Your search keyword '"Liu, Yanguang"' showing total 4 results

1. Sedimentary Record of Glacial Impacts and Melt Water Discharge off the East Siberian Continental Margin, Arctic Ocean.

Author

Zhao, Song, Liu, Yanguang, Dong, Linsen, Shi, Xuefa, Polyak, Leonid, Zou, Xinqing, Wang, Weiguo, and Wu, Dong

Subjects

MELTWATER, OXYGEN isotopes, PLEISTOCENE Epoch, FRESH water

Abstract

The East Siberian Continental Margin is a major constituent of the western Arctic Ocean, ideal for studying the evolutionary history of the Siberian Ice Sheet (SIS) based on its unique geographical location and medium‐depth bathymetry. For this study, the sedimentary core CHINARE‐ARC07‐E25 (E25) was analyzed, revealing nearly continuous stable oxygen isotope and mineralogy records that preserved scenarios of the SIS development. Lithostratigraphic evidence suggests that the stratigraphic range of E25 extends to marine isotope stage (MIS) 7. Stable oxygen isotope analysis reveals multiple strong, light‐oxygen isotopic excursions since the penultimate glacial, accompanied by multiple patterns of ice rafted debris content and mineralogy. Based on these isotopic events, the potential factors causing the excursions and the provenance of drainage were evaluated. It was found that the excursion events recorded in pink‐white carbonate detritus layers could be related to the retreat of the Laurentide Ice Sheet. The most typical events, occurring during the deglaciation periods of MIS6/5e and MIS4/3 to early MIS3, were characterized by involving a mixture of two or more sources, and could be used to trace the activity of the SIS, which has been ignored in previous studies. Findings of this study are expected to advance the understanding of SIS contribution to the western Arctic Ocean basin development, which is important for interpreting global climate change behavior of similar ice sheets in the Arctic region. Plain Language Summary: Several large ice sheets in the Arctic Ocean formed during the Late Pleistocene, which had a profound impact on the global climate. Recently published geophysical evidence shows that huge glaciers have repeatedly developed on the East Siberian Continental Margin, and they were proposed to have comprised the Siberian Ice Sheet (SIS). However, the contribution of the SIS has been ignored in previous studies of the western Arctic Ocean. In this study, a sediment core was collected from the medium‐depth bathymetry Mendeleev Ridge to ensure a sample that was not directly affected by glaciation erosion. Repeated freshwater events, identified based on significant light‐oxygen isotopic excursion and coarse fraction content peaks, were evaluated and analyzed for mineralogical composition to reflect their provenances. The results show that the freshwater events recorded in the Mendeleev Ridge sediments show strong and mixed‐provenance inputs, while an increase in plagioclase, illite, and chlorite during deglaciation may indicate the contribution of the SIS. This not only suggests that the SIS was a potential source of freshwater of the Arctic Ocean, but also provides evidence of its earlier expansion (MIS6), in addition to new perspectives for evaluating the ice sheet activities and corresponding paleoenvironmental changes. Key Points: Stable oxygen isotope and mineralogy were studied in sediment cores from the Mendeleev Ridge, Arctic Ocean, covering ∼220 kaIsotopic and mineralogical records could trace sources of glacial input during the late Quaternary, mainly from Eurasia and North AmericaThe Siberian ice sheet is determined to be a significant and independent potential freshwater provenance of the western Arctic Ocean [ABSTRACT FROM AUTHOR]

Published

2022

2. Isotopic Fingerprints of Ice‐Rafted Debris Offer New Constraints on Middle to Late Quaternary Arctic Circulation and Glacial History.

Author

Dong, Linsen, Polyak, Leonid, Liu, Yanguang, Shi, Xuefa, Zhang, Jun, and Huang, Yuanhui

Subjects

ISOTOPES, LEAD isotopes, ICE sheets, GLACIATION, SEA ice

Abstract

For the first time, ice‐rafted debris provenance related to the Quaternary glacial discharge and circulation was constrained using radiogenic Sr, Nd, and Pb isotopes from a sedimentary record (Core BN05) from the central Arctic Ocean. The record is composed of glacial/interglacial intervals estimated to span ~0.5 Ma (Marine Isotope Stages [MIS] 1–14). Nd versus Sr isotope data show two end member groups, further elaborated using Pb isotopes. Glacial data mostly point at North American sources with unradiogenic εNd and high 87Sr/86Sr values, including detrital carbonate (dolomite) layers originating from Paleozoic rocks eroded by the Laurentide Ice Sheet. The opposite end member group including estimated MIS6 and MIS4 samples indicates the Siberian Large Igneous Province eroded by the Eurasian Ice Sheet as the major source, possibly with additional inputs from the East Siberian Ice Sheet. The limited evidence for Siberian Ice Sheet provenance may result from the predominant distribution of this glaciation on the continental shelf providing weak, fine‐grained sediments. Glacial‐time western Arctic circulation inferred from isotopic data is mostly similar to the modern Beaufort Gyre but was more streamlined toward the Fram Strait during some glacial events. Interglacial/major interstadial, presumably sea ice transported sediments, shows a mixture of North American and Siberian sources, consistent with historically observed variations in the Transpolar Drift versus Beaufort Gyre circulation. Isotope pattern in major interglacials (e.g., MIS5e, MIS11, and MIS 13) resembles the recent trend of increased sediment ice transport from the East Siberian/Chukchi Sea, possibly in relation to the ongoing Arctic warming. Key Points: Radiogenic Sr, Nd, and Pb isotopes of ice‐rafted debris >63 μm are studied in sediment core from Canada Basin, Arctic Ocean, covering ~0.5 MaMain glacial provenance is identified as Siberian Large Igneous Province in MIS4 and MIS6 and North American sources in MIS2 and MIS8–MIS14Interglacial sediments show a mixture of North American and Siberian sources mostly consistent with modern‐type Arctic Ocean circulation [ABSTRACT FROM AUTHOR]

Published

2020

3. A Thick Negative Polarity Anomaly in a Sediment Core From the Central Arctic Ocean: Geomagnetic Excursion Versus Reversal.

Author

Liu, Jianxing, Shi, Xuefa, Liu, Yanguang, Liu, Qingsong, Liu, Yan, Zhang, Qiang, Ge, Shulan, and Li, Jinhua

Subjects

MARINE sediments, GEOMAGNETISM, QUATERNARY Period, SEDIMENTATION & deposition

Abstract

There are two distinctly different views on Quaternary sedimentation rates in the central Arctic Ocean, namely, that they were on cm/kyr or on mm/kyr scales, largely as a result of divergent interpretations of magnetic reversal stratigraphy. This study provides new evidence to help resolve this controversy in the form of an almost 1‐m‐thick negative polarity interval located at ~1.15 m below the seafloor in a 4.15‐m‐long sediment core from the Lomonosov Ridge, central Arctic Ocean. This thick polarity anomaly was first revealed through alternating field demagnetization of natural remanent magnetization on u‐channel samples. It was subsequently confirmed to be an authentic signal of a syndepositional geomagnetic field by integrating detailed rock magnetic studies, transmission electron microscopy with energy‐dispersive X‐ray spectroscopy analyses of magnetic extracts, and both alternating field and thermal demagnetization of discrete paleomagnetic samples. Here we conclude that it is more reasonable to interpret the reversed interval as a record of the Matuyama Chron rather than a Brunhes‐aged excursion, which yields mean sedimentation rates of ~1.5 mm/kyr and ~0.5 mm/kyr in the Brunhes and Matuyama Chrons, respectively. These estimates are remarkably lower than assumed in most recent studies, but in good agreement with both previous magnetostratigraphic and recent geochemical studies relative to the decay of Be and U‐series isotopes, which might indicate "sediment‐starved" environments at least in some parts of this region. Overall, our results not only imply that chronostratigraphy in the central Arctic Ocean remains open to debate but also warrant further investigations in this microfossil‐barren region. Key Points: The effects of self‐reversed CRM of diagenetic titanomaghemite are probably only regional in the central Arctic sedimentsThe "reversal" interpretation supports "sediment starved" environments at least in some regions of the central Arctic OceanThe chronostratigraphy and usability of paleomagnetism in the central Arctic Ocean remains open to debate and further studies are warranted [ABSTRACT FROM AUTHOR]

Published

2019

4. Distribution and sources of polycyclic aromatic hydrocarbons in surface sediments from the Bering Sea and western Arctic Ocean.

Author

Zhao, Mengwei, Wang, Weiguo, Liu, Yanguang, Dong, Linsen, Jiao, Liping, Hu, Limin, and Fan, Dejiang

Subjects

POLYCYCLIC aromatic hydrocarbons & the environment, MARINE sediments, OCEAN temperature, MARINE ecology

Abstract

To analyze the distribution and sources of polycyclic aromatic hydrocarbons (PAHs) and evaluate their potential ecological risks, the concentrations of 16 PAHs were measured in 43 surface sediment samples from the Bering Sea and western Arctic Ocean. Total PAH (tPAH) concentrations ranged from 36.95 to 150.21 ng/g (dry weight). In descending order, the surface sediment tPAH concentrations were as follows: Canada Basin > northern Chukchi Sea > Chukchi Basin > southern Chukchi Sea > Aleutian Basin > Makarov Basin > Bering Sea shelf. The Bering Sea and western Arctic Ocean mainly received PAHs of pyrogenic origin due to pollution caused by the incomplete combustion of fossil fuels. The concentrations of PAHs in the sediments of the study areas did not exceed effects range low (ERL) values. [ABSTRACT FROM AUTHOR]

Published

2016