455 ± 10 cm−1 (band II) and 3,522 ± 10 cm−1 (band III). Band II is usually more prominent than band III, except for few samples with low jadeite content. A further, broad band is centred between 3,270 and 3,370 cm−1 (band I) and a fourth, minor band at 3,611–3,635 cm−1 (band IV). Bands II and III are due to hydrogen bound as structural OH− ions in omphacite. In most cases, this also applies to band IV. However, some spectra with extremely large type IV bands reflect phengite inclusions. The ambiguous band I may be due to different H2O species (molecular water, structural OH, and water in phengite). Omphacite of quartz eclogite has lower contents of TiO2, Zr, Hf, and REE, compared with that from coesite eclogite. By contrast, omphacite in quartz eclogite from both EG (H2O sample averages: 465–852 ppm) and FG (546–1,089 ppm) contains the same amount of structural OH (concentrations given in wt.‐ppm H2O) as omphacite in coesite eclogite (492–1,140 ppm). The obtained difference in the garnet‐omphacite H2O partition coefficient between quartz (0.01–0.03) and coesite eclogite (0.08–0.11) results from different H2O contents in garnet (coesite eclogite: 50–150 ppm; quartz eclogite: 10 vol.% pre‐eclogitic hydrous minerals, is not preserved in eclogite but liberated to the mantle wedge., Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659

Published

2021

37. Metamorphic evolution of a Tonian eclogite associated with an island arc of the southern Brasiliano Orogen

Author

Carla Cristine Porcher, Cristiano Lana, Gláucia Nascimento Queiroga, David Debruyne, Viter Magalhães Pinto, Marco Paulo de Castro, L.A. Hartmann, Brenda Fragoso, and Jorge Henrique Laux

Subjects

TONIAN, P-T-T PATH, BRASILIANO OROGEN, Metamorphic rock, Geochemistry, NEOPROTEROZÓICO, Geology, SÃO GABRIEL TERRANE, engineering.material, TERRENO SÃO GABRIEL, MAGMATISMO, Augite, ECLOGITE, Geochemistry and Petrology, Tonian, engineering, EVOLUÇÃO METAMÓRFICA, NEOPROTEROZOIC ARC MAGMATISM, Eclogite, Omphacite, Metamorphic facies, Hornblende, Zircon

Abstract

The early evolution of the southern Brasiliano Orogen is recorded in the Sao Gabriel Terrane, which consists of two Neoproterozoic (Tonian and Cryogenian) juvenile arcs, ophiolite complexes and supracrustal rocks. This study aims at providing new insights into the geodynamics processes and subduction process of this orogen by investigating the first Tonian eclogite (named Tres Vendas eclogite) discovered in the southern Brasiliano Orogen. To determine the tectono-metamorphic evolution, we integrated field work with petrography, scanning electron microscopy, electron microprobe analyses of minerals and in situ LA-ICP-MS U-Pb geochronology with Lu-Hf and rare earth elements in zircon. The preserved high-grade metamorphic assemblage in these rocks has garnet, rutile, phengite, and omphacite, indicating that these rocks are (retro) eclogites. The presence of omphacite with up to 50% jadeite indicates minimum burial pressures of ≥15 kbar that are consistent with forward modeling of the garnet compositions. Omphacite was altered to fine-grained symplectites of hornblende, oligoclase, and diopside or augite with minor quartz during rapid exhumation. The second stage of retrogression involved reaction of garnet and diopside to plagioclase and hornblende symplectites (kelyphites) at amphibolite facies conditions. Kelyphitic hornblende-garnet pairs indicate peak temperatures of 710–760 °C. Whole rock composition and Zr–Y characteristics are consistent with tholeiitic island arc basalts, while their garnet compositions point to subduction zone eclogites. U-Pb ages of zircon cores yielded 909.5 ± 5.3 Ma and metamorphic rims 891.9 ± 8.2 Ma. Zircon age-corrected eHf isotope compositions range between +4 and +10, reflecting the moderately juvenile nature of these rocks. Zircon cores are distinguished by higher rare earth element (REE) contents and steeper middle REE to heavy REE (MREE-HREE) patterns, higher Th/U ratios and higher Sr and Ca contents than the metamorphic rims, and the rims are likely coeval with the kelyphites. The combined data indicate that the Tres Vendas eclogites belong to a Tonian arc and were buried to >45 km, most likely in a subduction channel. The data from the first eclogite in southern Brazil have significant consequences for the interpretation of the Tonian evolution of the Brasiliano Orogen and, by extension, the Rodinia framework.

Published

2021

38. Crystallographic preferred orientations and microtexture of the Himalayan eclogites revealing records of syn-deformation peak metamorphic stage and subsequent exhumation.

Author

Rehman, Hafiz U., Mainprice, David, Barou, Fabrice, Yamamoto, Hiroshi, Wei, Chunjing, Zafar, Tehseen, and Khan, Tahseenullah

Subjects

*ECLOGITE, *GARNET, *SPHENE, *RUTILE, *MATERIAL plasticity, *HORNBLENDE, *MINERALS

Abstract

Electron backscattered diffraction (EBSD) and crystallographic preferred orientations (CPO) studies on Himalayan high- and ultrahigh-pressure eclogites are reported. Subduction-related peak eclogite facies (omphacite, garnet, quartz, rutile) and exhumation-related post-eclogite facies (hornblende, epidote, titanite) minerals were investigated to understand subduction and exhumation-related deformation regimes. Petrographic features from the studied eclogite samples show preferably shape-oriented omphacites coexisting with random to weakly shape-oriented garnets, and overgrown by hornblende and symplectites. Quartz grains are also randomly shape-oriented in the eclogite matrix whereas epidote grains display shape-preferred orientations. Based on EBSD data, an L-type CPO was dominant in omphacites in the studied eclogites, exhibited by the maximum density of [001] axes parallel to the lineation and the high density of poles to the (010) and (110) planes forming girdles perpendicular to the foliation. This CPO likely developed in a constrictional strain regime during the peak eclogite-facies conditions due to dislocation creep and is associated with an intra-crystalline (110) [001] and (110) <110> slip systems. EBSD data of garnets exhibit complex fabric, suggesting they most likely behaved like rigid objects in the presence of omphacite, indicating insignificant plastic deformation. EBSD data of quartz in high-pressure eclogites show irregular CPO but in ultrahigh-pressure eclogites the fabric is relatively strong. EBSD data of rutile show CPO of [001] axes strongly aligned along the lineation, suggesting its deformation was coeval to the omphacite. Titanite, mainly overgrown around rutile, indicates a random CPO different from rutile, suggesting its growth during late-stages. Hornblende in both types of eclogites shows identical fabric to that of omphacite, displaying CPO of [001] axes parallel to the lineation and poles of (010) and (110) planes form girdles perpendicular to the foliation, suggesting topotactic replacement over omphacite during exhumation. The EBSD data, combined with textural features, indicate syn-deformation peak metamorphism as well as preserve records of subsequent exhumation. • Crystallographic Preferred Orientations (CPO) of Himalayan HP/UHP eclogites. • Data indicate petrofabric developed during peak eclogite facies stage. • Clinopyroxene with an L-type CPO suggests an intra-crystalline plasticity in constrictive strain regime. • Garnet with random fabric suggests rigid objects rotation. • Hornblende, with CPO similar to that of clinopyroxene, display topotactic growth over clinopyroxene during retrogression. [ABSTRACT FROM AUTHOR]

Published

2023

39. Fluid Pulses During Stepwise Brecciation at Intermediate Subduction Depths (Monviso Eclogites, W. Alps): First Internally Then Externally Sourced

Author

Thomas Pettke, Michele Locatelli, Anne Verlaguet, Philippe Agard, and Laura Federico

Subjects

010504 meteorology & atmospheric sciences, Lawsonite, Subduction, eclogite-facies breccia, fluid migration, engineering.material, subductions, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Monviso, Geochemistry and Petrology, 550 Earth sciences & geology, Breccia, engineering, W-alps, Paragenesis, Omphacite, Shear zone, Eclogite, Pseudomorph, Petrology, Geology, eclogite-facies breccia, fluid migration, Monviso, subductions, W-alps, 0105 earth and related environmental sciences

Abstract

Eclogite‐facies breccias from the Monviso metaophiolite complex (N‐Italy and W‐Alps) represent a unique opportunity to study the triggering mechanisms for transient brittle deformation at eclogite‐facies conditions in ductilely deforming subducted oceanic lithosphere. Here the intact foliation of Fe‐Ti‐rich and Mg‐Al‐rich metagabbro clasts, cemented by unfoliated eclogitic matrices (paragenesis: omphacite ± garnet ± lawsonite), demonstrates pristine brecciation at eclogite‐facies conditions. Successive generations of high‐pressure veins and eclogitic matrices reveal multiple brittle rupture events. Pseudosection modeling, textural observations, and geochemical data suggest that minerals of both prograde veins and first brecciation event (M1 matrix) crystallized in presence of fluids buffered by the surrounding metagabbro minerals, while M2 matrix composition suggests an incipient infiltration of external fluids. Trace element composition of the third M3 matrix, associated to its impressive lawsonite pseudomorphs, clearly points to the massive ingression of external, serpentinite‐derived fluids. Therefore, these rocks record the progressive increase in the scale of fluid circulation along multiple, stepwise eclogitic brecciation events, from locally released fluids (closed system) to kilometer‐scale fluid infiltration. The successive brecciation steps promoted permeability creation (at least transiently), which resulted in progressive opening of the system to large‐scale sustained fluid circulation. Eclogite‐facies brecciation also controlled the initial stages of strain localization, which highlights the importance, in ductilely deforming low‐permeability eclogite‐facies rocks, of brittle deformation events for both strain localization initiation and creation of large‐scale fluid circulation pathways. Thus, Monviso breccia blocks record the complete, stepwise development of a major shear zone, via progressive strain localization, permeability creation, and increasing scale of fluid circulation.

Published

2019

40. Origin of K-rich diamond-forming immiscible melts and CO2 fluid via partial melting of carbonated pelites at a depth of 180–200 km

Author

Anton Shatskiy, Ivan V. Podborodnikov, Konstantin D. Litasov, and Anton V. Arefiev

Subjects

010504 meteorology & atmospheric sciences, Partial melting, Geochemistry, Geology, Solidus, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Kyanite, Aluminosilicate, visual_art, Coesite, engineering, visual_art.visual_art_medium, Eclogite, Omphacite, 0105 earth and related environmental sciences, Melt inclusions

Abstract

Melt inclusions in kimberlitic and metamorphic diamonds worldwide range in composition from potassic aluminosilicate to alkali-rich carbonatitic and their low-temperature derivative, a saline high-density fluid (HDF). The discovery of CO2 inclusions in diamonds containing eclogitic minerals are also essential. These melts and HDFs may be responsible for diamond formation and metasomatic alteration of mantle rocks since the late Archean to Phanerozoic. Although a genetic link between these melts and fluids was suggested, their origin is still highly uncertain. Here we present experimental results on melting phase relations in a carbonated pelite at 6 GPa and 900–1500 °C. We found that just below solidus K2O enters potassium feldspar or K2TiSi3O9 wadeite coexisting with clinopyroxene, garnet, kyanite, coesite, and dolomite. The potassium phases react with dolomite to produce garnet, kyanite, coesite, and potassic dolomitic melt, 40(K0.90Na0.10)2CO3·60Ca0.55Mg0.24Fe0.21CO3 + 1.9 mol% SiO2 + 0.7 mol% TiO2 + 1.4 mol% Al2O3 at the solidus established near 1000 °C. Molecular CO2 liberates at 1100 °C. Potassic aluminosilicate melt appears in addition to carbonatite melt at 1200 °C. This melt contains (mol/wt%): SiO2 = 57.0/52.4, TiO2 = 1.8/2.3, Al2O3 = 8.5/13.0, FeO = 1.4/1.6, MgO = 1.9/1.2, CaO = 3.8/3.2, Na2O = 3.2/3.0, K2O = 10.5/15.2, CO2 = 12.0/8.0, while carbonatite melt can be approximated as 24(K0.81Na0.19)2CO3·76Ca0.59Mg0.21Fe0.20CO3 + 3.0 mol% SiO2 + 1.6 mol% TiO2 + 1.4 mol% Al2O3. Both melts remain stable to at least 1500 °C coexisting with CO2 fluid and residual eclogite assemblage consisting of K-rich omphacite (0.4–1.5 wt% K2O), almandine-pyrope-grossular garnet, kyanite, and coesite. The obtained immiscible alkali‑carbonatitic and potassic aluminosilicate melts resemble compositions of melt inclusions in diamonds worldwide. Thus, these melts entrapped by diamonds could be derived by partial melting of the carbonated material of the continental crust subducted down to 180–200 km depths. Given the high solubility of chlorides and water in both carbonate and aluminosilicate melts inferred in previous experiments, the saline end-member, brine, could evolve from potassic carbonatitic and/or silicic melts by fractionation of Ca-Mg carbonates/eclogitic minerals and accumulation of alkalis, chlorine and water in the residual low-temperature supercritical fluid. Direct extraction from the hydrated marine sediments under conditions of cold subduction would be another possibility for the brine formation.

Published

2019

41. The Role of Garnetization of Olivine in the Olivine–Diopside–Jadeite System in the Ultramafic–Mafic Evolution of Upper-Mantle Magmatism (Experiment at 6 GPa)

Author

E. V. Limanov, Yu. A. Litvin, and A. V. Kuzyura

Subjects

Olivine, Fractional crystallization (geology), Diopside, Geochemistry, Liquidus, engineering.material, Geophysics, Geochemistry and Petrology, Ultramafic rock, visual_art, engineering, visual_art.visual_art_medium, Mafic, Eclogite, Omphacite, Geology

Abstract

The peritectic mechanisms controlling the ultramafic–mafic evolution of magmatism during fractional crystallization and the genesis of peridotite–pyroxenite–eclogite rock series of the garnet–peridotite facies of the upper mantle were substantiated experimentally. The melting phase relations of differentiated mantle material in the olivine–clinopyroxene/omphacite–corundum–coesite multicomponent system were studied by the polythermal sections method; their boundary phases reproduced the compositions of peridotitic and eclogitic minerals. The peritectic reaction between orthopyroxene and melt with the formation of clinopyroxene proceeds at the liquidus of the olivine–orthopyroxene–clinopyroxene–garnet system as the mechanism for “clinopyroxenization of orthopyroxene,” which yields the regressive olivine + clinopyroxene + garnet + melt monovariant cotectic reaction. The further evolution of magmatism was studied experimentally at 6 GPa in the ultramafic–mafic olivine–diopside–jadeite–garnet system with a variable composition of the diopside–jadeite solid solutions (clinopyroxene ↔ omphacite). The peritectic reaction between olivine and melt with the formation of garnet was detected on the liquidus of the triple system olivine–diopside–jadeite as the of olivine garnetization mechanism yielding the omphacite + garnet + melt cotectic reaction with the formation of bimineral eclogite. The structure of the liquidus of the olivine–diopside–jadeite–garnet system was defined, as well as its critical role as the “physicochemical bridge” between the ultramafic olivine-bearing peridotite–pyroxenite composition and mafic silica-saturated eclogitic composition of matter within the garnet–peridotite facies. The experimental physicochemical results illustrate the genetic links between ultramafic and mafic rocks and the mechanisms of continuous fractional magmatic evolution and petrogenesis from olivine-bearing peridotite–pyroxenite rocks to silica-saturated eclogite–grospydite rocks. This explains the complete petrochemical trends for the rock-forming components in clinopyroxenes and garnets from differentiated rocks of the garnet–peridotite facies.

Published

2019

42. Helium Isotopic Composition of the Songduo Eclogites in the Lhasa Terrane, Tibet: Information from the Deep Mantle

Author

Tianfu Li, Songyong Chen, Jingsui Yang, and Zhaoli Li

Subjects

020209 energy, Eastern china, Geochemistry, chemistry.chemical_element, 02 engineering and technology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Mantle (geology), Isotopic composition, chemistry, 0202 electrical engineering, electronic engineering, information engineering, engineering, General Earth and Planetary Sciences, Omphacite, Eclogite, Biogeosciences, Helium, Geology, 0105 earth and related environmental sciences, Terrane

Abstract

Helium isotopic compositions are considered to be ideal tracers to identify whether mantle materials have been added to crustal rocks or fluids. In this paper, we present the helium isotopic compositions of the Songduo eclogites in the Lhasa terrane, Tibet. We found that garnet and omphacite in the eclogites have different helium retention characteristics. The 4He content of most omphacite grains are about 10-20 times of that of garnet, suggesting that omphacite has a higher ability to capture 4He than garnet. Similarly, there is about 10-20 times difference in 3He content between omphacite and garnet in the same eclogite samples. The 3He/4He ratios of garnet and omphacite in these rocks range from 0.27 to 0.60 Ra (relative to the modern air 3He/4He ratio, 1.4×10-6). These ratios are within the range of both mantle-and crust-derived helium, suggesting mixed sources. The Songduo eclogites have much higher 3 He/4He ratios than those observed in the Dabie eclogites of eastern China. Such high ratios are typically thought to be associated with deep mantle sources. We cautiously conclude that deep mantle materials might have been involved during the formation of the Songduo eclogites.

Published

2019

43. Metamorphic Evolution and Tectonic Implications of the Granulitized Eclogites from the Luliangshan Terrane in the North Qaidam Ultrahigh Pressure Metamorphic Belt, NW China: New Constraints from Phase Equilibrium Modeling

Author

Jianxin Zhang, Zenglong Lu, Guisheng Zhou, Xiaohong Mao, Xia Teng, and Yunshuai Li

Subjects

020209 energy, Metamorphic rock, Geochemistry, Metamorphism, 02 engineering and technology, engineering.material, 010502 geochemistry & geophysics, Granulite, 01 natural sciences, 0202 electrical engineering, electronic engineering, information engineering, engineering, General Earth and Planetary Sciences, Plagioclase, Omphacite, Eclogite, Geology, Amphibole, Metamorphic facies, 0105 earth and related environmental sciences

Abstract

The granulitized eclogites from the Luliangshan terrane of the North Qaidam UHP metamorphic belt occur as lenses within pelitic gneisses and orthogneisses. Combined petrologic data and phase equilibrium modeling indicate a multi-stage metamorphic history of the granulitized eclogites: (1) an earlier eclogite facies metamorphism (P>18.5 kbar, T> 830 °C) is deduced from omphacite relics in the matrix and rare omphacite inclusions within garnet. The possible assemblage is garnet+omphacite+rutile+ quartz; (2) the early stage of high pressure granulite facies assemblages (garnet+clinopyroxene+ plagioclase+rutile+quartz+liquid) developed in the early decompression process has a P-T regime of 17.5 kbar and 852–858 °C, constrained by plagioclase and clinopyroxene inclusions in garnet. The late stage of high pressure granulite assemblages (garnet+clinopyroxene+amphibole+plagioclase+rutile+quartz+liquid) records an isothermal decompression process with the pressure successively declining from 17.5 to 14.7 kbar and to 11.3 kbar at 858 °C; (3) the later medium pressure granulite facies assemblage (garnet+ orthopyroxene+ clinopyroxene+amphibole+plagioclase+ilmenite+liquid+quartz) indicates a drop in pressure and rise in temperature at P-T conditions of 7.6–7.7 kbar and 878–883 °C; (4) retrogressive amphibolite facies stage, which is represented by amphibole+plagioclase kelyphitic rims around garnet, formed under conditions of

Published

2019

44. Metamorphism and Oceanic Crust Exhumation—Constrained by the Jilang Eclogite and Meta-Quartzite from the Sumdo (U)HP Metamorphic Belt

Author

Cong Zhang, Tian Qiu, Yang Li, Tingting Shen, Xiaoyu Liu, and Jingsui Yang

Subjects

Lawsonite, 020209 energy, Metamorphic rock, Geochemistry, 02 engineering and technology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Phengite, Symplectite, 0202 electrical engineering, electronic engineering, information engineering, engineering, General Earth and Planetary Sciences, Omphacite, Eclogite, Metamorphic facies, Geology, 0105 earth and related environmental sciences, Terrane

Abstract

The Sumdo eclogite-bearing (U)HP metamorphic belt extends over 100 km across the middle part of the Lhasa terrane in southern Tibet, which forms a Permian-Triassic oceanic subduction zone between the south and the north Lhasa sub-terranes, leading to the reinterpretation of the tectonic evolution of the Lhasa terrane in the Tibetan-Himalayan orogeny. Previous studies show that there are significant differences in temperature and pressure conditions of the eclogites in four areas, e.g., Sumdo, Xindaduo, Bailang and Jilang areas. Studying the peak metamorphic P-T conditions and path of eclogite in the Sumdo belt is of great significance to reveal the subduction and exhumation mechanism of Paleo-Tethys Ocean in the Lhasa terrane. In this contribution, eclogite in the Jilang area of the Sumdo belt is chosen as an example to study its metamorphic evolution. The mineral assemblage of the eclogite is garnet, omphacite, phengite, hornblende, epidote, quartz and minor biotite. Garnet has a "dirty" core with abundant inclusions such as epidote, amphibole, plagioclase and a "clear" rim with few inclusions of omphacite and phengite. From the core to the rim, pyrope content in garnet increases while grossular content decreases, showing typical growth zoning. The rim of garnet is wrapped by the pargasite+plagioclase corona, showing amphibolite facies overprint during retrogression. Three stages of metamorphism are inferred as (1) prograde stage, represented by the core of garnet and mineral inclusions therein; (2) peak stage, represented by the garnet rim, omphacite, lawsonite, phengite, and quartz; (3) retrograde stage characterized by decomposition of lawsonite to zoisite, followed by symplectite of omphacite and corona rimmed garnet. A P-T pseudosection contoured with isopleths of grossular and pyrope contents in garnet is used to constrain the near peak P-T condition at 2.85 GPa, 575 C. In general, the Jilang eclogite shows a clockwise P-T path with a near isothermal decompression process during exhumation. Combined with the age peaks of 583, 911, and 1 134 Ma from the detrital zircons of the country metaquartzite, a continental margin material involving exhumation process at shallow depth after the subduction channel exhumation is inferred for the Jilang eclogite and may further indicate that the subduction direction of the Sumdo eclogite belt is from north to south.

Published

2019

45. Metamorphism and fluid evolution of the Sumdo eclogite, Tibet: Constraints from mineral chemistry, fluid inclusions and oxygen isotopes

Author

Lingsen Zeng, Yilin Xiao, Haihao Guo, Yangyang Wang, Alfons M. van den Kerkhof, and Haiyang Liu

Subjects

Grossular, 010504 meteorology & atmospheric sciences, Metamorphic rock, Geochemistry, Metamorphism, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Petrography, 13. Climate action, visual_art, engineering, visual_art.visual_art_medium, Fluid inclusions, Eclogite, Omphacite, Metamorphic facies, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

The Sumdo metamorphic belt, located in the Lhasa terrane of Tibet, is a key area for unraveling the Paleo-Tethys evolution. In order to identify the fluid evolution in oceanic subduction zones, eclogite from the Sumdo metamorphic belt, has been investigated in a combined study of petrography, mineral chemistry, fluid inclusions and oxygen isotopes. On the basis of petrography and mineral chemistry, two kinds of garnet were distinguished. The core part of Grt-I shows increasing grossular content and contains prograde mineral inclusions, suggesting that it grew during prograde metamorphism, while the rim of Grt-I shows varying grossular and pyrope contents, representing subsequent overgrowth. Grt-II displays a composition comparable with the outermost part of Grt-I, indicating that Grt-II grew at the peak or initial retrograde stage. Garnet trace element zoning patterns and P-T estimates suggest that the Sumdo eclogite experienced a heating stage during an initial exhumation after the peak metamorphic event. Based on textural criteria and host minerals, three types of fluid inclusions were distinguished: Type-I are primary NaCl dominated intermediate to high-salinity (10–22 wt% NaCl) fluid inclusions hosted by omphacite, which were most likely released during dehydration of the subducting oceanic crust and reflect the composition of eclogite-facies fluids; Type-II are defined as primary low-salinity (1–6 wt% NaCl) fluid inclusions hosted by epidote/clinozoisite, representing fluids that evolved towards low-salinity during uplift; Type-III are secondary low-salinity (0–7 wt% NaCl) fluid inclusions hosted by matrix quartz (i.e., minerals other than the mineral inclusions) and rarely by omphacite and must have formed at a very late stage. In addition, the eclogite displays δ18O values (δ18O = +5.0 to +8.9‰) similar to its protolith, low-temperature altered oceanic crust (δ18O = +4.9 to +12.7‰). The equilibrium oxygen isotope fractionations (Δ18OQtz-Min) between quartz and garnet/omphacite suggest isotopic equilibrium and a closed fluid system during eclogite facies metamorphism. Our data indicate that the Sumdo eclogite experienced “hot” exhumation, during which large amounts of fluids were released by dehydration. Fluids in the Sumdo eclogite were typically aqueous fluids of varying salinities and now preserved as fluid inclusions in HP metamorphic minerals. In comparison with continental subduction zones, we confirm previous conclusion that the fluid regime in oceanic subduction zones is relatively simple (i.e. mainly NaCl bearing brines) with seawater-altered slabs as the dominant source.

Published

2019

46. High‐Pressure Single‐Crystal Elasticity and Thermal Equation of State of Omphacite and Their Implications for the Seismic Properties of Eclogite in the Earth's Interior

Author

Caroline E. Pierotti, Zhiyuan Ren, Dongzhou Zhang, Ming Hao, and Jin S. Zhang

Subjects

Materials science, Thermodynamics, State (functional analysis), engineering.material, Geophysics, Space and Planetary Science, Geochemistry and Petrology, High pressure, Earth and Planetary Sciences (miscellaneous), engineering, Omphacite, Eclogite, Elasticity (economics), Anisotropy, Single crystal, Earth (classical element)

Published

2019

47. Inefficient high-temperature metamorphism in orthogneiss

Author

Nathan R. Daczko, Sandra Piazolo, Timothy Chapman, and Geoffrey L. Clarke

Subjects

010504 meteorology & atmospheric sciences, Metamorphic rock, Geochemistry, Metamorphism, engineering.material, 010502 geochemistry & geophysics, Granulite, 01 natural sciences, Igneous rock, Geophysics, Geochemistry and Petrology, engineering, Paragenesis, Eclogite, Omphacite, Protolith, 0105 earth and related environmental sciences

Abstract

A novel method utilizing crystallographic orientation and mineral chemistry data, based on large-scale electron backscatter diffraction (EBSD) and microbeam analysis, quantifies the proportion of relict igneous and neoblastic minerals forming variably deformed high-grade orthogneiss. The Cretaceous orthogneiss from Fiordland, New Zealand, comprises intermediate omphacite granulite interlayered with basic eclogite, which was metamorphosed and deformed at T ≈ 850 °C and P ≈ 1.8 GPa after protolith cooling. Detailed mapping of microstructural and physiochemical relations in two strain profiles through subtly distinct intermediate protoliths indicates that up to 32% of the orthogneiss mineralogy is igneous, with the remainder being metamorphic. Domains dominated by igneous minerals occur preferentially in strain shadows to eclogite pods. Distinct metamorphic stages can be identified by texture and chemistry and were at least partially controlled by strain magnitude. At the grain-scale, the coupling of metamorphism and crystal plastic deformation appears to have permitted efficient transformation of an originally igneous assemblage. The effective distinction between igneous and metamorphic paragenesis and their links to deformation history enables greater clarity in interpretations of the makeup of the crust and their causal influence on lithospheric scale processes.

Published

2019

48. Rare peak and ubiquitous post-peak zircon in eclogite: Constraints for the timing of UHP and HP metamorphism in Erzgebirge, Germany

Author

Thomas M. Will, Xian-Hua Li, Xiao-Xiao Ling, Esther Schmädicke, and Qiu-Li Li

Subjects

Isochron, Felsic, 010504 meteorology & atmospheric sciences, Geochemistry, Metamorphism, Geology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Igneous rock, Symplectite, Geochemistry and Petrology, engineering, Omphacite, Eclogite, 0105 earth and related environmental sciences, Zircon

Abstract

Erzgebirge eclogite occurs in three high-pressure (HP) units, including one UHP unit (Unit 1). Each sample investigated contains either magmatic or metamorphic zircon but never both. This is in contrast to many literature examples of eclogite with more than one generation of zircon. We infer that metamorphic zircon formed at the expense of a magmatic precursor, and that the process either went to completion (consuming all magmatic zircon) or did not occur at all. Metamorphic zircon is only present in UHP eclogite and one HP eclogite from Unit 2. Another sample from Unit 2 and one from Unit 3, which experienced the lowest metamorphic PT conditions of all samples, contain only magmatic zircon. The U-Pb SIMS age of c. 540 Ma of igneous zircon, being somewhat younger than average Hf model ages (i.e., 567 and 591 Ma), is attributed to crystallization in the basaltic or gabbroic precursor that formed from a juvenile mantle source. The time of peak metamorphism is recorded by only two zircons from UHP eclogite giving ages of 360.5 ± 5.4 Ma and 359.7 ± 5.3 Ma that well agree with a previous three-point Sm-Nd isochron of 360 ± 7 Ma. All other grains gave younger ages, mainly between 340 and 330 Ma but covering a range of c. 350–315 Ma, which is attributed to retrogression at amphibolite-facies conditions. We infer (i) that this post-eclogitic zircon replaced peak-metamorphic grains (only in UHP eclogite) as well as magmatic zircon and (ii) that peak-metamorphic zircon did not form in non-UHP eclogite. Growth of peak and post-peak zircon was governed by fluid and/or melt. The latter is related to decompressional melting in felsic host rocks (and possibly also to late-orogenic granitic magmatism). Fluid is either of external origin (melt-derived or from dehydration reactions in subducting footwall units) or due to decompressional release of internal fluid (molecular water from fluid inclusions or structural water in omphacite and garnet). The new and former age data can best be reconciled with a two-stage exhumation process. Initial, buoyancy-driven exhumation was fast and terminated as the HP/UHP slices reached lower crustal levels where the rocks presumably rested for 10–20 million years, followed by slow exhumation associated with gravitational collapse of the Variscan orogen. The majority of metamorphic zircon (with ages of 340–330 Ma) grew at lower crustal levels, where the rocks presumably rested for 10–20 million years, and other grains (younger than 330 Ma) during the final, slow exhumation that partly overlapped with the time of granitic magmatism.

Published

2018

49. Seismic Visibility of Eclogite in the Earth’s Upper Mantle—Implications From High Pressure‐Temperature Single‐Crystal Elastic Properties of Omphacite

Author

Qin Wang, Wen-Yi Zhou, Jin S. Zhang, and Ming Hao

Subjects

Visibility (geometry), engineering.material, Geophysics, Space and Planetary Science, Geochemistry and Petrology, High pressure, Earth and Planetary Sciences (miscellaneous), engineering, Omphacite, Eclogite, Elasticity (economics), Anisotropy, Petrology, Single crystal, Geology, Earth (classical element)

Published

2021

50. Omphacite paradox in mantle peridotites.

Author

Shur, M.Yu. and Perchuk, A.L.

Subjects

REGOLITH, PERIDOTITE, ECLOGITE, AMPHIBOLITES, PHLOGOPITE, ORTHOPYROXENE, KIMBERLITE

Abstract

Omphacite is a typomorphic mineral of eclogites, which is inappropriate to mineral assemblages of peridotites. Nevertheless, findings of this mineral in inclusions in peridotitic diamonds can be considered as indirect evidence for the existence of this paradoxical mineral assemblage. In this paper we present experimental results on the interaction between carbonate-bearing amphibolite and olivine that model processes operated at the crust–mantle boundary in subduction zones. The experiments demonstrate growth of omphacite at the interface between acid melt and peridotite media at 2.9 GPa and 850–900 °C; the omphacite coexists either with garnet and orthopyroxene or with phlogopite. The synthetic omphacite is exclusively of reactive-magmatic origin and does not form in metasomatic way. Findings of omphacite inclusions in peridotitic diamonds and in some pyroxenites from kimberlites are discussed in scope of the obtained experimental data. [ABSTRACT FROM AUTHOR]

Published

2015