发表论文

第一/通讯作者文章

[17] Zhang, Y.-Q., Wei, W.^*, Zhang, Z., Hu, X., Yu, H.-M., Huang, F., 2024. Rubidium isotope measurements of low-Rb geological materials by MC-ICP-MS. Geostandards and Geoanalytical Research https://doi.org/10.1111/ggr.12593.

[16] Yin, H., Wei, W.^*, Jing, Z.^*, Zou, C., Xu, W., Hao, J., Huang, F., 2024. Cd isotope evidence for elevated productivity in the Middle Triassic Ordos Basin. Geochemical Perspectives Letters 33, 13–19.

[15] Wei, W.^#*, Dong, L.-H.^#, Xiao, S., Lin, Y.-B., Xu, L., Wei, G.-Y., Wang, W., Tian, L.-L., Wei, H.-Z., Huang, F.^*, 2024. Seawater barium and sulfide removal improved marine habitability for the Cambrian Explosion of early animals. National Science Review 11(8), nwae237.

[14] 卫炜^*, 隋佩珊, 陈婷婷, 黄方, 2024. 新元古代氧化事件驱动海洋Ba循环变化. 高校地质学报 30(3), 288–296.

[13] Dong, L.-H., Wei, W.^*, Xu, L., Lin, Y.-B., Liu, Z.-R., Pan, S., Jing, Z., Huang, F., 2024. Vanadium isotope evidence for seawater contribution  to V enrichment/mineralization in early Cambrian metalliferous black shales. Science Bulletin 69(8), 1006–1010.

[12] Tian, L.-L., Wei, W.^*, Dong, L.-H., Pan, S., Jing, Z., Huang, F., 2023. Diagenetic effect on barium isotope compositions of barites in the lower Cambrian successions. Chemical Geology 635, 121631.

[11] Wei, W.^*, Chen, X., Ling, H.-F., Wu, F., Dong, L.-H., Pan, S., Jing, Z., Huang, F., 2023. Vanadium isotope evidence for widespread marine oxygenation from the late Ediacaran to early Cambrian. Earth and Planetary Science Letters 602, 117942.

[10] Dong, L.-H., Wei, W.^*, Yu, C.-L., Hou, Z.-H., Zeng, Z., Chen, T., Huang, F., 2021. Determination of vanadium isotope compositions in carbonates using an Fe coprecipitation method and MC-ICP-MS. Analytical Chemistry 93(19), 7172–7179.

[9] Wei, W.^*, Zeng, Z., Shen, J, Tian, L.-L., Wei, G.-Y., Ling, H.-F., Huang, F.^*, 2021. Dramatic changes in the carbonate-hosted barium isotopic compositions in the Ediacaran Yangtze Platform. Geochimica et Cosmochimica Acta 299, 113–129.

[8] Wei, W.^*, Frei, R., Klaebe, R., Tang, D., Wei, G.-Y., Li, D., Tian, L.-L., Huang, F., Ling, H.-F.^*, 2021. A transient swing to higher oxygen levels in the atmosphere and oceans at ~1.4 Ga. Precambrian Research 354, 106058.

[7] 王相力, 卫炜^*, 2020. 铬稳定同位素地球化学. 地学前缘 27(3), 78–103.

[6] Wei, W.^*, Klaebe, R., Ling, H.-F.^*, Huang, F., Frei, R., 2020. Biogeochemical cycle of chromium isotopes at the modern Earth's surface and its applications as a paleo-environment proxy. Chemical Geology 541, 119570.

[5] Wei, W., Frei, R., Gilleaudeau, G.J., Li, D., Wei, G.-Y., Huang, F., Ling, H.-F.^*, 2020. Variations of redox conditions in the atmosphere and Yangtze Platform during the Ediacaran-Cambrian transition: Constraints from Cr isotopes and Ce anomalies. Palaeogeography, Palaeoclimatology, Palaeoecology 543, 109598.

[4] Wei, W., Frei, R., Klaebe, R., Li, D., Wei, G.-Y., Ling, H.-F.^*, 2018. Redox condition in the Nanhua Basin during the waning of the Sturtian glaciation: A chromium-isotope perspective. Precambrian Research 319,198–210.

[3] Wei, W., Frei, R., Chen, T., Klaebe, R., Wei, G.-Y., Li, D., Ling, H.-F.*, 2018. Marine ferromanganese oxide: A potentially important sink of light chromium isotopes? Chemical Geology 495, 90–103.

[2] Wei, W., Frei, R., Gilleaudeau, G., Li, D., Wei, G.-Y., Chen, X., Ling, H.-F.^*, 2018. Oxygenation variations in the atmosphere and shallow seawaters of the Yangtze Platform during the Ediacaran Period: Clues from Cr-isotope and Ce-anomaly in carbonates. Precambrian Research 313, 78–90.

[1] Wei, W., Wang, D.^*, Li, D.^*, Ling, H., Chen, X., Wei, G., Zhang, F., Zhu, X., Yan, B., 2016. The marine redox change and nitrogen cycle in the Early Cryogenian interglacial time: Evidence from nitrogen isotopes and Mo contents of the basal Datangpo Formation, northeastern Guizhou, South China. Journal of Earth Science 27(2), 233–241.

合作作者文章

[19] Fan, H.^*, Zhang, H., Wei, W., Hiatt, E.E., Ward, J.F., Wen, H., 2024. Phosphorus flux during the Ediacaran: Rooted in continental weathering or pelagic upwelling? Earth and Planetary Science Letters 646, 118975.

[18] Cheng, M., Wei, W., Chen, X., Wang, H., Feng, L., She, Z., Fu, Y., Algeo, T.J., Huang, F.^*, Li, C.^*, 2024. Active methane release from the early Cambrian seafloor? Clues from Ba isotopes. Palaeogeography, Palaeoclimatology, Palaeoecology 653, 112399.

[17] Yang, X.^*, Mao, J., Li, R., Huang, F., He, C., Zhao, C., Wei, W., Yang, G., Xiong, Y., Poulton, S.W., 2024. Fluctuating oxygenation and dynamic iron cycling in the late Paleoproterozoic ocean. Earth and Planetary Science Letters 626, 118554.

[16] He, Y.^*, Gao, C., Wei, W., Liu, Y., 2023. Density functional theory calculations of equilibrium Mo isotope fractionation factors among MoO_xS_4–x^2– species in the aqueous phase by the ONIOM method. ACS Earth and Space Chemistry 7, 142–155.

[15] Wei, G.-Y.^*, Wang, J., Planavsky, N.J., Zhao, M., Wei, W., Ling, H.-F., 2022. Reply to Cui: Comment on “On the origin of Shuram carbon isotope excursion in South China and its implication for Ediacaran atmospheric oxygen levels”. Precambrian Research 380, 106838.

[14] Frederiksen, J.A.^*, Wei, W., Rugen, E.J., Ling, H.-F., Frei, R., 2022. Cadmium isotopes in Late Ediacaran–Early Cambrian Yangtze Platform carbonates – Reconstruction of bioproductivity in ambient surface seawater. Palaeogeography, Palaeoclimatology, Palaeoecology 601, 111096.

[13] Wei, G.-Y.^*, Wang, J., Planavsky, N.J., Zhao, M., Bolton, E.W., Jiang, L., Asael, D., Wei, W., Ling, H.-F., 2022. On the origin of Shuram carbon isotope excursion in South China and its implication for Ediacaran atmospheric oxygen levels. Precambrian Research 375, 106673.

[12] Wang, H., Wang, D.^*, Wei, G.-Y.^*, Ling, H.-F., Struck, U., Wei, W., Yao, S., Cheng, C., Li, J., Sun, Y., Wang, M., Zhu, X.^*, 2022. Increases in marine environmental heterogeneity during the early animal innovations: Evidence from nitrogen isotopes in South China. Precambrian Research 369, 106501.

[11] Zhao, Y.^*, Wei, W., Santosh, M., Hu, J., Wei, H., Yang, J., Liu, S., Zhang, G., Yang, D., Li, S., 2022. A review of retrieving pristine rare earth element signatures from carbonates. Palaeogeography, Palaeoclimatology, Palaeoecology 586, 110765.

[10] Zhao, Y.^*, Wei, W., Li, S.^*, Yang, T., Zhang, R., Somerville, I., Santosh, M., Wei, H., Wu, J., Yang, J., Chen, W., 2021. Rare earth element geochemistry of carbonates as a proxy for deep-time environmental reconstruction. Palaeogeography, Palaeoclimatology, Palaeoecology 574, 110443.

[9] Tian, L.-L, Gong, Y.-Z., Wei, W., Kang, J.-T., Yu, H.-M., Huang, F.^*, 2020. Rapid determination of Ba isotope compositions for barites using a H₂O-extraction method and MC-ICP-MS. Journal of Analytical Atomic Spectrometry 35, 1566–1573.

[8] Wei, G.-Y.^*, Planavsky, N.J., Tarhan, L.G., He, T., Wang, D., Shields, G.A., Wei, W., Ling, H.-F.^*, 2020. Highly dynamic marine redox state through the Cambrian explosion highlighted by authigenic δ²³⁸U records. Earth and Planetary Science Letters 544, 116361.

[7] Wei, G.-Y.^*, Wei, W., Wang, D., Li, T., Yang, X., Shields, G.A., Zhang, F., Li, G., Chen, T., Yang, T., Ling, H.-F., 2020. Enhanced chemical weathering triggered an expansion of euxinic seawater in the aftermath of the Sturtian glaciation. Earth and Planetary Science Letters 539, 116244.

[6] Hohl, S.V.^*, Jiang, S.Y.^*, Viehmann, S., Wei, W., Liu, Q., Wei, H.-Z., Galer, S.J.G., 2020. Trace metal and Cd isotope systematics of the basal Datangpo Formation, Yangtze Platform (South China) indicate restrained (bio) geochemical metal cycling in Cryogenian seawater. Geosciences 10(1), 36.

[5] Wei, G.-Y.^*, Hood, A.v.S., Chen, X., Li, D., Wei, W., Wen, B., Gong, Z., Yang, T., Zhang, Z.-F., Ling, H.-F.^*, 2019. Ca and Sr isotope constraints on the formation of the Marinoan cap dolostones. Earth and Planetary Science Letters 511, 202–212.

[4] Wei, G.-Y.^*, Planavsky, N.J., Tarhan, L.G., Chen, X., Wei, W., Li, D.^*, Ling, H.-F.^*, 2018. Marine redox fluctuation as a potential trigger for the Cambrian explosion. Geology 46, 587–590.

[3] 薛玮玮, 凌洪飞^*, 李达, 卫炜, 魏广祎, 高梦奇, 2018. 修水地区下寒武统富铀地层特征及其铀富集机制研究. 高校地质学报 24, 210–221.

[2] Wei, G.-Y., Ling, H.-F.^*, Li, D., Wei, W., Wang, D., Chen, X., Zhu, X.-K., Zhang, F.-F., Yan, B., 2017. Marine redox evolution in the early Cambrian Yangtze shelf margin area: Evidence from trace elements, nitrogen and sulphur isotopes. Geological Magazine 154(6), 1344–1359.

[1] 王丹, 凌洪飞^*, 姚素平, 李达, 卫炜, 魏广祎, 2016. 湖南会同寒武纪早期有机碳同位素地层学研究. 高校地质学报 22, 274–288.

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