Iron and magnesium isotopic constraints on the origin of chemical heterogeneity in podiform chromitite from the Luobusa ophiolite, Tibet

Xiao, Yan; Teng, Fang‐Zhen; Su, Ben‐Xun; Hu, Yan; Zhou, Mei‐Fu; Zhu, Bin; Shi, Ruiping; Huang, Quansheng; Gong, Xinghong; He, Yongsheng

doi:10.1002/2015gc006223

Cited by 68 publications

(45 citation statements)

References 70 publications

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“…There are limited variations in the contents of Ni, Mn, and Ti in Cr-spinel ( Figure 5). In this respect, much attention should be paid to these minor elements in their application to trace geologic processes (Figure 7c), since these elements are not affected by elemental exchange and are therefore more reliable and valid than the traditional index [64]. [5].…”

Section: Inducement Of Elemental Exchangementioning

confidence: 99%

“…Elemental exchange with coexisting silicate minerals is another important factor modifying the composition of spinel [61][62][63][64][65], and is commonly induced by the variation of physical conditions [66][67][68][69]. Generally, diffusion-induced zonation is caused by the long-term exchange between crystals subjected to continuous, high subsolidus temperatures [23,[70][71][72].…”

Section: Elemental Exchange With Coexisting Silicate Mineralsmentioning

confidence: 99%

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Origin of Reverse Zoned Cr-Spinels from the Paleoproterozoic Yanmenguan Mafic–Ultramafic Complex in the North China Craton

Bai

Xiao

et al. 2018

Minerals

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Abstract:We conducted petrological and mineral chemistry investigations of Cr-spinel in ultramafic rocks of the Yanmenguan mafic-ultramafic complex in the North China Craton. The Cr-spinel grains occur as inclusions in enstatite, tschermakite, phlogopite, and olivine, or as interstitial grains among the aforementioned silicate minerals, and show concentric or asymmetrical textures. Back-scattered electron and elemental images and compositional profiles of the spinel grains indicate the presence of Cr-and Fe-rich cores and Al-and Mg-rich rims. The host silicate minerals display a decrease in Al and Mg contents accompanied by an increase in Cr and Fe away from the spinel. These textures and compositional variations suggest that subsolidus elemental exchange more likely gave rise to the compositional zonation, resulting in the transfer of Al and Mg from the silicate minerals to the spinel. The Mn, Ni, and Ti contents in spinel and the major elements of olivine-hosted spinel are relatively stable during subsolidus elemental diffusion and thus are more reliable tracers of primary high-temperature processes. The temperature estimates reveal that the subsolidus diffusion might have occurred at 600-720 • C, which could be linked to the regional metamorphic event.

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Section: Inducement Of Elemental Exchangementioning

confidence: 99%

Section: Elemental Exchange With Coexisting Silicate Mineralsmentioning

confidence: 99%

Origin of Reverse Zoned Cr-Spinels from the Paleoproterozoic Yanmenguan Mafic–Ultramafic Complex in the North China Craton

Bai

Xiao

et al. 2018

Minerals

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“…Kinetic fractionation induced by sub-solidus Fe-Mg interdiffusion between olivine and chromite has been well documented in studies of layered intrusions and ophiolites, during which Mg in chromite and Fe in olivine exchange with each other [11,28,38,39]. Since light isotopes diffuse faster than their heavy counterparts [40], this process will lead to higher Mg# and lower d 26 Mg in olivine with a corresponding increase in d 26 Mg of chromite, which agrees with the results of olivine-chromite pairs from Tibetan ophiolites [11]. This is opposite, however, to the positive correlation between Mg# and d 26 Mg observed in the olivine from the Xiadong dunite (Fig.…”

Section: Large Chromite-olivine Mg Isotope Fractionationmentioning

confidence: 97%

“…Magnesium isotopic variation has been increasingly reported in igneous rocks and was attributed to various mechanisms. Source heterogeneity is a main factor controlling Mg isotopic variations in volcanic rocks [1][2][3][4][5][6]; silicate-carbonatite liquid immiscibility and carbonatite magma differentiation can result in significant Mg isotope fractionation [7], whereas diffusive Mg-Fe exchange with melt or chromite produces large Mg isotope fractionation in olivine [8][9][10][11]. Although Mg isotope fractionation during the differentiation of granitic and basaltic magma is limited [3,[12][13][14][15], magma differentiation involving chromite can potentially produce large Mg isotope fractionation.…”

Section: Introductionmentioning

confidence: 99%

Chromite-induced magnesium isotope fractionation during mafic magma differentiation

Teng

et al. 2017

Science Bulletin

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a b s t r a c tTo better understand the mechanism of Mg isotopic variation in magma systems, here we report high precision Mg isotopic data of 17 bulk rock samples including dunite, clinopyroxenite, hornblendite and gabbro and 10 pairs of dunite-hosted olivine and chromite separates from the well-characterized Alaskan-type Xiadong intrusion in NW China, which formed by continuous and high degree of lithological differentiation from mafic magmas. Chromite separates have highly variable d 26 Mg values from À0.10‰ to 0.40‰, and are consistently heavier than coexisting olivine separates (À0.39‰ to À0.15‰). Both mineral d 26 Mg values and the degrees of inter-mineral fractionation are well correlated with geochemical indicators of magma differentiation, indicating that these inter-sample and inter-mineral Mg isotope fractionations are caused by magma evolution. The d 26 Mg values range from À0.20‰ to À0.02‰ in the dunite, À0.43‰ in the clinopyroxenite, À0.43‰ to À0.28‰ in the hornblendite, 0.18‰ in the chromite-bearing hornblendite, and À0.56‰ to À0.16‰ in the gabbro. The Mg isotopic variations in different types of rocks are closely related to fractional crystallization and accumulation of different proportions of oxides vs. silicates. Chromite crystallization and accumulation is the most important factor in controlling Mg isotope fractionation during the formation of the Xiadong intrusion. Compared to basaltic and granitic magmas, differentiation of the Alaskan-type intrusions occurs at a relatively high oxygen fugacity, which favors chromite crystallization and consequently significant Mg isotope fractionations at both mineral and whole-rock scales. Therefore, Mg isotope systematics can be used to trace the degree of magma differentiation and related-mineralization.

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“…These studies include: major and trace elemental and/or isotopic compositions of different textural chromitites and their host peridotites (e.g., [1][2][3][4][5][6][7][8]), and unusual ultrahigh-pressure (UHP), highly reduced and crustally derived minerals found either in situ or as separates in the chromitites and peridotites (e.g., [9][10][11][12][13][14][15][16][17][18][19][20][21]). [42]), and the distribution of magmatism on the Lhasa terrane (modified from Chung et al [43]).…”

Section: Introductionmentioning

confidence: 99%

Timing of Secondary Hydrothermal Alteration of the Luobusa Chromitites Constrained by Ar/Ar Dating of Chrome Chlorites

Guo

et al. 2018

Minerals

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Chrome chlorites are usually found as secondary phases formed by hydrothermal alteration of chromite deposits and associated mafic/ultramafic rocks. Here, we report the 40 Ar/ 39 Ar age of chrome chlorites separated from the Luobusa massive chromitites which have undergone secondary alteration by CO 2 -rich hydrothermal fluids. The dating results reveal that the intermediate heating steps (from 4 to 10) of sample L7 generate an age plateau of 29.88 ± 0.42 Ma (MSWD = 0.12, plateau 39 Ar = 74.6%), and the plateau data points define a concordant inverse isochron age of 30.15 ± 1.05 Ma (MSWD = 0.08, initial 40 Ar/ 36 Ar = 295.8 ± 9.7). The Ar release pattern shows no evidence of later degassing or inherited radiogenic component indicated by an atmospheric intercept, thus representing the age of the hydrothermal activity. Based on the agreement of this hydrothermal age with the~30 Ma adakitic plutons exposed in nearby regions (the Zedong area, tens of kilometers west Luobusa) and the extensive late Oligocene plutonism distributed along the southeastern Gangdese magmatic belt, it is suggested that the hydrothermal fluids are likely related to the~30 Ma magmatism. The hydrothermal fluid circulation could be launched either by remote plutons (such as the Sangri granodiorite, the nearest~30 Ma pluton west Luobusa) or by a similar coeval pluton in the local Luobusa area (inferred, not found or reported so far). Our results provide important clues for when the listwanites in Luobusa were formed.

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Iron and magnesium isotopic constraints on the origin of chemical heterogeneity in podiform chromitite from the Luobusa ophiolite, Tibet

Cited by 68 publications

References 70 publications

Origin of Reverse Zoned Cr-Spinels from the Paleoproterozoic Yanmenguan Mafic–Ultramafic Complex in the North China Craton

Origin of Reverse Zoned Cr-Spinels from the Paleoproterozoic Yanmenguan Mafic–Ultramafic Complex in the North China Craton

Chromite-induced magnesium isotope fractionation during mafic magma differentiation

Timing of Secondary Hydrothermal Alteration of the Luobusa Chromitites Constrained by Ar/Ar Dating of Chrome Chlorites

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