Mantle Potential Temperature Estimates of Basalt from the East Taiwan Ophiolite

Shellnutt, J. Gregory; Hsieh, Robert B.J.

doi:10.3319/tao.2016.05.24.01(tt)

Cited by 4 publications

(6 citation statements)

References 40 publications

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“…The crystallization temperatures based on the primary melt compositions of the low-Ti basalt in this study are between 1,300 and 1,450 • C (oxidizing models = 1,315-1,410 • C; reducing models = 1,330-1,435 • C) and similar to the estimates using Al-in-olivine for komatiites and basalts from Gorgona, Baffin Island, SE Greenland and Madagascar but much higher than estimates (<1,300 • C) for mid-ocean ridge basalt (Coogan et al, 2014;Shellnutt and Hsieh, 2016). The Al-in-olivine thermometer method produced a range of crystallization temperatures from 1,188 ± 56 • C to 1,440 ± 63 • C (low-Ti picrites = 1249 ± 58 • C−1356 ± 61 • C) for all compositions of the ELIP picrites (Xu and Liu, 2016).…”

Section: Thermal and Compositional Estimates Of The Emeishan Primary supporting

confidence: 74%

“…The olivine-liquid T P (vertical black lines) estimates for low-Ti Emeishan picrite using melt fractions of (F) of ≈0.35 and ≈0.2 (Tao et al, 2015). Crystallization and mantle potential temperature estimates (blue circles) of mid-ocean ridge (MOR) basalt are also shown (Shellnutt and Hsieh, 2016).…”

Section: Thermal and Compositional Estimates Of The Emeishan Primary mentioning

confidence: 99%

“…Ultramafic volcanic rocks are commonly found in the lower volcanic sequences of flood basalt provinces, generated by high degrees of melting under high mantle temperatures, and provide a clear record of the thermal regime (Herzberg and O'Hara, 2002;Kamenetsky et al, 2012). In cases where ultramafic volcanic rocks are unexposed or unidentified, mafic volcanic (basalt) rocks may also be able to help constrain the thermal regime, providing that they have not experienced pyroxene or plagioclase fractionation or were not derived from a volatilerich and/or pyroxenite source (Coltice et al, 2007;Herzberg et al, 2007;Herzberg and Gazel, 2009;Hole, 2015;Whalen et al, 2015;Shellnutt and Hsieh, 2016;Yeh and Shellnutt, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Mantle Potential Temperature Estimates and Primary Melt Compositions of the Low-Ti Emeishan Flood Basalt

Shellnutt

Pham

2018

Front. Earth Sci.

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The Late Permian Emeishan large igneous province (ELIP) is considered to be one of the best examples of a mantle plume derived large igneous province. One of the primary observations that favor a mantle plume regime is the presence of ultramafic volcanic rocks. The picrites suggest primary mantle melts erupted and that mantle potential temperatures (T P) of the ELIP were > 200 • C above ambient mantle conditions. However, the picrites may represent a mixture of liquid and cumulus olivine and pyroxene rather than primary liquids. Consequently, temperature estimates based on the picrite compositions may not be accurate. Here we calculate mantle potential temperature (T P) estimates and primary liquids compositions using PRIMELT3 for the low-Ti (Ti/Y < 500) Emeishan basalt as they represent definite liquid compositions. The calculated T P yield a range from ∼1,400 to ∼1,550 • C, which is consistent with variability across a mantle plume axis. The primary melt compositions of the basalts are mostly picritic. The results of this study indicate that the Emeishan basalt was produced by a high temperature regime and that a few of the ultramafic volcanic rocks may be indicative of primary liquids.

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Section: Thermal and Compositional Estimates Of The Emeishan Primary supporting

confidence: 74%

Section: Thermal and Compositional Estimates Of The Emeishan Primary mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Mantle Potential Temperature Estimates and Primary Melt Compositions of the Low-Ti Emeishan Flood Basalt

Shellnutt

Pham

2018

Front. Earth Sci.

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“…Petrological and geochemical studies suggest the ETO was formed in a deep-sea slow-spreading ridge (Jahn 1986;Chung and Sun 1992;Hsieh et al 2017). However, whether the ETO was generated from a ridge on the South China Sea (e.g., Chung and Sun 1992;Shellnutt and Hsieh 2016;Hsieh et al 2017) or the Philippine Sea Plate (e.g., Chang et al 2009;Huang et al 2018) remained an open question. The recipe is the crystallization age of the ophiolitic rocks since the neighboring South China Sea and the Philippine Sea Plate were formed at different time intervals (Oligo-Miocene, and Eocene or Cretaceous, respectively; Deschamps et al 2000;Sibuet et al 2002;Yeh et al 2010).…”

Section: The Lichi Mélangementioning

confidence: 99%

“…Therefore, the ophiolitic rocks in the Lichi Mélange might have been also originated from the South China Sea lithosphere considering the age of mid-ocean ridge basalt (Hsieh et al 2017) eruption. Prolonged magmatic activity in the mush zone in a slow-spreading ridge environment (Chung and Sun 1992;Shellnutt and Hsieh 2016) might be responsible for the slightly older gabbro crystallization ages from sample JW-02, and not consistent with upper-plate suprasubduction processes (Huang et al 2018). So far no Luzon forearc basement rocks have been documented via geochronological or petrological means within the Lichi Mélange, indicating that although the Lichi Mélange was formed during forearc basin closure through basement underthrusting/ subduction, the basement rocks (except arc volcanics) were not mixed with overlying sediments.…”

Section: Origins Of the Ophiolitic Rocks In The Yuli Belt And The Licmentioning

confidence: 99%

Ages of ophiolitic rocks along plate suture in Taiwan orogen: Fate of the South China Sea from subduction to collision

Lo¹,

Chen²,

Lo³

et al. 2020

Terr. Atmos. Ocean. Sci.

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Ophiolite-bearing belts mark convergent plate suture zones and are central in reconstructing plate configuration and structures of mountain belts. The active Taiwan mountain belt, product of ongoing convergence between the Eurasian and Philippine Sea plates, has dismembered ophiolitic rocks exposed on both sides of the Longitudinal Valley suture: blueschist blocks in schistose Yuli Belt to the west, and the Eastern Taiwan Ophiolite (ETO) in the unmetamorphosed Lichi Mélange to the east. How these ophiolitic materials correlate with the consumed South China Sea and Luzon forearc oceanic lithospheres between the colliding Chinese continental margin and the Luzon Arc remained speculative. We present zircon U-Pb age results from both ophiolitic rocks in the Yuli Belt and the ETO to pinpoint the formation ages of respective oceanic crusts, and 40 Ar/ 39 Ar dates to unravel the tectonothermal history. The zircon U-Pb ages of ~15 Ma for all analyzed samples indicate a common South China Sea origin for ophiolitic materials across the plate suture, since oceanic crust of the Philippine Sea Plate near Taiwan is either Eocene or older. The 40 Ar/ 39 Ar ages of Yuli meta-ophiolitic rocks might suggest blueschist metamorphic overprint at ~9 Ma. The 40 Ar/ 39 Ar results are generally identical to zircon U-Pb ages for the ETO rocks, concurrent to their olistostromal origin in the forearc basin after being tectonically transported from the trench interface to the eastern retrowedge within the Hengchun accretionary prism. A working tectonic model for the Taiwan arc-continent collision is put forward with emphasis on the fate of the South China Sea during the mountain building processes.

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Strain Partitioning and Exhumation in Oblique Taiwan Collision: Role of Rift Architecture and Plate Kinematics

et al. 2020

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Taiwan is an archetypal example of continental accretionary wedges. Yet the generally poor knowledge of three-dimensional strain distribution over time and role of architecture of the rifted margin shed doubt on the cylindrical two-dimensional kinematic models of Taiwan collision. Here we provide new field-based constraints on strain distribution, new Raman Spectroscopy on Carbonaceous Materials temperatures and apply mica-chlorite multiequilibrium approach to determine pressure-temperature in the Central Range of Taiwan. We identify three distinct structural domains that define zones of orthogonal shortening in the western Backbone Range and left-lateral ductile shearing overprinted by left-lateral transtensional brittle deformation in eastern Central Range. Field surveys show the lack of nappe stacking in the Backbone Range. Combining new temperature estimates with existing thermochronological constraints we emphasize that western Taiwan mostly inherited preorogenic thermal history. We show that metamorphic peak conditions of 5-6 kbar and 330-400°C in the eastern Backbone Range and HP rocks of the Yuli Belt exhumed along the P-T paths related to transcurrent deformation. We propose a three-dimensional kinematic model of Taiwan accounting for the oblique motion of the Philippine Sea Plate relative to the plate boundary and the reactivation of a NS striking transform fault in the South China Sea rifted margin. Recent and ongoing strain partitioning in the Taiwan accretionary wedge is reflected by the coexistence of brittle left-lateral shear, oblique extension, and contraction. Our results have impact on orogen-based plate kinematic reconstructions that consider two-dimensional kinematic evolution of orogens.

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Mantle Potential Temperature Estimates of Basalt from the East Taiwan Ophiolite

Cited by 4 publications

References 40 publications

Mantle Potential Temperature Estimates and Primary Melt Compositions of the Low-Ti Emeishan Flood Basalt

Mantle Potential Temperature Estimates and Primary Melt Compositions of the Low-Ti Emeishan Flood Basalt

Ages of ophiolitic rocks along plate suture in Taiwan orogen: Fate of the South China Sea from subduction to collision

Strain Partitioning and Exhumation in Oblique Taiwan Collision: Role of Rift Architecture and Plate Kinematics

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