黃豐(中國地質大學(北京)副教授)

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黃豐,博士,副教授,博士生導師。

特長及主要研究領域:(1)Mo同位素地球化學,(2)Re-Os同位素地球化學,(3)大洋俯衝過程中板片活動過程,(4)超鉀質岩成因和源區組成特徵,(5)青藏高原和中國北部中-新生代的構造演化歷史。

主要從事青藏高原形成和中新生代構造演化,及華北-東北中生代以來的岩石和同位素地球化學研究工作,多次奔赴青藏高原及華北-東北地區開展野外地質考察工作,目前以第一作者及通訊作者身份在國際主流地學期刊GCA, GSA Bulletin, CMP, CG, G-Cube和Lithos等發表論文26篇,其中SCI論文23篇。先後主持國家自然科學基金面上項目2項,青年科學基金項目1項,國家重點研發計畫專題1項,博士後基金2項及中央高校基本科研業務費3項,參與國家重點研發計畫項目,國家自然科學基金委重大項目,重點項目和面上項目7項。

基本介紹

  • 中文名:黃豐
  • 國籍中國
  • 學位/學歷:博士
  • 職業:教師
  • 專業方向:岩石地球化學
主要成就,學術兼職,研究成果,科研項目,指導學生,

主要成就

2017年入選‘國家博士後創新人才支持計畫’
2018年首屆全國地學研究生論壇“優秀指導教師獎”
2019年科技部重點領域“青藏高原岩石圈演化與成礦創新團隊”成員
2020年一篇論文入選中國科技信息研究所“領跑者5000”中國期刊頂尖論文
2022年第三屆全國地學研究生論壇“優秀召集人獎”
2023年北京市高校優秀本科育人團隊“地球化學育人團隊”成員
2023年獲中國地質大學(北京)翟裕生青年教師獎
2024年入選中國地質大學(北京)“求真學人”

學術兼職

2023年起 《地質通報》首屆青年編委
2023年起 《礦產勘查》首屆青年編委
2024年起 《Journal of Earth Science》 青年編委
2024年起 《地球科學》 青年編委
2024年起 《成都理工大學學報(自然科學版)》 青年編委

研究成果

第一或通訊作者論文(*表示通訊作者):
(26) Tang, W.-L, Huang, F.*, Qin, Z.-W.*, Zeng, Y.-C., Xu,J.-F., Early Cretaceous magmatism archives crustal architecture of northernLhasa Terrane, central Tibetan Plateau. Lithos, 2024, doi:10.1016/j.lithos.2024.107559.
(25) Zhang, S., Huang, F.*, Xu, J., Zeng, Y., Lv, M., Su, C., Tian, Y., Tian, Y., Fan, H., Wang, S., Geodynamics and nature of the basement of the northern Lhasa Terrane: Insights from Early Cretaceous highly fractionated I-type granites in the Beila and Dongga areas, central Tibetan Plateau. Journal of Asian Earth Sciences, 2024, 264, 106078.
(24) Huang, F., Liu, Y., Xu, J.*, Liu, F., Lv, M., Zeng, Y., Zhang, Z.*, Mg-Ca-Fe isotopes of post-collisional magmatic rocks record the crust-mantle interaction processes beneath southern Tibet. Chemical Geology, 2024, 648, 121930.
(23) Tang, W., Huang, F.*, Xu, J., Zeng, Y., Liu, X., Cretaceous magmatism in the northern Lhasa Terrane: Implications for the tectonic evolution and crustal growth tempos of central Tibet. GSA Bulletin, 2024, doi: 10.1130/B36986.1.
(22) Zhang, Y.,Huang, F.*, Xu, J., Liu, H., Li, M., Zeng, Y., Hu, J., Lv, M., Liu, X., Extremely enriched lithospheric mantle–derived magmas in the central Lhasa Terrane, southern Tibet. International Geology Review, 2024, 66(4), 971-991.
(21) Yang, X., Huang, F.*, Xu, J., Liu, X., Zhang, L., Zhang, Z., Xu, B., Zhang, M., Zeng, Y., Liu, Q., Lv, M., Paleo-Pacific Plate rollback triggered Early Cretaceous intermediate-felsic magmatism in the northern North China Craton. Journal of Asian Earth Sciences, 2024, 259, 105873.
(20) Huang, F.*, Li, J., Xu, J., Chen, J., Wang, B., Hu, P., Xu, R., Zeng, Y., Zhang, L., Zhou, T., Mo isotopes archive oceanic sediments in post-orogenic lithospheric mantle. Geochimica et Cosmochimica Acta, 2023, 341, 75-89.
(19) Zhang, Z., Huang, F.*, Xu, J., Liu, X., Zhang, L., Zhang, M., Yang, X., Zeng, Y., Liu, Q., Development of Songliao Basin by Paleo-Pacific slab rollback: Evidence from Early Cretaceous rhyolites in SK2 Borehole, NE China. Geological Journal, 2023, 58(4), 1342-1365.
(18) Zhang, Y., Huang, F.*, Xu, J., Zeng, Y., Wang, B., Lv, M., Zhang, L., Li, M., Zhang, Z., Tian, Y., Liu, Q., Zhang, L., Origin of the volcanic rocks in Dianzhong Formation, central Lhasa Terrane, Tibet: Implication for the genesis of syn-collisional magmatism and Neo-Tethyan slab roll-back. International Geology Review, 2023, 65(1), 21-39.
(17) Fan, H., Zhang, M., Huang, F.*, Xu, J., Liu, X., Zeng, Y., Zhang, S., Liu, Q., Lv, M., Yu, H., Tian, Y., Zhang, L., Zhou, T., Li, Z., Zhang, Y., Subducted oceanic plateau fed crustal growth: Insights from Amdo dacites in central Tibetan Plateau. Lithos, 2022, 434-435, 106944.
(16) 張釗, 黃豐*, 許繼峰, 曾雲川, 張麗瑩, 楊旭立, 張蔓. 松科二井早白堊世早期玄武安山岩的發現及地質意義. 岩石學報, 2022, 38(6):1756-1770.
(15) Tian, Y., Huang, F.*, Xu, J., Zeng, Y., Hu, P., Yu, H., Tian, Y., Yang, Z., Yang, X., Petrogenesis and geodynamic mechanisms of the Late Cretaceous magmatic ‘flare-up’ in the southern Lhasa Terrane, Tibet. Lithos, 2022, 424-425, 106766.
(14) Yang, C., Huang, F.*, Xu, J., Zeng, Y., Liu, Q., Liu, X., Yu, H., Tian, Y., Zhang, Z., Zhang, L., Zhang, Y., Wen, Y., Crustal reworking and growth during India–Asia continental collision: Insights from early Cenozoic granitoids in the central Lhasa Terrane, Tibet. Geological Journal, 2022, 57(1), 79-98.
(13) Huang, F.*, Rooney, T. O., Xu, J.*, Zeng, Y., Magmatic record of continuous Neo-Tethyan subduction after initial India-Asia collision in the central part of southern Tibet. GSA Bulletin, 2021, 133(7-8):1600-1612.
(12) Huang, F.*, Zhang, Z., Xu, J.*, Li, X., Zeng, Y., Xu, R., Liu, X., Zhang, L., Zhang, M., Yang, C., Zhang, L., Yu, H., Yang, X. Lithospheric extension in response to subduction of the Paleo-Pacific Plate: Insights from Early Jurassic intraplate volcanic rocks in the Sk2 Borehole, Songliao Basin, NE China. Lithos, 2021, 380-381, 105871.
(11) Tian, Y., Huang, F.*, Xu, J., Wang, B., Liu, H., Zeng, Y., Liu, X., Yang, C., Yu, H., Wen, Y., Zhang, Z., Zhang, L., Zhang, Y., Neo-Tethyan slab tearing constrained by Paleocene N-MORB-like magmatism in the southern Tibet. Geological Journal, 2021, 56(1): 205-223.
(10) 黃豐*, 許繼峰, 王保弟, 曾雲川, 劉希軍, 劉函, 余紅霞, 印度-亞洲大陸碰撞過程中新特提斯洋岩石圈的命運. 地球科學, 2020, 45(8): 2785-2804.
(9) 張麗瑩, 黃豐*, 許繼峰, 曾雲川, 龔小晗, 張釗, 西藏山南地區花崗質岩石成因及其對地殼結構變化的記錄. 地球科學, 2019, 44 (6): 1822-1833.
(8) 鄒潔瓊, 余紅霞, 王保弟, 黃豐*, 曾雲川, 黃文龍, 文雅倩, 張釗, 范子塵, 談榮鈺, 南拉薩地塊中部早侏羅世仁欽則花崗閃長岩成因及其地質意義. 地球科學, 2018, 43 (8): 2795-2810.
(7) Huang, F., Zhang, Z., Xu, J., Li, X., Zeng, Y., Wang, B., Li, X., Xu, R., Fan, Z., Tian, Y., Fluid flux in the lithosphere beneath southern Tibet during Neo-Tethyan slab breakoff: Evidence from an appinite–granite suite. Lithos, 2019, 344-345: 324-338.
(6) Huang, F., Li, M., Xu, J., Zeng, Y., Chen, J., Wang, B., Yu, H., Chen, L., Zhao, P., Zhang, Z., Geodynamic transition from subduction to extension: evidence from the geochronology and geochemistry of granitoids in the Sangsang area, southern Lhasa Terrane, Tibet. International Journal of Earth Sciences, 2019, 108(5): 1663-1681.
(5) Huang, F., Xu, J., Zeng, Y., Chen, J., Wang, B., Yu, H., Chen, L., Huang, W., Tan, R., Slab breakoff of the Neo-Tethys Ocean in the Lhasa Terrane inferred from contemporaneous melting of the mantle and crust. Geochemistry, Geophysics, Geosystems, 2017, 18(11): 4074-4095.
(4) Huang, F., Xu, J.-F., Liu, Y.-S., Li, J., Chen, J.-L., Li, Xi-Yao, Re–Os isotope evidence from Mesozoic and Cenozoic basalts for secular evolution of the mantle beneath the North China Craton. Contributions to Mineralogy and Petrology, 2017, 172(5): 28.
(3) Huang, F., Xu, J.-F., Chen, J.-L., Wu, J.-B., Zeng, Y.-C., Xiong, Q.-W., Chen, X.-F., Yu, H.-X., Two Cenozoic tectonic events of N–S and E–W extension in the Lhasa Terrane: Evidence from geology and geochronology. Lithos, 2016, 245: 118-132.
(2) Huang, F., Chen, J.-L., Xu, J.-F., Wang, B.-D., Li, J., Os–Nd–Sr isotopes in Miocene ultrapotassic rocks of southern Tibet: Partial melting of a pyroxenite-bearing lithospheric mantle? Geochimica et Cosmochimica Acta, 2015, 163: 279-298.
(1) 黃豐, 許繼峰, 陳建林, 康志強, 董彥輝, 早侏羅世葉巴組與桑日群火山岩:特提斯洋俯衝過程中的陸緣弧與洋內弧? 岩石學報, 2015, 31(7): 2089-2100.(本文入選2020年“領跑者5000”中國期刊頂尖論文)
其他合作論文:
(29) Zeng, Y., Xu, J., Chen, J., Wang, B., Huang, F., Yu, H., Paleocene oceanic island basalt-type magmatism in the Lhasa Block attests to decoupled mantle-crust deformation during Indian-Asian collision. GSA Bulletin, 2024, doi: 10.1130/B37289.1.
(28) Zhang, H., Zeng, Y.-C., Chen, Q., Xu, J.-F., Li, M.-J., Huang, F., Petrogenesis of Late Cretaceous gabbronorites in southwestern Lhasa Terrane, Tibetan Plateau, China: Sediment melt-mantle interaction and magmatic flare-up in response to Neo-Tethys slab roll-back. Journal of Asian Earth Sciences, 2024, 259, 105875.
(27) Zhang, G.-K., Li, X.-W., Xu, J.-F., Wang, F.-Y., Thomas, B., Cao, G.-Y., Huang, F., Mo, X.-X., Shan, W., Li, D.-P., Dong, G.-C., Multiple magmatic processes revealed by distinct clinopyroxene populations in the magma plumbing system: a case study from a Miocene volcano in West Qinling, Central China. American Mineralogist, 2023, doi: 10.2138/am-2022-8744.
(26) Li, M.-J., Zeng, Y.-C., Tiepolo, M., Farina, F., Xu, J.-F., Huang, F., Liu, X.-J., Chen, Q., Ma, Y., Grain-scale zircon Hf isotope heterogeneity inherited from sediment metasomatized mantle: Geochemical and Nd-Hf-Pb-O isotopic constrains on Early Cretaceous intrusions in central Lhasa Terrane, Tibetan Plateau. American Mineralogist, 2023, 108(9), 1692-1707.
(25) Chai, X.-H., Zeng, Y.-C., Xu, J.-F., Li, M.-J., Huang, F., Liu, X.-J., Chen, Q., Yu, H.-X., Ren, S.-H., Crustal thickening and uplift of the northwestern Lhasa Terrane, central Tibetan Plateau: Insights from Mid-Eocene volcanic rocks in the Gerze Region. Lithos, 2023, 446-447, 107157.
(24) Zeng, Y.-C., Xu, J.-F., Chen, J.-L., Wang, B.-D., Huang, F., How and How Much Did Western Central Tibet Raise by India–Asia Collision? Geophysical Research Letters, 2022, 49, e2022GL101206.
(23) Zhang, L., Chen, Q., Huang, F., Xu, J., Liu, X., Zhang, Z., Zeng, Y., Yang, X., Zhang, Y., Zhang, M., Tian, Y., Li, M., Triassic volcanism on the North margin of the North China Craton: Insights for lithospheric modification during closure of Paleo-Asian Ocean. Lithos, 2022, 434-435, 106918.
(22) Ren, S.-H., Chen, Q., Zeng, Y.-C., Xu, J.-F., Li, M.-J., Huang, F., Lv, M., Identification of Jurassic pure sediment-derived granites in the Central Lhasa Terrane, Tibetan Plateau: Implications for continental crustal reworking during Mesozoic Tethyan subduction. Lithos, 2022, 434-435, 106927.
(21) Li, X.-Y., Li, S., Suo, Y., Huang, F., Wang, P., Luan, S., Zhou, J., High-silica rhyolites in the terminal stage of massive Cretaceous volcanism, SE China: Modified crustal sources and low-pressure magma chamber. Gondwana Research, 2022, 102, 133-150.
(20) Zeng, Y.C., Xu, J.F., Li, M.J., Chen, J.L., Wang, B.D., Huang, F., Ren, S.H., Late Eocene two-pyroxene trachydacites from the southern Qiangtang Terrane, central Tibetan Plateau: High-temperature melting of overthickened and dehydrated lower crust. Journal of Petrology, 2021, 62(11), egab080.
(19) Liu, H., Wang, B., Chen, L., Huang, F., Zeng, Y., Wang, L., Silurian intermediate–felsic complex in the Xiangtaohu area of central Qiangtang, northern Tibet: Evidence for southward subduction of the Longmuco–Shuanghu Prototethys oceanic plate. Lithos, 2021, 404: 106465.
(18) Zeng, Y.-C., Xu, J.-F., Chen, J.-L., Wang, B.-D., Huang, F., Xia, X.-P., Li, M.-J., Early Cretaceous (~138–134 Ma) forearc ophiolite and tectonomagmatic patterns in central Tibet: subduction termination and re-initiation of Meso-Tethys Ocean caused by collision of an oceanic plateau at the continental margin? Tectonics, 2021, 40(3):e2020TC006423.
(17) Zeng, Y.-C., Xu, J.-F., Huang, F., Li, M.-J., Chen, Q., Generation of the 105–100 Ma Dagze volcanic rocks in the north Lhasa Terrane by lower crustal melting at different temperature and depth: Implications for tectonic transition. GSA Bulletin, 2020, 132 (5-6):1257-1272.
(16) Ma, J., An, X., Huang, F., Li, Y., Zhang, Y., Zhu, T., Provenance of glacial marine conglomerates in the Permian Lagar Formation of southern Tibet: Evidence for affinity of the Lhasa Terrane with Australia. Journal of Asian Earth Sciences, 2020, 187: 104064.
(15) Li, M.-J., Zeng, Y.-C., Xu, J.-F., Huang, F., Chen, Q., Petrogenesis of Early Jurassic (ca. 181 Ma) dacitic-rhyolitic volcanic rocks in the Amdo ophiolite mélange, central Tibetan Plateau: Low-pressure partial melts of Bangong-Nujiang Tethys oceanic crust? Geological Journal, 2020, 55(5):3283-3296.
(14) Li, X.-Y., Li, S.-Z., Huang, F., Wang, Y.-M., Yu, S.-Y., Cao, H.-H., Xie, W.-M., Petrogenesis of high Ba–Sr plutons with high Sr/Y ratios in an intracontinental setting: evidence from Early Cretaceous Fushan monzonites, central North China Craton. Geological Magazine, 2019, 156(12): 1965-1981.
(13) Zeng, Y.-C., Xu, J.-F., Ducea, M. N., Chen, J.-L., Huang, F., Zhang, L., Initial Rifting of the Lhasa Terrane from Gondwana: Insights From the Permian (~262 Ma) Amphibole-Rich Lithospheric Mantle-Derived Yawa Basanitic Intrusions in Southern Tibet. Journal of Geophysical Research: Solid Earth, 2019, 124, 2564-2581.
(12) Zeng, Y. C., Xu, J. F., Chen, J. L., Wang, B. D., Huang, F., Yu, H. X., Chen, X. F., Zhao, P. P., Breakup of Eastern Gondwana as inferred from the Lower Cretaceous Charong Dolerites in the central Tethyan Himalaya, southern Tibet. Palaeogeography, Palaeoclimatology, Palaeoecology, 2019, 515, 70-82.
(11) Zeng, Y.-C., Chen, Q., Xu, J.-F., Chen, J.-L., Huang, F., Yu, H.-X., Zhao, P.-P., Petrogenesis and geodynamic significance of Neoproterozoic (~925?Ma) high-Fe–Ti gabbros of the RenTso ophiolite, Lhasa Terrane, central Tibet. Precambrian Research, 2018, 314, 160-169.
(10) Zeng, Y.-C., Xu, J.-F., Chen, J.-L., Wang, B.-D., Kang, Z.-Q., Huang, F., Geochronological and geochemical constraints on the origin of the Yunzhug ophiolite in the Shiquanhe-Yunzhug-Namu Tso ophiolite belt, Lhasa Terrane, Tibetan Plateau. Lithos, 2018, 300-301, 250-260.
(9) Li, X. Y., Li, S. Z., Suo, Y. H., Somerville, I. D., Huang, F., Liu, X., Wang, P. C., Han Z. X., Jin, L. J. Early Cretaceous diabases, lamprophyres and andesites-dacites in western Shandong, North China Craton: Implications for local delamination and Paleo-Pacific slab rollback. Journal of Asian Earth Sciences, 2018, 160, 426-444.
(8) Zeng, Y.-C., Chen, J.-L., Xu, J.-F., Wang, B.-D., Huang, F., Sediment melting during subduction initiation: Geochronological and geochemical evidence from the Darutso high-Mg andesites within ophiolite melange, central Tibet. Geochemistry, Geophysics, Geosystems, 2016, 17(12): 4859-4877.
(7) 陳玲, 潘磊, 黃豐, 許繼峰, 雲南普朗超大型斑岩銅礦床岩漿混合作用: 熔融包裹體證據. 大地構造與成礦學, 2018, 42(5): 880-892.
(6) 黃文龍, 許繼峰, 陳建林, 黃豐, 皮橋輝, 李政林, 滇東南箇舊白雲山鹼性岩年代學和地球化學及成因意義. 岩石礦物學雜誌, 2018, 37(5): 716-732.
(5) 劉峪菲, 許繼峰, 張兆峰, 王桂琴, 陳建林, 黃豐, 祝紅麗, 劉芳, 青藏高原拉薩地塊中西部超鉀質岩Ca-Mg同位素特徵及其地質意義. 地質學報, 2018, 92(3): 545-559.
(4) 黃文龍, 許繼峰, 陳建林, 黃豐, 曾雲川, 皮橋輝, 蔡永豐, 蔣興洲, 雲南箇舊雜岩體年代學與地球化學:岩石成因和幔源岩漿對錫成礦貢獻. 岩石學報, 2016, 32(8): 2330-2346.
(3) 熊秋偉, 陳建林, 許繼峰, 黃豐, 陳雪峰, 曾雲川, 雷鳴, 拉薩地塊南部得明頂地區葉巴組火山岩LA-ICP-MS鋯石U-Pb年齡、地球化學特徵及其成因. 地質通報, 2015, 34(9): 1645-1655.
(2) 劉希軍, 王桂琴, Castillo P R, 許繼峰, 黃豐, 余紅霞, 陳玲, 高精度鉛同位素207Pb-204Pb雙稀釋劑TIMS測試方法. 地球化學, 2013, 42(2): 103-115.
(1) 呼建雄, 陳建林, 張占武, 姚勝, 王貝, 楊文, 許繼峰, 鄔建斌, 黃豐, 曾雲川,青藏高原南部謝通門侏羅紀埃達克質岩地球化學特徵及其形成機制. 大地構造與成礦學, 2013, 37(2): 320-332.

科研項目

1 國家自然科學基金面上項目(批准號:42373045,執行年限:2024.01-2027.12,主持)
2 國家自然科學基金面上項目(批准號:41973027,執行年限:2020.01-2023.12,主持)
3 國家自然科學基金青年項目(批准號:41603033,執行年限:2017.01-2019.12,主持)
4 國家博士後創新人才支持計畫(批准號:BX201700213,執行年限:2017.07-2019.09,主持)
5 中國博士後科學基金面上二等資助(批准號:2017M620847,執行年限:2017.11-2019.09,主持)
6 中央高校基本科研業務費拔尖青年教師創新能力培養項目(批准號:2652019054,執行年限:2020.01-2022.12,主持)
7 中央高校基本科研業務費優秀教師基金項目(批准號:2652017213,執行年限:2017.07-2019.11,主持)
8 國家重點研發計畫項目“青藏高原碰撞造山成礦系統深部結構與成礦過程”(批准號:2016YFC0600304,執行年限:2016.07-2021.06,子課題負責人)
9 第二次青藏高原綜合科學考察研究(批准號:2019QZKK0702,執行年限:2019.01-2024.12,參與)
10 國家自然科學基金委重點項目“鉬同位素在岩漿熱液系統的分餾機制及其對斑岩型礦床的成因指示”(批准號:41730427,2018.01-2022.12,參與)
11 國家自然科學基金委重大項目“松遼及遼西地區早白堊世高解析度陸相地質記錄及其分布規律”(批准號:41790453,2018.01-2022.12,參與)
12 國家自然科學基金委重大研究計畫“西南三江昌寧—孟連縫合帶複合造山演化與成礦系統時空結構”(批准號:91855217,2019.01-2023.12,參與)
13 國家重點研發計畫項目“松遼盆地深層早白堊世新層系古環境與古氣候及油氣資源潛力評價”(批准號:2019YFC0605400,2020.01-2022.12,參與)
14 國家自然科學基金委面上項目(批准號:41573024,2016.01-2019.12,參與)
15 國家自然科學基金委面上項目(批准號:41373030,2014.01-2017.12,參與)

指導學生

2023年,本科生校級優秀畢業論文
2023年,研究生國家獎學金

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