High-temperature diffusion of major elements may obscure the records of early and peak metamorphic stages in granulites,while trace elements are more likely to preserve these records due to their lower diffusion rates...High-temperature diffusion of major elements may obscure the records of early and peak metamorphic stages in granulites,while trace elements are more likely to preserve these records due to their lower diffusion rates.Thus,using calibrated REE-based thermobarometers has proved essential for reconstructing these key stages,drawing considerable attention and application from scholars.However,the precision of these thermobarometers depends on including both major and trace elements from coexisting minerals to define the correlation coefficients(A,B,and D) among mineral pairs,indicating that the elemental composition of these pairs can affect the results.Our study examines the mafic-ultramafic granulites in the southern granulite terrain,India,employing integrated methods such as petrography,mineral chemistry,phase equilibrium modeling,and REE-based thermobarometers.We aim to determine their metamorphic conditions and evolutionary history and to identify potential challenges in using REE-based thermobarometers.The garnet,clinopyroxene,and orthopyroxene in the mafic-ultramafic granulite samples display homogeneous compositional profiles,with pronounced Fe-Mg diffusion zones at the interfaces between garnet and clinopyroxene.Conversely,the profiles of trace elements within garnet and clinopyroxene are better preserved.Investigations into Fe-Mg exchange and randomly selected mineral pairs significantly influence the accuracy of REE-based thermobarometers.Fe-Mg exchange can increase in coefficient A,while decreasing coefficient B for light rare earth elements(LREEs) and increasing it for heavy rare earth elements(HREEs),ultimately resulting in overestimations when calculating REE-based thermobarometers.For example,selecting major compositions with an Ex(=(X_(Mg)^(C)-X_(Mg)^(0))/X_(Mg)^(0)×100%;where X_(Mg)^(C) is the value after Fe-Mg exchange,X_(Mg)^(0) is the value before Fe-Mg exchange;X_(Mg)=Mg/(Fe^(2+)+Mg)) value of ~10 for calculation using the REE-in-Grt-Cpx thermobarometer will result in pressures and temperatures being ~10 kbar and 30-40℃ higher than the true values.Random pairing,such as selections based solely on the core or rim of minerals with changes in trace elements,can severely impact the distribution coefficient D,resulting in substantial discrepancies in thermobarometric calculations and potentially producing anomalous results.Thus,to minimize the impact of these factors,it is necessary to first analyze the profiles of major and trace elements in coexisting minerals before applying the REE-based thermobarometers to evaluate the P-T conditions of granulites.Based on this analysis,maj or element compositions less affected by Fe-Mg exchange(such as avoiding the selection of major compositions at the boundaries of minerals) and in relative equilibrium in trace element compositions among coexisting minerals(same growth periods) should be selected for pairing.Furthermore,integrating additional methods should also be considered when applying the REE-based thermobarometers,to prevent the misinterpretation of the P-T conditions obtained.展开更多
The provenance and tectonic implications of Late Paleozoic sedimentary rocks in the South Qinling Belt(SQB) provide important clues for understanding the timing and mechanism of the collision between North China Block...The provenance and tectonic implications of Late Paleozoic sedimentary rocks in the South Qinling Belt(SQB) provide important clues for understanding the timing and mechanism of the collision between North China Block(NCB) and South China Block(SCB).Here we report new LAICP-MS zircon U-Pb ages and geochemical composition of metasedimentary rocks from the Foping area in the SQB.The results indicate that the depositional age of the Wenquan Group can be limited to the Early Devonian by the youngest U-Pb age of 398 Ma,whereas those of the quartz schist from the Changjiaoba Group could be constrained after the Carboniferous by the youngest206Pb/238U peak age of 306 Ma.Therefore,much of the previously-assumed “Neoarchaean or Paleoproterozoic” strata,including the Wenquan and Changjiaoba groups,were actually deposited in the Late Paleozoic.Based on analysis and comparison of the detrital zircon ages of the Devonian tectonic units in the SQB,we found that most prominent peak ages of detrital zircons from metasedimentary rocks in the Foping area shared similar characteristics with others.They mainly derived from the North Qinling Belt and South Qinling Belt-Yangtze Block,with a minor source probably from the North China Block,implying that the Shangdan Ocean between NCB and SCB had closed in the Early Devonian.Combined with regional geological background and geochemical data,we inferred that these Devonian strata formed in the foreland basin after the amalgamation of the North China Block and South China Block.展开更多
基金supported by the National Natural Science Foundation of China (Grants Nos. 41890831 and 42302223)the State Key Laboratory of Continental Dynamics (Grant No. SKLCD-04)。
文摘High-temperature diffusion of major elements may obscure the records of early and peak metamorphic stages in granulites,while trace elements are more likely to preserve these records due to their lower diffusion rates.Thus,using calibrated REE-based thermobarometers has proved essential for reconstructing these key stages,drawing considerable attention and application from scholars.However,the precision of these thermobarometers depends on including both major and trace elements from coexisting minerals to define the correlation coefficients(A,B,and D) among mineral pairs,indicating that the elemental composition of these pairs can affect the results.Our study examines the mafic-ultramafic granulites in the southern granulite terrain,India,employing integrated methods such as petrography,mineral chemistry,phase equilibrium modeling,and REE-based thermobarometers.We aim to determine their metamorphic conditions and evolutionary history and to identify potential challenges in using REE-based thermobarometers.The garnet,clinopyroxene,and orthopyroxene in the mafic-ultramafic granulite samples display homogeneous compositional profiles,with pronounced Fe-Mg diffusion zones at the interfaces between garnet and clinopyroxene.Conversely,the profiles of trace elements within garnet and clinopyroxene are better preserved.Investigations into Fe-Mg exchange and randomly selected mineral pairs significantly influence the accuracy of REE-based thermobarometers.Fe-Mg exchange can increase in coefficient A,while decreasing coefficient B for light rare earth elements(LREEs) and increasing it for heavy rare earth elements(HREEs),ultimately resulting in overestimations when calculating REE-based thermobarometers.For example,selecting major compositions with an Ex(=(X_(Mg)^(C)-X_(Mg)^(0))/X_(Mg)^(0)×100%;where X_(Mg)^(C) is the value after Fe-Mg exchange,X_(Mg)^(0) is the value before Fe-Mg exchange;X_(Mg)=Mg/(Fe^(2+)+Mg)) value of ~10 for calculation using the REE-in-Grt-Cpx thermobarometer will result in pressures and temperatures being ~10 kbar and 30-40℃ higher than the true values.Random pairing,such as selections based solely on the core or rim of minerals with changes in trace elements,can severely impact the distribution coefficient D,resulting in substantial discrepancies in thermobarometric calculations and potentially producing anomalous results.Thus,to minimize the impact of these factors,it is necessary to first analyze the profiles of major and trace elements in coexisting minerals before applying the REE-based thermobarometers to evaluate the P-T conditions of granulites.Based on this analysis,maj or element compositions less affected by Fe-Mg exchange(such as avoiding the selection of major compositions at the boundaries of minerals) and in relative equilibrium in trace element compositions among coexisting minerals(same growth periods) should be selected for pairing.Furthermore,integrating additional methods should also be considered when applying the REE-based thermobarometers,to prevent the misinterpretation of the P-T conditions obtained.
基金jointly supported by the National Natural Science Foundation of China (No.41890831)China Postdoctoral Science Foundation (No.2022M712571)MOST Special Fund from the State Key Laboratory of Continental Dynamics,Northwest University。
文摘The provenance and tectonic implications of Late Paleozoic sedimentary rocks in the South Qinling Belt(SQB) provide important clues for understanding the timing and mechanism of the collision between North China Block(NCB) and South China Block(SCB).Here we report new LAICP-MS zircon U-Pb ages and geochemical composition of metasedimentary rocks from the Foping area in the SQB.The results indicate that the depositional age of the Wenquan Group can be limited to the Early Devonian by the youngest U-Pb age of 398 Ma,whereas those of the quartz schist from the Changjiaoba Group could be constrained after the Carboniferous by the youngest206Pb/238U peak age of 306 Ma.Therefore,much of the previously-assumed “Neoarchaean or Paleoproterozoic” strata,including the Wenquan and Changjiaoba groups,were actually deposited in the Late Paleozoic.Based on analysis and comparison of the detrital zircon ages of the Devonian tectonic units in the SQB,we found that most prominent peak ages of detrital zircons from metasedimentary rocks in the Foping area shared similar characteristics with others.They mainly derived from the North Qinling Belt and South Qinling Belt-Yangtze Block,with a minor source probably from the North China Block,implying that the Shangdan Ocean between NCB and SCB had closed in the Early Devonian.Combined with regional geological background and geochemical data,we inferred that these Devonian strata formed in the foreland basin after the amalgamation of the North China Block and South China Block.
