The Late Paleozoic marked Earth’s most recent icehouse–greenhouse transition,providing valuable insights into future climate and environmental changes.Although the aridification of the North China Craton(NCC)during ...The Late Paleozoic marked Earth’s most recent icehouse–greenhouse transition,providing valuable insights into future climate and environmental changes.Although the aridification of the North China Craton(NCC)during the Late Paleozoic is well established,its pattern and causes remain unclear.Here,we identify four aridification intervals from the late Gzhelian to Lopingian by analyzing continuous records of elemental climate proxies(MgO/CaO,Sr/Cu),a volcanism proxy(Hg/TOC),and spore–pollen assemblages.Interval I(∼303–295 Ma),during which the NCC was located at low paleolatitudes,was characterized by humid conditions and a predominance of ferns,associated with weak volcanism.Interval II(∼295–286 Ma)was subhumid,with increasing gymnosperm presence,and significant climate fluctuations linked to volcanism.CO_(2) emissions from the Tarim LIP and Panjal Traps drove aridification from the late Asselian to late Artinskian,contributing to the decline of the Late Paleozoic Ice Age.As a result,aridification in the NCC lagged behind that of Pangea.Interval III(∼286–280.98 Ma)marked the transition to subarid conditions and the onset of dominance by gymnosperms,associated with a rapid northward drift of the NCC and an increase in atmosphericρCO_(2).Interval IV(∼259.51–251.902 Ma),separated from the underlying Interval III by a major regional unconformity(∼280.98–259.51),coincided with global aridification and intensified volcanism.These findings highlight the significant influences of both tectonic plate motion and volcanism on the climate evolution of the NCC,with shifts in the dominant controlling factors through time.This study provides new insights into the distinct trajectories of global and regional climate dynamics.展开更多
Zircon U-Pb ages and geochemical analytical results are presented for the volcanic rocks of the Naozhigou, Ergulazi, and Sidaogou Formations in the Linjiang area, southeastern Jilin Province to constrain the nature of...Zircon U-Pb ages and geochemical analytical results are presented for the volcanic rocks of the Naozhigou, Ergulazi, and Sidaogou Formations in the Linjiang area, southeastern Jilin Province to constrain the nature of magma source and their tectonic settings. The Naozhigou Formation is composed mainly of andesite and rhyolite and its weighted mean ^206pb/^238U age for 13 zircon grains is 222±1 Ma. The Ergulazi Formation consists of basaltic andesite, basaltic trachyandesite, and andesite, and six grains give a weighted mean ^206pb/^238U age of 131±4 Ma. The Sidaogou Formation consists mainly of trachyandesite and rhyolite, and six zircon grains yield a weighted mean ^206pb/^238U age of 113±4 Ma. The volcanic rocks have SIO2=60.24%-77.46%, MGO=0.36%-1.29% (Mg#=0.32-0.40) for the Naozhigou Formation, SIO2=51.60%-59.32%, MGO=3.70%-5.54% (Mg#=0.50-0.60) for the Ergulazi Formation, and SIO2=58.28%-76.32%, MGO=0.07%-1.20% (Mg#=0.14-0.46) for the Sidaogou Formation. The trace element analytical results indicate that these volcanic rocks are characterized by enrichment in light rare earth elements (LREEs) and large ion lithophile elements (LILEs), relative depletion in heavy rare earth elements (HREEs) and high field strength elements (HFSEs, Nb, Ta, and Ti), and negative Eu anomalies. Compared with the primitive mantle, the Mesozoic volcanic rocks in the Linjiang area have relatively high initial ^87Sr/^86Sr ratios (0.7053-0.7083) and low εNd(t) values (-8.38 to -2.43), and display an EMⅡ trend. The late Triassic magma for the Naozhigou Formation could be derived from partial melting of a newly accretional crust with the minor involvement of the North China Craton basement and formed under an extensional environment after the collision of the Yangtze Craton and the North China Craton. The Early Cretaceous volcanic rocks for the Ergulazi and Sidaogou Formations could be formed under the tectonic setting of an active continental margin related to the westward subduction of the Izanagi plate.展开更多
The tectonic setting of podiform chromitite formation still remains highly debated. There is a close correlation between tectonic settings and oxygen fugacity(fO2)(e.g., Ballhaus, 1993;Dare et al., 2009;Parkinson and ...The tectonic setting of podiform chromitite formation still remains highly debated. There is a close correlation between tectonic settings and oxygen fugacity(fO2)(e.g., Ballhaus, 1993;Dare et al., 2009;Parkinson and Arculus, 1999). Here we present results of fO2 of chromites determined by M?ssbauer spectroscopy from both the Luobusha and Dazhuqu areas along Yarlung Zangbo suture zone, Southern Tibet. The fO2 values(-1.02~0.04 log units against the FMQ buffer) and Cr#(22~54%) in chromites from lherzolites and harzburgites of both areas are similar to those of abyssal peridotites, indicating that they may be residues after partial melting at spreading centers. However, both dunite envelopes and chromitites from Luobusha have high fO2 values(0.04~2.25 log units) and Cr#(73~84%), showing an affinity to boninitic melts, and thus form in a suprasubduction zone. Dazhuqu dunites show diverse fO2 values(-0.22~2.19 log units) and Cr#(22~82%), indicating that they form in distinct settings. Chromitites and chromite dunites from Dazhuqu have low fO2 values(-0.3~0.71 log units) and Cr#(16~63%), both of which are similar to those of MORB-like basalts, inferring that they form in an extensional setting. Both high-Cr and high-Al chromitites from other typical podiform chromite ore deposits, such as Kempirsai, Oman, and Albania ophiolites, also show high fO2 values(e.g., Chashchukhin and Votyakov, 2009;Melcher et al., 1997;Quintiliani et al., 2006;Rollinson and Adetunji, 2015), while the distribution-limited small chromitites and chromite dunites from Dazhuqu exhibit low fO2 values. The phenomenon infers that the suprasubduction zone is more beneficial to the formation of podiform chromitites.展开更多
基金financially supported by CNPC Innovation Found(2021DQ02-1003)the Fundamental Research Funds for the Central Universities(Ph.D.Top Innovative Talents Fund of CUMTB)(BBJ2025043).
文摘The Late Paleozoic marked Earth’s most recent icehouse–greenhouse transition,providing valuable insights into future climate and environmental changes.Although the aridification of the North China Craton(NCC)during the Late Paleozoic is well established,its pattern and causes remain unclear.Here,we identify four aridification intervals from the late Gzhelian to Lopingian by analyzing continuous records of elemental climate proxies(MgO/CaO,Sr/Cu),a volcanism proxy(Hg/TOC),and spore–pollen assemblages.Interval I(∼303–295 Ma),during which the NCC was located at low paleolatitudes,was characterized by humid conditions and a predominance of ferns,associated with weak volcanism.Interval II(∼295–286 Ma)was subhumid,with increasing gymnosperm presence,and significant climate fluctuations linked to volcanism.CO_(2) emissions from the Tarim LIP and Panjal Traps drove aridification from the late Asselian to late Artinskian,contributing to the decline of the Late Paleozoic Ice Age.As a result,aridification in the NCC lagged behind that of Pangea.Interval III(∼286–280.98 Ma)marked the transition to subarid conditions and the onset of dominance by gymnosperms,associated with a rapid northward drift of the NCC and an increase in atmosphericρCO_(2).Interval IV(∼259.51–251.902 Ma),separated from the underlying Interval III by a major regional unconformity(∼280.98–259.51),coincided with global aridification and intensified volcanism.These findings highlight the significant influences of both tectonic plate motion and volcanism on the climate evolution of the NCC,with shifts in the dominant controlling factors through time.This study provides new insights into the distinct trajectories of global and regional climate dynamics.
基金supported by the National Natural Science Foundation of China(Grant No.40672038).
文摘Zircon U-Pb ages and geochemical analytical results are presented for the volcanic rocks of the Naozhigou, Ergulazi, and Sidaogou Formations in the Linjiang area, southeastern Jilin Province to constrain the nature of magma source and their tectonic settings. The Naozhigou Formation is composed mainly of andesite and rhyolite and its weighted mean ^206pb/^238U age for 13 zircon grains is 222±1 Ma. The Ergulazi Formation consists of basaltic andesite, basaltic trachyandesite, and andesite, and six grains give a weighted mean ^206pb/^238U age of 131±4 Ma. The Sidaogou Formation consists mainly of trachyandesite and rhyolite, and six zircon grains yield a weighted mean ^206pb/^238U age of 113±4 Ma. The volcanic rocks have SIO2=60.24%-77.46%, MGO=0.36%-1.29% (Mg#=0.32-0.40) for the Naozhigou Formation, SIO2=51.60%-59.32%, MGO=3.70%-5.54% (Mg#=0.50-0.60) for the Ergulazi Formation, and SIO2=58.28%-76.32%, MGO=0.07%-1.20% (Mg#=0.14-0.46) for the Sidaogou Formation. The trace element analytical results indicate that these volcanic rocks are characterized by enrichment in light rare earth elements (LREEs) and large ion lithophile elements (LILEs), relative depletion in heavy rare earth elements (HREEs) and high field strength elements (HFSEs, Nb, Ta, and Ti), and negative Eu anomalies. Compared with the primitive mantle, the Mesozoic volcanic rocks in the Linjiang area have relatively high initial ^87Sr/^86Sr ratios (0.7053-0.7083) and low εNd(t) values (-8.38 to -2.43), and display an EMⅡ trend. The late Triassic magma for the Naozhigou Formation could be derived from partial melting of a newly accretional crust with the minor involvement of the North China Craton basement and formed under an extensional environment after the collision of the Yangtze Craton and the North China Craton. The Early Cretaceous volcanic rocks for the Ergulazi and Sidaogou Formations could be formed under the tectonic setting of an active continental margin related to the westward subduction of the Izanagi plate.
基金granted by the China Geological Survey(Grant No.121201102000150069)
文摘The tectonic setting of podiform chromitite formation still remains highly debated. There is a close correlation between tectonic settings and oxygen fugacity(fO2)(e.g., Ballhaus, 1993;Dare et al., 2009;Parkinson and Arculus, 1999). Here we present results of fO2 of chromites determined by M?ssbauer spectroscopy from both the Luobusha and Dazhuqu areas along Yarlung Zangbo suture zone, Southern Tibet. The fO2 values(-1.02~0.04 log units against the FMQ buffer) and Cr#(22~54%) in chromites from lherzolites and harzburgites of both areas are similar to those of abyssal peridotites, indicating that they may be residues after partial melting at spreading centers. However, both dunite envelopes and chromitites from Luobusha have high fO2 values(0.04~2.25 log units) and Cr#(73~84%), showing an affinity to boninitic melts, and thus form in a suprasubduction zone. Dazhuqu dunites show diverse fO2 values(-0.22~2.19 log units) and Cr#(22~82%), indicating that they form in distinct settings. Chromitites and chromite dunites from Dazhuqu have low fO2 values(-0.3~0.71 log units) and Cr#(16~63%), both of which are similar to those of MORB-like basalts, inferring that they form in an extensional setting. Both high-Cr and high-Al chromitites from other typical podiform chromite ore deposits, such as Kempirsai, Oman, and Albania ophiolites, also show high fO2 values(e.g., Chashchukhin and Votyakov, 2009;Melcher et al., 1997;Quintiliani et al., 2006;Rollinson and Adetunji, 2015), while the distribution-limited small chromitites and chromite dunites from Dazhuqu exhibit low fO2 values. The phenomenon infers that the suprasubduction zone is more beneficial to the formation of podiform chromitites.
