<i>P</i>–<i>T</i> evolution and episodic zircon growth in barroisite eclogites of the Lanterman Range, northern Victoria Land, Antarctica

Kim, Tae‐Hwan; Kim, Yoonsup; Cho, Moonsup; Lee, Jong Ik

doi:10.1111/jmg.12474

Cited by 19 publications

(27 citation statements)

References 152 publications

(282 reference statements)

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“…Mineral inclusions in and core-to-rim compositional zoning of garnet are robust recorders of prograde metamorphism for low-and medium-temperature HP eclogites, which have been well documented by previous studies (e.g. Kim et al, 2019;Wang et al, 2018;Wei, Yang, et al, 2009). The garnet in the Tongbai eclogites is characterized by a weakly bell-shaped X sps (X represents the proportion of the garnet end-member) distribution, which is interpreted as petrographic evidence for the growth zoning of garnet (Spear, 1995).…”

Section: T a B L E 4 Mineral Assemblages Of Eclogites In Tongbai Orog...supporting

confidence: 76%

Construction of P–T–t paths for eclogite in the Tongbai orogen by combining phase equilibria modelling with zircon inclusion composition

Zhang

Gao

Zheng

2021

Journal Metamorphic Geology

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The interpretation of metamorphic ages for zircon domains in eclogite remains challenging because of the uncertainties in interpreting their rare earth element (REE) patterns and mineral inclusions. This has seriously hindered the construction of robust pressure (P)–temperature (T)–time (t) paths for eclogites from collisional orogens. In this study, a composite approach is used to obtain a reliable P–T path for eclogite from the Tongbai orogen and quantitatively attribute zircon U–Pb ages to specific P–T intervals. An integrated study using isochemical phase diagram section (pseudosection) modelling, multi‐equilibrium thermobarometry, and the Zr‐in‐rutile thermometry with petrographic observations indicates that the target eclogite experienced multistage metamorphic evolution. The evolution is characterized by a clockwise P–T path with compressional heating for peak eclogite facies metamorphism at 588 ± 20°C and 26.7 ± 2.8 kbar and two stages of isothermal decompression from an early stage of amphibole eclogite facies metamorphism at 15–10 kbar to a late stage of amphibolite facies metamorphism at pressures of <10 kbar. Metamorphic zircon domains in eclogite and quartz vein show relatively flat patterns of heavy REE without notable Eu anomalies but different cathodoluminescence responses and middle REE (MREE) contents. This indicates their growth in different stages of eclogite facies metamorphism, which are categorized into two groups. The first group is composed of bright rims or homogenous grains that are characterized by low MREE contents, suggesting the existence of abundant amphibole during the metamorphism. The compositional isopleths of amphibole inclusions indicate that this group of zircon domains would form by hydration during crustal exhumation to amphibole eclogite facies at 240 ± 2 Ma. The second group consists of dark sector mantles and shows high MREE contents, indicating the prograde to peak metamorphism with significant decomposition of amphibole or lawsonite during crustal subduction to eclogite facies at 245 ± 2 Ma. Therefore, the combination of the isopleth thermobarometry of mineral inclusions with the Zr‐in‐rutile thermometry and the zircon REE partitioning is an effective means to link the metamorphic P–T conditions to the ages of metamorphic zircons in the different stages of collisional orogeny.

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Section: T a B L E 4 Mineral Assemblages Of Eclogites In Tongbai Orog...supporting

confidence: 76%

Construction of P–T–t paths for eclogite in the Tongbai orogen by combining phase equilibria modelling with zircon inclusion composition

Zhang

Gao

Zheng

2021

Journal Metamorphic Geology

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“…10). These are supported by the stratigraphic position of the group and existence of a coesitebearing eclogite (~498 Ma) in western margin of the Bowers Terrane (Federico et al, 2009;Rossetti et al, 2011;Kim et al, 2019). The upper Furongian to Lower Ordovician Leap Year Group consists mostly of continental facies which was envisaged as a result of deposition in the tectonic inversion of the basin, caused by possible continental collision and rapid exhumation reflected by occurrence of the retrogressed amphibolite facies (490 to 486 Ma) (Di Vincenzo et al, 1997;Federico et al, 2006Federico et al, , 2009Rocchi et al, 2011;Rossetti et al, 2011).…”

Section: Geodynamic Controls On Development and Demise Of The Lost Camentioning

confidence: 86%

Middle Cambrian slope deposits in northern Victoria Land, Antarctica: Fingerprinting small carbonate platforms dominated by grainy carbonates and microbial reefs

et al. 2021

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“…Regarding barroisite, an open question is its P–T environment of formation. There are two views about the metamorphic stage at which barroisite forms: as part of a prograde and even peak metamorphic assemblage coexisting with the eclogite phases garnet and omphacite (Chatterjee & Ghose, 2010; Di Vincenzo, Horton, & Palmeri, 2016; Gómez‐Pugnaire et al., 1997; Kim et al., 2019; Weller et al., 2015; Yokoyama, Brothers, & Black, 1986) versus formation at the epidote–amphibolite facies as the product of later decompression (Bucher, 2005; Caby et al., 2008; Kabir & Takasu, 2016; Li, Klemd, Gao, & Meyer, 2012; Lombardo, Rolfo, & Compagnoni, 2000; Miyamoto, Enami, Tsuboi, & Yokoyama, 2007; Okay & Whitney, 2010). Singh, Pant, Saikia, and Kundu (2013) made a systematic investigation of the role of amphiboles during the metamorphism of UHP rock in the Tso Morari Complex, northwest Himalayas.…”

Section: Discussionmentioning

confidence: 99%

“…This observation is consistent with both previous petrological analysis T A B L E 6 Experimental conditions and results on reaction 4 using winchite as the starting amphibole of natural samples and experimental studies of metabasaltic rocks. Barroisite is a common amphibole in eclogites in warm subduction zones, including those from the Nerkau Complex in Northern Urals (Gómez-Pugnaire, Karsten, & Sánchez-Vizcaíno, 1997), the Sanbagawa metamorphic belt in southwest Japan (Weller, Wallis, Aoya, & Nagaya, 2015), Akeyazi metamorphic terrane of Western Tianshan in China (Li, Klemd, Gao, & John, 2016) and the Lanterman Range of northern Victoria Land in Antarctica (Kim, Kim, Cho, & Lee, 2019). Experimental work at the stability field of blueschist and eclogite, starting with natural basaltic rock or glass, also showed a compositional change of amphibole from sodic glaucophane to sodic-calcic barroisite (Forneris & Holloway, 2004;Liu et al, 1996;Molina & Poli, 2000).…”

Section: Compositional Change In Amphibolementioning

confidence: 99%

Experimental study of metamorphic reactions and dehydration processes at the blueschist–eclogite transition during warm subduction

Cheng

Jenkins

2020

Journal Metamorphic Geology

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The transition between blueschist and eclogite plays an important role in subduction zones via dehydration and densification processes in descending oceanic slabs. There are a number of previous petrological studies describing potential mineral reactions taking place at the transition. An experimental determination of such reactions could help constrain the pressure–temperature conditions of the transition as well as the processes of dehydration. However, previous experimental contributions have focused on the stability of spontaneously formed hydrous minerals in basaltic compositions rather than on reactions among already formed blueschist facies minerals. Therefore, this study conducted three groups of experiments to explore the metamorphic reactions among blueschist facies minerals at conditions corresponding to warm subduction, where faster reaction rates are possible on the time scale of laboratory experiments. The first group of experiments was to establish experimental reversals of the reaction glaucophane+paragonite to jadeite+pyrope+quartz+H2O over the range of 2.2–3.5 GPa and 650–820°C. This reaction has long been treated as key to the blueschist–eclogite transition. However, only the growth of glaucophane+paragonite was observed at the intersectional stability field of both paragonite and jadeite+quartz, confirming thermodynamic calculations that the reaction is not stable in the system Na2O–MgO–Al2O3–SiO2–H2O. The second set of experiments involved unreversed experiments using glaucophane+zoisite ±quartz in low‐Fe and Ca‐rich systems and were run at 1.8–2.4 GPa and 600–780°C. These produced omphacite+paragonite/kyanite+H2O accompanied by compositional shifts in the sodium amphibole, glaucophane, towards sodium–calcium amphiboles such as winchite (☐(CaNa)(Mg4Al)Si8O22(OH)2) and barroisite (☐(CaNa)(Mg3Al2)(AlSi7)O22(OH)2). This suggests that a two‐step dehydration occurs, first involving the breakdown of glaucophane+zoisite towards a paragonite‐bearing assemblage, then the breakdown of paragonite to release H2O. It also indicates that sodium–calcium amphibole can coexist with eclogite phases, thereby extending the thermal stability of amphibole to greater subduction zone depths. The third set of experiments was an experimental investigation at 2.0–2.4 GPa and 630–850°C involving a high‐Fe (Fe#=Fetotal/(Fetotal+Mg)≈0.36) natural glaucophane, synthetic paragonite and their eclogite‐forming reaction products. The results indicated that garnet and omphacite grew over most of these pressure–temperature conditions, which demonstrates the importance of Fe‐rich glaucophane in forming the key eclogite assemblage of garnet+omphacite, even under warm subduction zone conditions. Based on the experiments of this study, reaction between glaucophane+zoisite is instrumental in controlling dehydration processes at the blueschist–eclogite transition during warm subduction.

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P–T evolution and episodic zircon growth in barroisite eclogites of the Lanterman Range, northern Victoria Land, Antarctica

Cited by 19 publications

References 152 publications

Construction of P–T–t paths for eclogite in the Tongbai orogen by combining phase equilibria modelling with zircon inclusion composition

Construction of P–T–t paths for eclogite in the Tongbai orogen by combining phase equilibria modelling with zircon inclusion composition

Middle Cambrian slope deposits in northern Victoria Land, Antarctica: Fingerprinting small carbonate platforms dominated by grainy carbonates and microbial reefs

Experimental study of metamorphic reactions and dehydration processes at the blueschist–eclogite transition during warm subduction

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