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2026

1.?Li, W.-C., Zhang, L.,?Wang, Q.*, Palin, R. M., Zhang, X.-Z., Wang, J., Li, W.-F., Wang, B.-Z., Dan, W., Huang, T.-Y., Xue, E.-K. 2026. Metamorphic Evolution and Tectonic Implications of the Granulitized Eclogites from the Central East Kunlun Orogen, Northwest China.?GSA Bulletin?(accepted).

2.?Li, C., Ma, L., Kerr, A. C., Dan, W.,?Wang, Q., Yu, Z., Qiao, W., Pu, R., Yang, F. 2026. Petrogenesis of Late Triassic adakitic rocks and basalts from the southern Lhasa: Insights into subduction initiation of Neo-Tethys.?Lithos,?530–531, 108498

3.?Xue, E.-K.,?Wang, Q.*, Chew, D., Xue, W.-W., Li, W.-C., Huang, T.-Y. 2026. The surface response to two episodes of lithosphere underthrusting and detachment during Tibetan Plateau growth.?Geology,?https://doi.org/10.1130/G54475.1.

4.?Gong, L.,?Wang, Q.*, Li, Z.-X., Kerr, A.C., Zhang, X.-Z., Qi, Y., Shen, X.-M., Zhang, Z.-Y., Chen, B., and Yu, Z.-W. 2026. From mountain range to flat plateau in the Qiangtang Block (western China): Insights from low-temperature thermochronology.?GSA Bulletin,?https://doi.org/10.1130/B38637.1.

5.?Huang, T.-Y.,?Wang, Q.*, Kerr, A., Wang, J., Jiang, Z.-Q., Ma, L. 2026. Multiple Origins of Hornblende-Rich Cumulates within a Deep Magma Reservoir from the Late Jurassic Gangdese Arc, South Tibet: Implications for Arc Crustal Evolution.?Journal of Petrology, 2026, egag006, https://doi.org/10.1093/petrology/egag006.

6.?Ma, L., Zhou, J.-S.*,?Wang, Q.*, Ma, L., Liu, J.-H., Li, W.-F., Wang, B.-Z., Wang, C.-T., Liu, J.-D., Zhang, X.-Y., Liu, M.-R., Yu, Z.-W., Yang, Q.-J., and Shi, Z.-K., 2026, Geochemistry of tourmaline in granitic rocks from the Zharigana and Caolong areas, Northern Tibet: Implications for the identification of lithium-mineralizing plutons.?Lithos, 526-527, 108444，https://doi.org/10.1016/j.lithos.2026.108444.

7.?Zhou, J.,?Wang, Q., Li, Q., Huang, T., Wang, Z., and He, P. 2026. Complex crystal textures and zoning patterns in the Saillipu potassic rocks (southern Tibet) and petrological implications.?Lithos, .522-523, 108404，https://doi.org/10.1016/j.lithos.2026.108404.

8.?Liu, M.-R., Bai, J.-H., Zhu, G.-H., Deng, G.-C.,?Wang, Q., and Wei, G.-J., 2026, Precise δ²⁹/²⁸Si and δ³⁰/²⁸Si determination by high-resolution MC-ICP-MS.?Journal?of Analytical Atomic Spectrometry, 41, 547-555,?https://doi.org/10.1039/D5JA00424A.

9.?王秉璋*，王強，苗國文，王濤，吳治之，趙子送，喬建峰，王春濤，田濤，李積清．2025.?東昆侖祁漫塔格灘北雪峰泥盆紀鈮礦化方解石角閃石巖的發(fā)現(xiàn)、成因及找礦意義．大地構造與成礦學. https://link.cnki.net/urlid/44.1595.p.20250930.1126.002.

10.?曹錦山?，徐海明?，王軍*，王偉，鄭英，馬永成，緱明亮，張新遠，李玉龍，王濤，黃彤宇，史兆凱，劉毅，王秉璋*，王強*. 2025.?東昆侖大格勒溝北部晚志留世鎂鐵質–超鎂鐵質巖體及鎳鈷礦化的發(fā)現(xiàn)．大地構造與成礦學.?https://link.cnki.net/urlid/44.1595.P.20251229.1121.004.

11.?張修政，張新遠，李五福，龔林，胡萬龍，劉建棟，余志偉，鄭英，薛偉偉，薛爾堃，李旺超，王秉璋*，王強*．2026.?藏北可可西里布喀達坂峰中新世含綠柱石富鋰白云母淡色花崗巖的發(fā)現(xiàn)及鋰鈹成礦潛力．大地構造與成礦學.?https://doi.org/10.16539/j.ddgzyckx.2025.00.039.

12.?龔林，張修政，張新遠，李五福，胡萬龍，余志偉，劉建棟，鄭英，王秉璋*，王強*．2026.?藏北可可西里布喀達坂峰晚中新世陸內Cu-Sn?礦化的首次發(fā)現(xiàn)．大地構造與成礦學. https://doi.org/10.16539/j.ddgzyckx.2025.00.038.

13.?王秉璋*,?王強,?王濤,?焦和,?李五福,?權朝軍,王春濤,?趙子送. 2026.?南祁連柴達木山與錫礦化共生花崗巖的成因及成礦背景、勘查意義．巖石學報，42(01): 71~98, doi:10.18654/1000-0569/2026.01.03.

14.?Liu, J.-H., Liu, X.,?Wang, Q.*, Wang, H., Wyman, D. A., Guo, H.-F., Tang, G.-J.*, Ma, L., Zhao, Z.-H., Huang, X.-L., Li, W.-X., Yuan, C., Xia, X.-P., Yang, Y.-N., Zhang, L. 2026. Tourmaline-bearing two-mica granites and associated mafic dikes in an intra-continental extension setting: Implications for the petrogenesis of leucogranites and crustal growth.?GSA Bulletin,?https://doi.org/10.1130/B38413.1

15.?Tang, G.-R., Dan, W., Maulana, A., Wang, J., Zhang, X.-Z., Ma, X.,?Wang, Q., Liu, X.-J., and Tang, G.-J. 2026. Low-δ¹⁸O magmas at Batur, Indonesia: Evidence for slab-window melting beneath arc volcanoes.?Chemical Geology, 702, 123224，https://doi.org/10.1016/j.chemgeo.2025.123224.

2025

16.?王?強?但?衛(wèi)?張修政等著. 2025.?羌塘地塊古生代—中生代地質演化的巖漿-?變質作用記錄.北京：科學出版社. 1-566.

17.?Wang, J.,?Wang, Q.*, Hawkesworth, C. J.* 2025. Reply: Indian cratonic mantle beneath northern Qiangtang in eastern Tibet ca. 11 Ma.?Geology，?53 (11): e590, https://doi.org/10.1130/G53924Y.1

18.?Wang, J.,?Wang, Q.*, Hawkesworth, C. J.* 2025. Reply: Indian cratonic mantle beneath northern Qiangtang in eastern Tibet ca. 11 Ma.?Geology，?53 (11): e589,?https://doi.org/10.1130/G53922Y.1.

19.?Li, Z., Li, P., Rosenbaum, G., Cawood, P.A.,?Wang, Q., Yuan, C., and Shen, J. 2025. Rivers of change: the Tethyan Himalaya records how the Gondwanide orogeny altered Late Triassic global climate.?Earth and Planetary Science Letters, 671, 119687，?https://doi.org/10.1016/j.epsl.2025.119687.

20.?Dan, W.,?Wang, Q., Tang, G. J., Zhang, X. Z. 2025. Magmatism in continental rifts and rifted margins. Science China Earth Sciences, https://doi.org/ 10.1007/s11430-024-1623-5. (但衛(wèi),?王強,?唐功建,?張修政. 2025.?大陸張裂帶和裂解邊緣的巖漿作用.?中國科學-地球科學, 55, https://doi.org/10.1360/SSTe-2024-0367.)

21.?Liu, M.-R., Wang, J.,?Cui, Z.-X., Wei, G.-J., Yang, Q., Xu, Y.-G., Kerr, A.C., Wyman, D., Bai, J.-H., Zhu, G.-H., Ma, L., Hao, L.-L., Zhou, J.-S., Fan, J.-J., Huang, T.-Y., Zhang, M.-Y., and?Wang, Q.*?2025.?Discovery of a heavy silicon isotope mantle reservoir.?National Science Review, nwaf410,?https://doi.org/10.1093/nsr/nwaf410.

22.?Xu, J., Xia, X.-P., Bartoli, O., Zhang, L., Wang, Y., Ma, J.-L., Cui, Z.-X., Zhang, Y.-Q., Yang, Q.,?Wang, Q., and Xu, Y.-G. 2025. Heavy boron isotopes in plume-derived magmas trace recycled water in deep-mantle reservoir.?Communications Earth & Environment, 6, 593，https://doi.org/10.1038/s43247-025-02596-4.

23.?Xue, E.-K.,?Wang, Q.*, Chew, D., Xue, W.-W., Li, W.-C., and Huang, T.-Y. 2025. Oligocene to Miocene Topographic Inversion and Accelerated Uplift of Southern Tibet Revealed by the Paleodrainage Evolution of Intermontane Basins.?Geophysical Research Letters, 52, e2025GL116138,?https://doi.org/10.1029/2025GL116138.

24.?Dan, W., Zhang, X.-Z., Chen, Y.-X., Tang, G.-J.,?Wang, Q., and Zheng, Y.-F. 2025. Metamorphic evolution of Mesozoic microcontinent suture zones in the Tibet region.?Earth-Science Reviews, 268, 105174，https://doi.org/10.1016/j.earscirev.2025.105174.

25.?Yang, Z.-Y.,?Wang, Q.*,?Wang, J., Ma, L., Wyman, D., Kerr, A.C., Bi, X.-W., Sun, P., Zhang, X.-Z., Hao, L.-L., Liu, X., Xu, C.-B., Liu, J.-H., and Huang, T.-Y. 2025. Recycling of sub-continental lithosphere during early ocean spreading revealed by Triassic trachytes in the central Tibetan Plateau.?Chemical Geology, 693, 122985,?https://doi.org/10.1016/j.chemgeo.2025.122985.

26.?Li, W.,?Wang, Q.*, Palin, R.M., Zhang, L., Zhang, X., Xue, W., Huang, T., and Xue, E. 2025.?New pressure-temperature-time constraints on initial India-Asia collision from eastern Himalayan syntaxis eclogite-facies metamorphic rocks.?Earth and Planetary Science Letters, 668, 119547,?https://doi.org/10.1016/j.epsl.2025.119547.

27.?Huang, S.-Y., Hao, L.-L.,?Wang, Q., Kerr, A.C., Hu, W.-L., Mo, Q.-Q., Liu, M.-R., Qi, Y., Dan, W., and Zhang, X.-Z. 2025.?Post-collisional crustal evolution in the central Lhasa block of southern Tibet: Insights from early and late Cretaceous magmatism.?Lithos, 514-515, 108213，https://doi.org/10.1016/j.lithos.2025.108213.

28.?Hao, L.-L., Hu, W.-L.,?Wang, Q.*, Kerr, A.C., Dan, W., Zhang, X.-Z., Yang, Z.-Y., and Sun, P., 2025,?Bangong-Nujiang Neo-Tethyan Ocean (Central Tibet): Geodynamics, Crustal Evolution, Metallogeny, and Linkages to the “Yanshan Movement”.?Earth-Science Reviews, 265, 105119,?https://doi.org/10.1016/j.earscirev.2025.105119.

29.?Wang, J., Xu, C.-B.,?Wang, Q.*, Hawkesworth, C.J.*, Xu, Y.-G., Tang, G.-J., Wyman, D., Kerr, A.C., Wang, B.-Z., Liu, J.-H., Li, W.-F., Li, S.-P., Qi, Y., Li, J., Xiao, Z., and Wang, C.-T. 2025.?Indian cratonic mantle beneath northern Qiangtang in eastern Tibet ca. 11 Ma.?Geology,?53 (6): 514–518,?https://doi.org/10.1130/G52845.1.

30.?Fan, J.J.,?Wang, Q.*, Long, X.P., Wyman, D.A., Kerr, A.C., Li, J., Wang, Z.L., Gong, L., Xu, D.J., Yang, Q.J., Zhang, L., and Cui, Z.-X. 2025. Mo isotope evidence for the significance of subducted continental crust in formation of post-collisional porphyry Cu deposits.?Chemical Geology, 680, 122683,?https://doi.org/10.1016/j.chemgeo.2025.122683.

31.?Zhang, L.,?Wang, Q., Mikhailenko, D.S., Xian, H., Ding, X., Li, W.-C., and Yang, Y. 2025. Formation of Mg-rich kuliginite (Fe₃Mg(OH)₆Cl₂) during serpentinization by saline fluids.?Lithos, 504-505, 108040, https://doi.org/10.1016/j.lithos.2025.108040.

32.?Zhou, J. S.*,?Wang, Q.*,?Wang, H., Ma, J. L., Zhu, G., and Zhang, L. 2025.?Pegmatite lithium deposits formed within low-temperature country rocks.?Nature Communications, 16, 447, DOI: 10.1038/s41467-024-55793-8，https://doi.org/10.1038/s41467-024-55793-8.

33.?Zhang, M.-Y., Hao, L.-L., Qi, Y.,?Wang, Q., Kerr, A.C., Ma, L., Huang, C.-C., Wei, G.-J., Li, J., Ma, J.-L., Li, Q.-W., Wang, Z.-L., Huang, T.-Y., and Yang, Y.-C. 2025.?Mantle metasomatism by subducted Indian continental crust: Evidence from post-collisional basaltic ultrapotassic rocks in southern Tibetan plateau.?Lithos, 498-499, 107966.?https://doi.org/10.1016/j.lithos.2025.107966.

34.?Li, Q.W.,?Wang, Q.*, Ma, L., Kerr, A.C., Fan, J.J., Zhao, J.H., Gu, H.O., Wang, W. and Su, Z.K. 2025.?Light iron isotopes in high-silica granites record fluid evolution in magmatic-hydrothermal systems.?Geochimica et Cosmochimica Acta, 391, 277-290, DOI: 10.1016/j.gca.2024.12.034，https://doi.org/10.1016/j.gca.2024.12.034.

35.?Gong, L.,?Wang, Q.*,?Kerr, A.C., Chen, H., Fan, J., Wang, Z., Xu, D., and Yang, Q. 2025.?Eocene tearing and fragmentation of Indian lithosphere beneath the Woka rift, southern Tibet:?GSA Bulletin, 137 (1-2), 564–574,??https://doi.org/10.1130/B37577.1.

36.?焦和,?王秉璋,?魯海峰,?王濤,?徐倩,?周發(fā),?權朝軍,?蘇壽奎,?王強. 2025.?南祁連地塊西段志留紀云英巖型錫礦床的發(fā)現(xiàn)及找礦意義.?大地構造與成礦學, 49 (6)：1382~1392, DOI：10.16539/j.ddgzyckx.2024.01.169.

37.?許傳兵,?王強*,?王軍,?但衛(wèi),?劉金恒,?李五福,?王秉璋,?李善平,?王春濤,?王子龍. 2025.?羌塘東部玉樹地區(qū)阿多中三疊世A型流紋巖地球化學特征、成因及其地質意義[J].大地構造與成礦學, 49(03):712-723. DOI:10.16539/j.ddgzyckx.2024.01.211.

38.?趙振華,?唐功建,?王強. 2025.?下陸殼形成和分異的一種機制——刮墊作用.?大地構造與成礦學, 49（204）, 1-16，DOI：10.16539/j.ddgzyckx.2024.01.121.

2024?

39.?Xu, J., Xia, X.-P.,?Wang, Q., Zhang, L., Cui, Z.-X., Yang, Q., and Zhang, W.-F., 2024, Iron isotope fractionation during transcrustal magmatic differentiation: Implications for continental crustal formation in subduction zones. GSA Bulletin, 137, 1843-1854，https://doi.org/10.1130/B37831.1.

40.?Liu, M.-R., Ou, Q.,?Wang, Q.*, Qi, Y.*, Kerr, A. C., Wyman, D., Dan, W., Hao, L.-L., Jiang, Z.-Q. 2024. Lithospheric evolution and uplift of the Tibetan Plateau during continental convergence: evidence from Early Oligocene pseudoleucite phonolites from southern Qiangtang, central Tibet.?Journal of Petrology, 65(11), 1-21 DOI: 10.1093/petrology/egae113.

41.?Xu, D.J., Qi, Y.*,?Wang, Q.*, Li, J., Wyman, D. A., Kerr, A. C., Zhang, X.-Z., Guo, P. 2024. Identifying recycled materials using Mo isotopes in intraplate alkali basalts from southeastern margin of Tibetan Plateau.?Geochemistry, Geophysics, Geosystems, 25, e2024GC011750.?https://doi.org/10.1029/2024GC011750.

42.?Hu, W.L.,?Wang, Q.*, Yang, J.H., Wang, J., Qi, Y., Yang, Z.Y., Sun, P., 2024c. Petrogenesis of Early Cretaceous andesites and mafic dikes in central Tibet: Implications for the growth of continental crust in collision zones. Journal of Asian Earth Sciences, 259 105898,?https://doi.org/10.1016/j.jseaes.2023.105898.

43.?李五福,王強*,李玉龍*,王秉璋,金婷婷,劉建棟,王濤,張新遠,鄭英,袁博武,韓曉龍,周金勝,王泰山,王春濤,曹錦山,趙忠國. 2024.?東昆侖大格勒地區(qū)富鈮橄欖巖中的含鈮礦物組成.?地球化學.?2024 ,53 (05), 708–718. DOI：10.19700/j.0379-1726.2024.05.007.

44.?Huang, Z., Yuan, C., Zhang, Y., Narantsetseg, T., Gu, H., Xu, Y.-G.,?Wang, Q.?2024. Influences of the Stagnant Pacific Slab Beyond its Westernmost Edge: Insights from the Cenozoic Alkaline Basalts in the Dariganga Volcanic Field, SE Mongolia.?Journal of Geophysical Research: Solid Earth,?129, e2024JB028884.??https://doi.org/10.1029/2024JB028884.

45.?Zhang, L.,?Wang, Q., Xian, H., Ding, X., Li, W.C., Yang, Y., 2024. Low–temperature crystallization of kumdykolite, a polymorph of albite, during mineral carbonation within fluid inclusions in hornblendite from the Dabie orogen, central China.?American Mineralogist, in press, https://doi.org/10.2138/am-2023-9169.

46.?Shi, S., Jiang, Y., Weinberg, R.F., Zhang, Z., and?Wang, Q.?2024. Eocene crustal thickening in the Tethyan Himalaya: Insights from Barrovian metamorphism and granite geochemistry from the Ramba area.?GSA Bulletin, 136, 3649–3672, https://doi.org/10.1130/B37284.1.

47.?Xu, J., Xia, X.-P.,?Wang, Q., Spencer, C. J., Zhang, L., and Zhu X. 2024. Apatite textures, elemental and isotopic compositions unmask the homogenizing process in silicic magma chambers.?Geophysical Research Letters, 51(2), e2023GL106646,?https://doi.org/10.1029/2023GL106646.

48.?Chen, Z.-W., Yuan, C., Huang, Z.-Y., Jiang, Y.-D., Li, P.-F., Xiao, M., Wang, X.-Y., Zhang, Y.-Y., and?Wang, Q.?2024. Tungsten enrichment processes in peraluminous granites of the Chinese Altai.?Ore Geology Reviews, 172, 106211. https://doi.org/10.1016/j.oregeorev.2024.106211.

49.?Wang, J., Tappe, S.,?Wang, Q., Li, J., Zou, Z.–Q., Tang, G.–J. 2024. Carbon cycling during the India–Asia collision revealed by δ²⁶Mg–δ⁶⁶Zn–δ⁹⁸Mo evidence from ultrapotassic volcanoes in NW Tibet.?Geology, 52 (9), 672–677,https://doi.org/10.1130/G52267.1.

50.?Liu, X.,?Wang, Q.*, Liu, X.–J., Ma, L., Wyman, D.A., Tang, G.–J., Dan, W., Jiang, Z.–Q., Wu, H., Hu, W.–L., Liu, J.–H., Xu, C.–B., and Fang, G.–C. 2024. Early Cretaceous fayalite–, ferrosilite–, and biotite–bearing rhyolitic porphyries in the Baishuizhai area, South China: Formation by fractional crystallization in the shallow crust.?Lithos, 482–483, 107694, https://doi.org/10.1016/j.lithos.2024.107694.

51.?Tang, G.–R., Dan, W., Maulana, A., Wang, J., Zhang, X.–Z., Zhang, Y.–Y., Ma, X.,?Wang, Q., Liu, X.–J., and Tang, G.–J. 2024. Arc building and maturation of the Lombok Island, East Sunda Arc.?Chemical Geology, 663, 122265, https://doi.org/10.1016/j.chemgeo.2024.122265.

52.?Ma, X., Wang, J., Dan, W.,?Wang, Q., Tang, G.–R., Gadoev, M., Oimahmadov, I., Azamdzhon, M., Odinaev, S., and Tang, G.–J. 2024. Late cretaceous intraplate magmatism in Central and South Pamir: Response to edge–driven convection.?Lithos, 482–483, 107676, https://doi.org/10.1016/j.lithos.2024.107676.

53.?Yu, Z.–W., Dan, W.*,?Wang, Q.*, Zhang, X.–Z., Wang, J., Chen, B., and Gong, L. 2024. First identification of Carboniferous mafic dikes during a period of arc magmatic quiescence in the Northern Qiangtang terrane, central Tibet: Back–arc extension and implications for opening of the Xijir Ulan Ocean.?Lithos, 480–481, 107662.?https://doi.org/10.1016/j.lithos.2024.107662

54.?Xu, C.–B., Wang, J.,?Wang, Q.*, Kerr, A.C., Li, W.–F., Liu, J.–H., Wang, B.–Z., Li, S.–P., Wang, C.–T., Wang, Z.–L., and Gong, L. 2024. First identification of Mid–Miocene north–south trending dikes in the eastern Qiangtang terrane, eastern Tibet: Mantle melting and implications for plateau uplift.?Lithos, 478–479, 107620.?https://doi.org/10.1016/j.lithos.2024.107620.

55.?Wei, Y.–W., Wang, J.,?Wang, Q.*, Wang, B.–Z., Kerr, A.C., Li, W.–F., Li, S.–P., Liu, J.–H., Wang, C.–T., and Wang, Z.–L. 2024. Eocene rhyolites in the Shanglaxiu–Xialaxiu area of north–eastern Qiangtang Block, Tibet: Partial melting of juvenile crust??Lithos, 476–477, 107594.?https://doi.org/10.1016/j.lithos.2024.107594

56.?Hu, W.L.,?Wang, Q.*, Tang, G.–J., Qi, Y., Wang, J., Yang, Z.–Y., Sun, P. 2024. First identification of the Early Cretaceous mafic dykes in the Baingoin area, Central Tibet: Implications for crust–mantle interactions and magmatic flare–up.?GSA Bulletin, 136 (1–2), 846–860,?https://doi.org/10.1130/B36755.1.

57.?黃彤宇,?王強*,?楊宗永. 2024.?俯沖侵蝕的研究歷史、現(xiàn)狀與展望.?巖石學報, 40(3): 719–740.?doi:?10.18654/1000-0569/2024.03.04.

58.?王強*,?李五福,?王秉璋*,?王濤*,?周金勝,?馬林,?李玉龍,?袁博武,?王春濤,?王軍,?張新遠,?劉建棟,?薛爾堃,?胡萬龍?,?黃彤宇,?李旺超. 2024.?與堿性巖?碳酸巖雜巖共生的鈮–稀土成礦作用——兼論東昆侖大格勒鈮–稀土礦床中的堿性巖?碳酸巖雜巖成因.?大地構造與成礦學，48(1), 1–37，https://doi.org/10.16539/j.ddgzyckx.2024.01.00.

59.?李五福,?王強*,?王秉璋*,?劉建棟,?王春濤,?周金勝,?馬林,?王濤,?張新遠,?劉金恒,?李玉龍,?袁博武,?王泰山,?曹錦山,?金婷婷,?韓曉龍,?譚運鴻. 2024b.?東昆侖大格勒地區(qū)堿性雜巖體中輝石角閃石巖的年代學、地球化學特征及地質意義.?大地構造與成礦學，48(1), 144–162，https://doi.org/10.16539/j.ddgzyckx.2024.01.000.

60.?王秉璋，王強，王春濤，李五福，李玉龍，金婷婷，劉建棟．2024b.?東昆侖大格勒泥盆紀正長巖巖石成因和地質意義.大地構造與成礦學，48(1), 61–81，https://doi.org/10.16539/j.ddgzyckx.2023.06.005.

61.?王春濤，李五福，王秉璋，王強，張新遠，王濤，鄭英，金婷婷，劉建棟，袁博武，韓曉龍，曹錦山，王泰山，譚運鴻，李玉龍．2024.?東昆侖大格勒地區(qū)堿性雜巖體中輝石巖的年代學、地球化學、Sr–Nd同位素特征及其地質意義．大地構造與成礦學，48(1), 125–143，https://doi.org/10.16539/j.ddgzyckx.2023.06.002.

62.?周金勝,?王強*,?王秉璋,?王濤,?馬林,?李五福,?李玉龍,?袁博武,?翟國良,?王春濤,?劉建棟,?鄭??英,?金婷婷,?史兆凱,?馬玲,?劉懋銳,?李成,?余志偉,?楊其濟. 2024.?東昆侖大格勒稀有金屬礦床類型的厘定:?碳酸巖型鈮礦床.?大地構造與成礦學，48(1), 163–171，?https://doi.org/10.16539/j.ddgzyckx.2024.01.000.

63.?Wang, J., Tang, G.‐J., Tappe, S., Li, J., Zou, Z.,?Wang, Q., Su, Y.P., Zheng, J.P., 2024, Tracing subducted carbonates in Earth's mantle using zinc and molybdenum isotopes.?Geophysical Research Letters, 51, e2023GL105208. https://doi.org/10.1029/2023GL105208

64.?Hao, L.–L.*,?Wang, Q., Kerr, A.C., Huang, F., Xiao, M., Ma, X.–L., Zhang, W.–F., Wang, W.–Y., and Liu, M.–R. 2024. Andesitic arc magmas derived from two contrasting mélange origins: Evidence from central Tibetan dioritic porphyries.?Chemical Geology, 650, 121920. https://doi.org/10.1016/j.chemgeo.2023.121920.

65.?Tang, G.–J., Wyman, D. A. , Dan, W.,?Wang, Q., Liu, X.–J. , Yang, Y.–N., Gadoev, M., Oimahmadov, I. 2024. Protracted and progressive crustal melting during continental collision in the Pamir and plateau growth.?Journal of Petrology, 65(4), egae024,?https://doi.org/10.1093/petrology/egae024.

66.?Hu,?W.–L.,?Wang,?Q.*,?Yang,?J.–H., Hao,?L.–L., Wei,?G.–J., Qi,?Y.,?Wang,?J., Yang,?Z.–Y., Sun,?P., 2024.?Reworking and maturation of continental crust in collision zones: Insights?from Early Cretaceous compositionally diverse magmatic rocks in central?Tibet.?Lithos, 472–473, 107662, https://doi.org/10.1016/j.lithos.2024.107562.

67.?Dan，W., Yu, Z.–W.,?Wang, Q., Tang, G.–J., Zhang, X.–Z., Wang, J. 2024. Origin of the Songpan–Garzê terrane, Tibetan Plateau: a perspective from the tectonic evolution of the Palaeo–Tethys Ocean. Nance, R. D., Strachan, R. A., Quesada, C. and Lin, S. (eds) Supercontinents, Orogenesis and Magmatism.?Geological Society, London, Special Publications, 542,?https://doi.org/10.1144/SP542–2022–349.

68.?Gong, L.,?Wang, Q.*, Shen, X., Zhang, Z., Fan, J., Wang, Z., Yang, Q., Xu, D. 2024. Exhumation of the Cuonadong Sn–W–Be polymetallic deposit, Tethyan Himalaya: Implications for exploration.?Ore Geology Reviews, 2024, 165, 105870,?https://doi.org/10.1016/j.oregeorev.2024.105870

69.?Liu, J. H.,?Wang, Q.*, Li, W. F., Wang, B. Z., Wyman, D. A., Ding, L., Wang, H., Xu, C. B., Li, S. P., Wang, C. T., Liu, J. D., Zhang, R. Q., Wang, Z. L., Huang, T. Y., Zhang, X. Y. 2024. Origins and evolution of two types of Late Triassic granitic magmas in the Caolong–Xiangkariwa area of central–eastern Songpan–Ganze terrane, northern Tibet: Implications for pegmatite lithium mineralization.?GSA Bulletin, 136 (5-6), 2543–2557.?https://doi.org/10.1130/B37088.1.

70.?Fan, J.J., Zhang, X.Z., Ma, L.,?Wang, Q., Jiang, Z.Q., Xia, X.P., Wei, G.J., Wang, Z.L., Zhou, J.S., Li, Q.W., Liu, X., Huang, T.Y., Zhang, M.Y., Liu, J.H. 2024. Formation of Eocene–Miocene felsic magmatic rocks along N–S–trending Yardoi–Kongbugang mountain ranges in the eastern Himalaya: New insights into surface uplift and the initiation of E–W extension in southern Tibet.?GSA Bulletin, 136 (1–2), 433–446，https://doi.org/10.1130/B36617.1.

71.?Qi, Y.,?Wang, Q.*, Wei, G.–J., Zhang, X.–Z., Dan, W., Yang, Z.–Y., Hao, L.–L., Hu, W.–L. 2024. Oligocene high–MgO alkali basalts in central Tibet: implications for magma–mush mixing and mantle processes.?Journal of Petrology, 65, 1–19, egad091, https://doi.org/10.1093/petrology/egad091.

72.?徐義剛,?黃小龍,?王強,?王煜,?李高軍,?劉耘,?毛河光,?倪懷瑋,?朱茂炎. 2024 .?地球宜居性的深部驅動機制.?科學通報, 69 (02)?, 169–183.

2023?

73.?但衛(wèi),?王強,?馬林,?唐功建,?張修政. 2023.?俯沖板塊板內巖漿作用和動力學.?礦物巖石地球化學通報, 42 (05),?976–987.

74.?王核,?馬華東,?張嵩,?杜曉飛,?黃亮,?蔡銘澤,?陳根文,?朱炳玉,?王強,?王堃宇,?邢春輝,?王威,?邱林,?沈明宏. 2023.?新疆阿爾金地區(qū)黃龍嶺超大型偉晶巖型鋰礦床的發(fā)現(xiàn)及找礦意義.?巖石學報, 39(11):??3307-3318, DOI：10.18654/1000-0569/2023.11.06.

75.?王秉璋,?潘彤,?王強,?李五福,?祁生勝,?鄭英,?金婷婷,?劉金恒. 2023.青藏高原東北緣茶卡北山地區(qū)印支期高分異花崗巖的發(fā)現(xiàn)及找礦意義.?巖石學報, 39 (08), 2402–2428.

76.?Xue, W., Hu, X., Ma, A., Garzanti, E., Liang, W., Hao, L.,?Wang, Q.?2023. Oligocene Orogen–Parallel Extension in Southern Tibet During Indian Continental Subduction.?Geophysical Research Letter, 50: 20, 10.1029/2023GL105193.

77.?周金勝，李五福，王強，王秉璋，王濤，馬林. 2023.?與REE–HFSE成礦有關的堿性巖漿系統(tǒng),?礦物巖石地球化學通報, 42(5): 1101–1113.

78.?Zhang, M．–Y., Huang, C.–C., Hao, L.–L. *, Qi, Y. *,?Wang, Q., Kerr, A. C., Wei, G.–J., Li, J., Ma, J.–L., Ma, L., Fan, J.–J. 2023. Light Mo isotopes of post–collisional ultrapotassic rocks in southern Tibet derived from subducted Indian continental crust.?Geochemistry, Geophysics, Geosystems, 24, e2023GC011053,?https://doi.org/10.1029/2023GC011053.

79.?Zhou, D., Sun, P., Jiang, S., Liu, X.*, and?Wang, Q.*?2023. Geochronology and geochemistry of Early Cretaceous high–silica granites in the Nan’ao Island, South China: Petrogenesis and implications for lithospheric extension.?Journal of Asian Earth Sciences,? 245, 105558，https://doi.org/10.1016/j.jseaes.2023.105558.

80.?Wang, J.,?Wang, Q., Ma, L., Hu, W.–L., Wang, J., Belousova, E., and Tang, G.–J. 2023. Rapid Recycling of Subducted Sediments in the Subcontinental Lithospheric Mantle.?Journal of Petrology, 64(8), egad056, https://doi.org/10.1093/petrology/egad056.

81.?Wang, J.,?Wang, Q.*, Sun, P., Dan, W., Kerr, A.C., Zhang, Z.–P., Zhang, L., Wei, G., Dong, H., Hu, W.–L., Yang, Z.–Y., Zhang, X.–Z., and Qi, Y. 2023. Crustal Growth Identified by High–δ¹⁸O Zircon and Olivine: A Perspective from Ultramafic Arc Cumulates in Southern Tibet.?Journal of Petrology, 64, 1–20，egad052，?https://doi.org/10.1093/petrology/egad052.

82.?Li, Q.–W., Nebel, O., Zhao, J.–H., Wang, R., Jacobsen, Y., Richter, M.,?Wang, Q., and Cawood, P.A. 2023. An amphibolitic source for “adakitic” I–type plutons in continental collision zones.?Earth and Planetary Science Letters, 619, 118324, https://doi.org/10.1016/j.epsl.2023.118324.

83.?Zhang, L.,?Wang, Q., Xian, H., Zhou, J.–S., Ding, X., and Li, W.–C. 2023. Carbon mineralization and abiotic methane synthesis within fluid inclusions in mafic minerals from postcollisional pyroxenite.?Geochimica et Cosmochimica Acta, 356, 38–50, https://doi.org/10.1016/j.gca.2023.07.007.

84.?Tang, G.–J., Wyman, D.A.,?Wang, Q., Dan, W., Ma, L., and Yang, Y.–N. 2023. Large–scale rare–metal pegmatite deposit formation driven by supercontinent assembly.?Geology, 51 (9), 880–884，https://doi.org/10.1130/G51454.1.

85.?Hao, L.–L.*, Kerr, A.C.,?Wang, Q.*, Ma, L., Qi, Y., Xiao, M., and Ou, Q. 2023. Recycling of subducted Indian continental crust constrained by late Cretaceous mafic dykes in Central Lhasa block of the Tibetan plateau.?Lithos, 454–455, 107276，?https://doi.org/10.1016/j.lithos.2023.107276.

86.?Tang, G.–J., Wyman, D.A., Dan, W.,?Wang, Q., Gadoev, M., and Oimahmadov, I., 2023, Magma migration and surface uplift in Pamir–western Tibet driven by deep lithospheric dynamics.?Geology, 51 (9), 813–817，https://doi.org/10.1130/G51216.1.

87.?Qi, Y.,?Wang, Q.*, Wei, G.–J., Wyman, D. A., Zhang, X.–Z., Dan, W., Zhang, L., Yang, Y.–N. 2023. Post–collisional silica–undersaturated Bamaoqiongzong volcanic rocks from northern Qiangtang: Indicators of the mantle heterogeneity and geodynamic evolution of central Tibet.?Journal of Petrology, 64, 1–24, egac123, https://doi.org/10.1093/petrology/egac123.

88.?Gong, L., Chen, H.,?Wang, Q., Xiao, B., Zhang, S., and Tang, G., 2023, Multiple tectonic switches in the Eastern Tianshan, Central Asian Orogenic Belt: Implications for crustal growth and metallogenesis.?Lithos, 454–455, 107235, https://doi.org/10.1016/j.lithos.2023.107235.

89.?Ma, X., Dan, W., Wang, J.,?Wang, Q., Tang, G.–R., Gadoev, M., Oimahmadov, I., and Tang, G.–J., 2023, Cretaceous magmatic migration and flare–up in Pamir–Karakoram.?Lithos, 454–455, 107285, https://doi.org/10.1016/j.lithos.2023.107285.

90.?Zhang, X.–Z.,?Wang, Q.*, Kerr, A.C., Wei, G.–J., Qi, Y., Liu, Y., and Yang, Y.–C., 2023, Sediment recycling by continental subduction indicated by B–Hf–Pb–Nd isotopes from Miocene–Quaternary lavas in the northern margin of Tibet.?Lithos, 444–445, 107109,?https://doi.org/10.1016/j.lithos.2023.107109.

91.?Zhang, X.–Z.,?Wang, Q.*, Wyman, D., Kerr, A.C., Gou, G.–N., Dan, W., and Qi, Y. 2023. Are low–velocity zones within the Tibetan crust the result of crustal melting from at least 28?Ma??Lithos, 440–441, 107044, https://doi.org/10.1016/j.lithos.2023.107044

92.?Dan, W., Murphy, J.B., Tang, G.J., Zhang, X.Z., White, W.M. and?Wang, Q.?2023. Cambrian–Ordovician magmatic flare–up in NE Gondwana: a silicic large igneous province??GSA Bulletin, 135 (5–6), 1618–1632,?https://doi.org/10.1130/B36331.1.

93.?Hu, W.–L.,?Wang, Q.*, Yang, J.–H., Hao, L.–L., Wang, J., Qi, Y., Yang, Z.–Y., and Sun, P., 2023, Growth of the continental crust induced by slab rollback in subduction zones: Evidence from Middle Jurassic arc andesites in central Tibet.?Gondwana Research, 117, 8–22, https://doi.org/10.1016/j.gr.2023.01.001.

94.?Ma, L.*,?Wang, Q.*, Kerr, A., Li, Z.–X., Dan, W., Yang, Y.–N., Zhou, J.–S., Wang, J., Li, C. 2023. Eocene magmatism in the Himalaya: Response to lithospheric flexure during early Indian collision??Geology, 51 (1), 96–100,?https://doi.org/10.1130/G50438.1.

95.?Liu, J.–H.,?Wang, Q.*, Wang, B.–Z., Li, W.–F., Xu, C.–B., Li, S.–P., Wang, Z.–L., Hao, L.–L., Song, T.–Z., Wang, C.–T., Zheng, Y., and Wang, J.–S., 2023, Petrogenesis of the Chakabeishan pegmatites, North Qaidam Terrane: Implications for Indosinian lithium mineralization in the northern Tibetan Plateau.?Lithos, 440–441, 107025, https://doi.org/10.1016/j.lithos.2023.107025.

2022

96.?馬林,?王強,?唐功建,?李成. 2022.?岡底斯陸殼屬性與顯生宙生長演化.?大地構造與成礦學, 46 (06), 1170-1184.

97.?董云鵬,?任建國,?張志飛,?鄧軍,?郭安林,?張興亮,?胡修棉,?王強,?李建威,?邱楠生,?孫有斌,?趙國春,?張進江,?彭建兵,?林楊挺,?初航,?呂大煒. 2022.?地質學科未來5～10年發(fā)展戰(zhàn)略:趨勢與對策.?科學通報, 67 (23), 2708–2718.

98.?Zhang, X.-Z.,?Wang, Q., Dan, W., and Wyman, D. 2022. Locating Lhasa terrane in the Rodinia and Gondwana supercontinents: A key piece of the reconstruction puzzle.?GSA Bulletin, 135, 67-80，https://doi.org/10.1130/B36152.1.

99.?Ma, Y.,?Wang, Q., Wang, H., Wan, B., Zhang, S., Deng, C., Zhang, D., Re, Q., Yang, T., Wu, D., Zou, D., Wang, J., Liu, X., Kang, Z., Dan, W., Han, F., Dekkers, M. J. 2022. Jurassic paleomagnetism of the Lhasa terrane—Implications for Tethys evolution and true polar wander.?Journal of Geophysical Research: Solid Earth, 127, e2022JB025577,?https://doi.org/10.1029/2022JB025577.

100.?李五福,?劉金恒,?李善平,?賈春興,?王成武,?周金勝,?王春濤,?許傳兵,?談生祥,?胡繼春,?章榮清,?龔林,?王秉璋*,?王強*. 2022.?青藏高原東北部玉樹地區(qū)尕朵–扎朵早侏羅世含(綠柱石–鋰云母)鋰輝石偉晶巖的發(fā)現(xiàn)及成礦意義.大地構造與成礦學, 46(05), 924–950，?doi: 10.16539/j.ddgzyckx.2022.05.005.

101.?Zhou, J.–S., Huang, C.C.,?Wang, Q.*, Ren, Z.Y., Ma, L., Hao, L.–L., Zhang, L. 2022. Olivines and their melt inclusions in potassic volcanic rocks record mantle heterogeneity beneath the Southern Tibet.?Journal of Petrology, 63(11), 1–21, egac103, https://doi.org/10.1093/petrology/egac103.

102.?Dan, W., Murphy, J.B.,?Wang, Q., Zhang, X.Z., Tang, G.J. 2022. Tectonic evolution of the Proto–Qiangtang Ocean and its relationship with the Palaeo–Tethys and Rheic oceans. Hynes, A. J. and Murphy, J. B. (eds) The Consummate Geoscientist: A Celebration of the Career of Maarten de Wit.?Geological Society, London, Special Publications, 531,?https://doi.org/10.1144/SP531-2022-146.

103.?Zhang, X. Z.,?Wang, Q.*, Wyman, D., Kerr, A., Dan, W., Qi, Y. 2022.?Tibetan Plateau insights into >1100℃ crustal melting in the Quaternary.?Geology, 50 (12), 1432–1437,?https://doi.org/10.1130/G50387.1.

104.?Xu, J., Xia, X.–P.,?Wang, Q., Spencer, C.J., Lai, C.–K., Zhang, L. 2022. Two magma fractionation paths for continental crust growth: Insights from the adakite–like and normal–arc granites in the Ailaoshan fold belt (SW Yunnan, China).?GSA Bulletin, 134(11–12), 2986–3002, https://doi.org/10.1130/B36230.1.

105.?Zhang, L.,?Wang, Q., Mikhailenko, D. S., Ding, X., Li, W.–C., & Xian, H. 2022. Hydroxychloride–bearing fluid inclusions in ultramafic rocks from New Caledonia: Implications for serpentinization in saline environments on Earth and beyond.?Journal of Geophysical Research: Solid Earth, 127, e2022JB024508,?https://doi.org/10.1029/2022JB024508.

106.?Qi, Y.,?Wang, Q.*, Wei, G.–J.,?Li, J.,^?Wyman, D. A. 2022.?Magnesium and calcium isotopic geochemistry of silica–undersaturated alkaline basalts: Applications for tracing recycled carbon.?Geochemistry, Geophysics, Geosystems,?23, e2022GC010463,?https://doi.org/10.1029/2022GC010463.

107.?Fan, J.–J.,?Wang, Q.*, Ma, L., Li, J., Zhang, X.–Z., Zhang, L., Wang, Z.–L. 2022.?Extreme Mo isotope variations recorded in high–SiO₂?granites: Insights into magmatic differentiation and melt–fluid interaction.?Geochimica et Cosmochimica Acta, 334, 241–258, https://doi.org/10.1016/j.gca.2022.08.009.

108.?Xu, C.–B., Zeng, J.–P.,?Wang, Q.*, Zhang, X.–Z.*, Ou, Q., Wang, J., Hao, L.–L., Chen, Y. 2022.?Eocene adakitic quartz monzonites and granite porphyries from the northern Qiangtang Block, central Tibet: Partial melting of sediment–rich mélange.?Front. Earth Sci.,?10, 953448, https://doi.org/10.3389/feart.2022.953448.

109.?Zhang, M.–Y., Hao, L.–L.,?Wang, Q., Qi, Y., Ma, L. 2022.?B–Sr–Nd isotopes of Miocene trachyandesites in Lhasa block of southern Tibet: Insights into petrogenesis and crustal reworking.?Front. Earth Sci.,?10, 953364, doi: 10.3389/feart.2022.953364.

110.?Zhou, J.–S.,?Wang, Q.*, Wyman, D.A., Zhao, Z.H., Zhang, L., He, P.–L. 2022. The efficiency of copper extraction from magma bodies: Implications for mineralization potential and fluid–silicate melt partitioning of copper.?American Mineralogist, 107 (9), 1681–1696,?https://doi.org/10.2138/am–2021–7951.

111.?Hao, L.–L.,?Wang, Q., Ma, L., Qi, Y., and Yang, Y.–N. 2022. Differentiation of continent crust by cumulate remelting during continental slab tearing: Evidence from Miocene high–silica potassic rocks in southern Tibet.?Lithos, 426–427, 106780,?https://doi.org/10.1016/j.lithos.2022.106780.

112.?Ou, Q.,?Wang, Q.*, Wyman, D. A., Zhang, X.–Z.*, Hao, L.–L., Zeng, J.–P., Yang, J.–H., Zhang, H.–X., Hou, M.–C., Qi, Y., Liu, Z. 2022. Formation of late Miocene silicic volcanic rocks in the central Tibetan Plateau by crustal anatexis of granulites.?Lithos, 432–433, 106882, https://doi.org/10.1016/j.lithos.2022.106882.

113.?Liu, X., Liang, H.,?Wang, Q.*, Ma, L.*, Yang, J.H., Ou, Q., Guo, H.F., Xiong, X.L., Zeng, J.P., Gou, G.N., and Hao, L.L. 2022. Early Cretaceous Sn–bearing granite porphyries, A–type granites, and rhyolites in the Mikengshan–Qingxixiang–Yanbei area, South China: Petrogenesis and implications for ore mineralization.?Journal of Asian Earth Sciences, 235, 105274, https://doi.org/10.1016/j.jseaes.2022.105274.

114.?Tang, G.–J., Wyman, D.A.,?Wang, Q., Ma, L., Dan, W., Yang, Y.–N., Liu, X.–J., Chen, H.–Y. 2022.?Links between continental subduction and generation of Cenozoic potassic–ultrapotassic rocks revealed by olivine oxygen isotopes: A case study from NW Tibet.?Contributions to Mineralogy and Petrology, 177, 53，https://doi.org/10.1007/s00410–022–01920–x.

115.?Liu, J.–H., Gou, G.–N.,?Wang, Q.*, Zhang, X.–Z.*, Guo, H.–F. 2022.?Petrogenesis of Eocene high–silica granites in the Maliaoshan area, northern Tibet: Implications for the Eocene magmatic flare–up in the Northern Qiangtang Block.?Journal of Asian Earth Sciences,?234, 105268，https://doi.org/10.1016/j.jseaes.2022.105268.

116.?Liu, J.–H.,?Wang, Q.*, Xu, C.–B., Zhou, J.–S., Wang, B.–Z., Li, W.–F., Li, S.–P., Huang, T.–Y., Yan, Q.–H., Song, T.–Z., Wang, C.–T., Zheng, Y., Wang, J.–S. 2022.?Geochronology of the Chakabeishan Li–(Be) rare–element pegmatite, Zongwulong orogenic belt, northwest China: Constraints from columbite–tantalite U–Pb and muscovite–lepidolite?⁴⁰Ar/³⁹Ar dating.?Ore Geology Reviews, 146, 104930，https://doi.org/10.1016/j.oregeorev.2022.104930.

117.?Zhao, Z.–H.,?Wang, Q., Xiong, X.–L., Wyman, D.A., Bai, Z., Tang, G.–J., Niu, H.–C., Luo, Y., Liu, H.–Q., Qiao, Y.–L. 2022.?Stagnated eclogitic slab–related shoshonitic series volcanic rocks in West Tianshan, Xinjiang, China: Insights from Li–B–Sr–Nd–Hf–Pb isotope and trace element compositions.?Lithos, 422–423, 106724，https://doi.org/10.1016/j.lithos.2022.106724.

118.?Xu, J., Xia, X.–P., Spencer, C.J.,?Wang, Q., Yin, C.–Q. 2022.?Identification of High δ¹⁸O Adakite–Like Granites in SE Tibet: Implication for Diapiric Relamination of Subducted Sediments.?Geophysical Research Letters, 49, e2022GL098541,?https://doi.org/10.1029/2022GL098541.

119.?Wang, J.,?Wang, Q.*, Zeng, J.–P., Ou, Q., Dan, W., Yang, A. Y., Chen, Y.–W., Wei, G.–J. 2022.?Generation of continental alkalic mafic melts by tholeiitic melt–mush reactions: A new perspective from contrasting mafic cumulates and dikes in central Tibet.?Journal of Petrology, 63(5), egac039,?https://doi.org/10.1093/petrology/egac039.

120.?Huang, T.–Y.,?Wang, Q.*, Wyman, D. A., Ma, L., Tang, G.–J., Zhang, Z.–P., Dong, H. 2022.?Subduction erosion revealed by Late Mesozoic magmatism in the Gangdese arc, South Tibet.?Geophysical Research Letters, 49, e2021GL097360. https://doi.org/10.1029/2021GL097360.

121.?Hao, L–L.,?Wang, Q.*, Kerr, A., Wei, G–J., Huang, F., Zhang, M–Y., Qi, Y., Ma, L., Chen, X–F., Yang, Y.–N. 2022. Contribution of continental subduction to very light B isotope signatures in post–collisional magmas: evidence from southern Tibetan ultrapotassic rocks.?Earth and Planetary Science Letters, 584, 117508.?https://doi.org/10.1016/j.epsl.2022.117508.

122.?Wang, J.,?Wang, Q.*, Xu, C.–B., Dan, W.*, Xiao, Z., Shu, C., Wei, G. 2022. Cenozoic delamination of the southwestern Yangtze Craton owing to densification during subduction and collision.?Geology, 50 (8), 912–917, https://doi.org/10.1130/G49732.1

123.?Hu, W.–L.,?Wang, Q.*, Tang, G.–J., Zhang, X.–Z., Qi, Y., Wang, J., Ma, Y.–M., Yang, Z.–Y., Sun, P., Hao, L.–L. 2022. Late Early Cretaceous magmatic constraints on the timing of closure of the Bangong–Nujiang Tethyan Ocean, Central Tibet.?Lithos, 416–417, 106648，https://doi.org/10.1016/j.lithos.2022.106648.

124.?Tang, G.–J., Wyman, D.A.,?Wang, Q., Yin, J.–Y., Dan, W. 2022. Long–Distance Lateral Magma Propagation and Pamir Plateau Uplift.?Geophysical Research Letters, 49, e2021GL096467，https://doi.org/10.1029/2021GL096467.

125.?Zhang, X.Z.,?Wang, Q.*, Wyman, D., Ou, Q., Qi, Y., Gou, G.–N., Dan, W., Yang, Y.–N. 2022.? Tibetan Plateau growth linked to crustal thermal transitions since the Miocene.?Geology, 50 (5): 610–614,?https://doi.org/10.1130/G49534.1.

126.?Ma, Y.*,?Wang, Q.*, Yang, T., Ou, Q., Zhang, X., Dan, W., Zhang, S., Wu, H., Li, H., Cao, L., Wang, J., Zou, D., Wang, H. 2022. Location of the Lhasa terrane in the Late Cretaceous and its implications for crustal deformation.?Palaeogeography, Palaeoclimatology, Palaeoecology, 588, 110821,?https://doi.org/10.1016/j.palaeo.2021.110821.

127.?Wang, Z.–L., Fan, J.–J.,?Wang, Q.*, Hu, W.–L., Wang, J., Ma, Y.–M. 2022. Campanian transformation from post–collisional to intraplate tectonic regime: Evidence from ferroan granites in the Southern Qiangtang, central Tibet.?Lithos, 408–409, 106565，https://doi.org/10.1016/j.lithos.2021.106565.

128.?Xu, J., Xia, X.P.,?Wang, Q., Spencer, C.J., Lai, C.K., Ma, J.L., Zhang, L., Cui, Z.X., Zhang, W.F., and Zhang, Y.Q. 2022. Pure sediment–derived granites in a subduction zone.?GSA Bulletin, 134, 599–615, https://doi.org/10.1130/B36016.1.

129.?Yan, Q.H., Wang, H., Chi, G.,?Wang, Q., Hu, H., Zhou, L., Zhang, X.Y. 2022.?Recognition of a 600–km–long Late Triassic rare–metal (Li–Rb–Be–Nb–Ta) pegmatite belt in the Western Kunlun orogenic belt, western China.?Economic Geology, 117(1)，213–236，https://doi.org/10.5382/econgeo.4858.

130.?Xu, J., Xia, X.–P.,?Wang, Q., Spencer, C. J., He, B., and Lai, C.–K. 2022. Low–δ¹⁸O A–type granites in SW China: Evidence for the interaction between the subducted Paleotethyan slab and the Emeishan mantle plume.?GSA Bulletin, 134 (1–2): 81–93,?https://doi.org/10.1130/B35929.1.

131.?周金勝,?王強. 2022.?地殼內的巖漿動力學過程及其資源與環(huán)境效應.?巖石學報, 38(5):1399–1418, doi: 10.18654/1000–0569/2022.05.09.

132.?馬鑫,?但衛(wèi),?王強,?楊亞楠,?唐國榮,?唐功建. 2022.?中帕米爾塔什庫爾干早白堊世二云母花崗巖與中–基性包體的巖石成因及其地質意義.?大地構造與成礦學, 46 (02), 380–397.

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133.?Tang, G.-J., Cawood, P. A., Wyman, D. A., Dan, W.,?Wang, Q., Yang, Y.-N. 2021. The missing magmatic arc in a long-lived ocean from the western Kunlun- Pamir Paleo-Tethys realm.?Geophysical Research Letters, 48, e2021GL095192. https://doi.org/10.1029/2021GL095192.

134.?Sun, P.,?Wang, Q.*,?Hao, L.-L.*, Dan, W., Ou, Q., Jiang, Z.-Q., and Tang, G.-J., 2021. A mélange contribution to arc magmas recorded by Nd–Hf isotopic decoupling: An example from the southern Qiangtang Block, central Tibet.?Journal of Asian Earth Sciences, p. 104931, in press, https://doi.org/10.1016/j.jseaes.2021.104931.

135.?Qi, Y.,?Wang, Q.*, Wei, G.-J., Zhang, X.-Z., Dan, W., Hao, L.-L., and Yang, Y.-N.. 2021.? Late Eocene post-collisional magmatic rocks from the southern Qiangtang terrane record the melting of pre-collisional enriched lithospheric mantle.?GSA Bulletin, 133 (11-12): 2612–2624, https://doi.org/10.1130/B35864.1.

136.?Liu, X.,?Wang, Q.*,?Ma, L.*, Yang, J.-H., Ma, Y.-M., and Huang, T.-Y., 2021. Early Paleozoic and Late Mesozoic crustal reworking of the South China Block: Insights from Early Silurian biotite granodiorites and Late Jurassic biotite granites in the Guangzhou area of the south-east Wuyi-Yunkai orogeny.?Journal of Asian Earth Sciences, 219, 104890，?https://doi.org/10.1016/j.jseaes.2021.104890.

137.?Zhou, J.-S.,?Wang, Q.*, Xu, Y.-G., Cempírek, J., Wang, H., Ma, J.-L., Wei, G.-J., Huang, T.-Y., Zhu, G.-H., and Zhang, L., 2021. Geochronology, petrology, and lithium isotope geochemistry of the Bailongshan granite-pegmatite system, northern Tibet: Implications for the ore-forming potential of pegmatites.?Chemical Geology, 584, 120484，?https://doi.org/10.1016/j.chemgeo.2021.120484.

138.?Li, Q.-W., Nebel-Jacobsen, Y., Zhao, J.-H., Nebel, O., Richter, M., Cawood, P. A.,?Wang, Q.，2021. An early garnet redox-filter as an additive oxidizer in lower continental arc crust traced through Fe isotopes.?Journal?of Geophysical Research: Solid Earth,?126, e2020JB021217. https://doi.org/10.1029/2020JB021217

139.?Dan, W.,?Wang, Q., Murphy, J.B., Zhang, X.-Z., Xu, Y.-G., White, W.M., Jiang, Z.-Q., Ou, Q., Hao, L.-L., Qi, Y. 2021. Short duration of Early Permian Qiangtang-Panjal large igneous province: Implications for origin of the Neo-Tethys Ocean.?Earth and Planetary Science Letters, 568, 117054, https://doi.org/10.1016/j.epsl.2021.117054.

140.?Zhou, J.-S.,?Wang, Q.*, Xing, C.-M., Ma, L., Hao, L.-L., Li, Q.-W., Wang, Z.-L., and Huang, T.-Y., 2021. Crystal growth of clinopyroxene in mafic alkaline magmas.?Earth and Planetary Science Letters, 568, 117005, https://doi.org/10.1016/j.epsl.2021.117005.

141.?Wang, Z.-L., Fan, J.-J.,?Wang, Q.*, Hu, W.-L., Yang, Z.-Y., and Wang, J., 2021. Reworking of juvenile crust beneath the Bangong–Nujiang suture zone: Evidence from Late Cretaceous granite porphyries in Southern Qiangtang, Central Tibet.?Lithos, 390-391, 106097，?https://doi.org/10.1016/j.lithos.2021.106097.

142.?Ma, L.,?Wang, Q., Kerr, A.C., and Tang, G.-J., 2021. Nature of the pre-collisional lithospheric mantle in Central Tibet: Insights to Tibetan Plateau uplift.?Lithos, 388-389, 106076，https://doi.org/10.1016/j.lithos.2021.106076.

143.?Ma, L., Gou, G.-N., Kerr, A.C.,?Wang, Q.*, Wei, G.-J., Yang, J.-H., and Shen, X.-M., 2021. B isotopes reveal Eocene mélange melting in northern Tibet during continental subduction:?Lithos, 392-393, 106146，https://doi.org/10.1016/j.lithos.2021.106146.

144.?Fan, J.-J.,?Wang, Q.*, Li, J., Wei, G.-J., Ma, J.-L., Ma, L.*, Li, Q.-W., Jiang, Z.-Q., Zhang, L., Wang, Z.-L., and Zhang, L., 2021. Boron and molybdenum isotopic fractionation during crustal anatexis: Constraints from the Conadong leucogranites in the Himalayan Block, South Tibet.?Geochimica et Cosmochimica Acta, 297, 120-142,??https://doi.org/10.1016/j.gca.2021.01.005.

145.?Liu, X.,?Wang, Q.*, Ma, L.*, Gou, G.-N., Ou, Q., Wang, J., 2021. Late?Jurassic?Maofengshan?two‐mica?granites?in?Guangzhou,?South?China:?fractional?crystallization?products?of?metasedimentary‐rock‐derived?magmas.?Mineralogy and Petrology,?115, 323–341,?https://doi.org/10.1007/s00710-020-00733-9.

146.?Yang, Z.-Y.,?Wang, Q.*, Hao, L.-L., Wyman, D. A., Ma, L., Wang, J., Qi, Y., Sun, P., and Hu, W.-L., 2021. Subduction erosion and crustal material recycling indicated by adakites in central Tibet.?Geology, 49 (6), 708–712,?https://doi.org/10.1130/G48486.1.

147.?Hu, W.-L.,?Wang, Q*, Yang, J.-H., Tang, G.-J., Ma, L., Yang, Z.-Y., Qi, Y., and Sun, P., 2020.?Petrogenesis of Late Early Cretaceous high-silica granites from the Bangong–Nujiang suture zone, Central Tibet.?Lithos, 105788,?https://doi.org/10.1016/j.lithos.2020.105788.

148.?Wang, J., Dan, W.*,?Wang, Q.*, Tang, G.J., 2021.?High-Mg# adakitic rocks formed by lower-crustal magma differentiation: mineralogical and geochemical evidence from garnet-bearing diorite porphyries in central Tibet.?Journal of Petrology,?62(4), egaa099, https://doi.org/10.1093/petrology/egaa099.

149.?Hao L.-L.,?Wang, Q*, Kerr A. C., Yang J.-H., Ma L., Qi Y., Wang J., and Ou Q. 2021.?Post-collisional crustal thickening and plateau uplift of southern Tibet: Insights from Cenozoic magmatism in the Wuyu area of the eastern Lhasa block.?GSA Bulletin, 133 (7-8), 1634–1648, https://doi.org/10.1130/B35659.1.

150.?Zhang, L.,?Wang, Q., Ding, X., and Li, W.-C., 2021. Diverse serpentinization and associated abiotic methanogenesis within multiple types of olivine-hosted fluid inclusions in orogenic peridotite from northern Tibet.?Geochimica et Cosmochimica Acta,?296, 1–17，?https://doi.org/10.1016/j.gca.2020.12.016.

151.?Wang, J.,?Wang, Q.*, and Dan, W.*, 2021. Reply to comment by Vind et al. on “the role of clinopyroxene in amphibole fractionation of arc magmas: Evidence from mafic intrusive rocks within the Gangdese arc, southern Tibet”.?Lithos, 380-381, 105721，?https://doi.org/10.1016/j.lithos.2020.105721.

152.?Dan W.,?Wang Q., White W.M., Li X.H., Zhang X.Z., Tang G.J., Ou Q., Hao L.L., Qi Y., 2021.?Passive-margin magmatism caused by enhanced slab-pull forces in central Tibet.?Geology,?49 (2): 130–134,?https://doi.org/10.1130/G47957.1?

153.?Qi, Y., Hawkesworth, C. J.,?Wang, Q*, Wyman, D. A., Li, Z.X., Dong, H., Ma, T., Chen, F., Hu, W.L., and Zhang, X.Z., 2021.?Syn-collisional magmatic record of Indian steep subduction by 50 Ma.?GSA Bulletin,?133 (5-6), 949–962,?https://doi.org/10.1130/B35498.1.

154.?Ou, Q.,?Wang, Q*, Zeng, J., Yang, J., Zhang, H., Xia, X., Chen, Y. 2021.?Petrogenesis and tectonic implications of Middle Triassic basalts and rhyolites in the northern Qiangtang Block, central Tibet.?Journal of Asian Earth Sciences, 206, 104573,?https://doi.org/10.1016/j.jseaes.2020.104573.

155.?Fan, J.J.,?Wang, Q.*, Li, J., Wei, G., Derek, W., Zhao, Z., Liu, Y., Ma, J., Zhang, L., Wang, Z., 2021.?Molybdenum and Boron isotopic compositions of porphyry Cu mineralization-related adakitic rocks in central-eastern China: New insights into their petrogenesis and crust‐mantle interaction.?Journal of Geophysics Research: Solid Earth,?125, e2020JB020474,?https://doi.org/10.1029/2020JB020474.

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156.?Yan, H.Y., Long, X.P., Li, J.,?Wang, Q., Wang, X.C., Wu, B., Wang, J.Y., and Gou, L.L., 2020, Miocene adakites in south Tibet: Partial melting of the thickened Lhasa juvenile mafic lower crust with the involvement of ancient Indian continental crust compositions.?GSA Bulletin,?132, 1273-1290, https://doi.org/10.1130/B35239.1.

157.?Xu, Y.*, Wang, Q., Tang, G., Wang, J., Li, H., Zhou, J., Li, Q., Qi, Y., Liu, P., Ma, L., and Fan, J., 2020. The origin of arc basalts: New advances and remaining questions.?SCIENCE CHINA Earth Sciences, . 63, 1969-1991，https://doi.org/10.1007/s11430-020-9675-y. (徐義剛,?王強,?唐功建,?王軍,?李洪顏,?周金勝,?李奇維,?齊玥,?劉平平,?馬林,?范晶晶, 2020.?弧玄武巖的成因:?進展與問題.?中國科學:?地球科學, 50(12)::?1818-1844,?https://doi.org/10.1360/SSTe-2020-0032)

158.?Wang, Q*, Hao, L., Zhang, X., Zhou, J., Wang, J., Li, Q., Ma, L., Zhang, L., Qi, Y., Tang, G., Dan, W., and Fan, J., 2020.?Adakitic rocks at convergent plate boundaries: Compositions and petrogenesis.?SCIENCE CHINA Earth Sciences, 63, 1992-2016,?https://doi.org/10.1007/s11430-020-9678-y?（王強*,?郝露露,?張修政,?周金勝,?王軍,?李奇維,?馬林,?張龍,?齊玥,?唐功建,?但衛(wèi),?范晶晶., 2020.?匯聚板塊邊緣的埃達克質巖:?成分和成因.?中國科學:?地球科學, 50(12): 1845-1873,?https://doi.org/10.1360/SSTe-2020-0034）

159.?Zhou, J.-S., Yang, Z.-S.*,?Wang, Q*, Zheng, Y.-C., Hou, Z.-Q., Wyman, D.A., 2020. Extraction of high-silica granites from an upper crustal magma reservoir: insights from the Narusongduo magmatic system, Gangdese arc.?American Mineralogist,?105, 1572-1584，?DOI: https://doi.org/10.2138/am-2020-7369.

160.?Liu, X.,?Wang, Q*, Ma, L., Yang, J.-H., Gou, G.-N., Ou, Q., and Wang, J., 2020.?Early Paleozoic intracontinental granites in the Guangzhou region of South China: Partial melting of a metasediment-dominated crustal source.?Lithos, 376-377, 105763，?https://doi.org/10.1016/j.lithos.2020.105763.

161.?Wang, Q.*, Tang, G., Hao, L., Wyman, D., Ma, L., Dan, W., Zhang, X., Liu, J., Huang, T., Xu, C., 2020.?Ridge subduction, magmatism and metallogenesis.?Science in China Earth Sciences, 63(10): 1499–1518,?https://doi.org/10.1007/s11430-019-9619-9. (王強,?唐功建,?郝露露, DerekWYMAN,?馬林,?但衛(wèi),?張修政,?劉金恒,?黃彤宇,?許傳兵., 2020.?洋中脊或海嶺俯沖與巖漿作用及金屬成礦.?中國科學:?地球科學, 50（10）: 1401 ~ 1423, doi: 10.1360/SSTe-2019-0194)

162.?Zhou, J.-S.,?Wang, Q*, Wyman, D. A., Zhao, Z.-H., 2020.?Petrologic reconstruction of the Tieshan magma plumbing system: Implications for the genesis of magmatic-hydrothermal ore deposits within originally water-poor magmatic systems.?Journal of Petrology, 61(5), egaa056,https://doi.org/10.1093/petrology/egaa056.

163.?Fan, J.-J., Li, J.,?Wang, Q., Zhang, L., Zhang, J., Zeng, X.-L., Ma, L., and Wang, Z.-L., 2020.?High-precision molybdenum isotope analysis of low-Mo igneous rock samples by MC–ICP–MS.?Chemical Geology, 545, 119648,?https://doi.org/10.1016/j.chemgeo.2020.119648.

164.?Liu, X.,?Wang, Q. *,?Ma, L. *, Yang, Z.-Y., Hu, W.-L., Ma, Y.-M., Wang, J., and Huang, T.-Y., 2020.?Petrogenesis of Late Jurassic two-mica granites and associated diorites and syenite porphyries in Guangzhou, SE China.?Lithos,?364-365,?105537，https://doi.org/10.1016/j.lithos.2020.105537.

165.?Li, Q.-W., Zhao, J.-H.*,?Wang, Q.*, Zhang, Z.-F., An, Y.-J., and He, Y.-T., 2020.?Iron isotope fractionation in hydrous basaltic magmas in deep crustal hot zones.?Geochimica et Cosmochimica Acta, 279, 29-44,https://doi.org/10.1016/j.gca.2020.03.032.

166.?Qi, Y.,?Wang, Q.*, Zhu, Y.-T., Shi, L.-C., and Yang, Y.-N., 2020.?Miocene olivine leucitites in the Hoh Xil Basin, northern Tibet: implications for intracontinental lithosphere melting and surface uplift of the Tibetan Plateau.?Journal of Petrology,?61(2),?egaa026,?https://doi.org/10.1093/petrology/egaa026.

167.?Tang, G.-J.,?Wang, Q., Wyman, D.A., Dan, W., Ma, L., Zhang, H.-X., and Zhao, Z.-H., 2020.?Petrogenesis of the Ulungur Intrusive Complex, NW China, and Implications for Crustal Generation and Reworking in Accretionary Orogens.?Journal of Petrology,?61(2),?egaa018,?https://doi.org/10.1093/petrology/egaa018.

168.?Sun, P., Dan, W.,?Wang, Q.*, Tang, G.-J.*, Ou, Q., Hao, L.-L., and Jiang, Z.-Q., 2020. Zircon U–Pb geochronology and Sr–Nd–Hf–O isotope geochemistry of Late Jurassic granodiorites in the southern Qiangtang block, Tibet: Remelting of ancient mafic lower crust in an arc setting??Journal of Asian Earth Sciences, 192, 104235,?https://doi.org/10.1016/j.jseaes.2020.104235.

169.?Liu, X.,?Wang, Q.*, Ma, L.*, Wyman, D.A., Zhao, Z.-H., Yang, J.-H., Zi, F., Tang, G.-J., Dan, W., and Zhou, J.-S. 2020.?Petrogenesis of Late Jurassic Pb–Zn mineralized high δ¹⁸O granodiorites in the western Nanling Range, South China.?Journal of Asian Earth Sciences, 192, 104236,?https://doi.org/10.1016/j.jseaes.2020.104236.

170.?Dan, W.,?Wang, Q., Zhang, X.-Z., and Tang, G.-J., 2020.?Early Paleozoic S-type granites as the basement of Southern Qiantang Terrane, Tibet.?Lithos, 356-357, 105395，https://doi.org/10.1016/j.lithos.2020.105395

171.?Fan, J.-J., Tang, G.-J.*, Wei, G.-J., Wang, H., Xu, Y.-G.,?Wang, Q.*, Zhou, J.-S., Zhang, Z.-Y., Huang, T.-Y., and Wang, Z.-L., 2020.?Lithium isotope fractionation during fluid exsolution: Implications for Li mineralization of the Bailongshan pegmatites in the West Kunlun, NW Tibet.?Lithos, 352-353, 105236，https://doi.org/10.1016/j.lithos.2019.105236.

172.?Ou, Q.,?Wang, Q.*, Zhang, C., Zhang, H.-X.*, Hao, L.-L., Yang, J.-H., Lai, J.-Q., Dan, W., Jiang, Z.-Q., Xia, X.-P., 2020.?Petrogenesis of late Early Oligocene trachytes in central Qiangtang Block, Tibetan Plateau: crustal melting during lithospheric delamination??International Geology Review, 62, 225-242, DOI: 10.1080/00206814.2019.1597391.

173.?Zhou, J.-S., Yang, Z.-S., Hou, Z.-Q.,?Wang, Q., 2020.?Amphibole-rich cumulate xenoliths in the Zhazhalong intrusive suite, Gangdese arc: Implications for the role of amphibole fractionation during magma evolution.?American Mineralogist?105, 262-375. https://doi.org/10.2138/am-2020-7199.

2019?

174.?Yang, Z.-Y.,?Wang, Q.*, Yang, J.-H., Dan, W., Zhang, X.-Z., Ma, L., Qi, Y., Wang, J., and Sun, P. 2019.?Petrogenesis of Early Cretaceous granites and associated microgranular enclaves in the Xiabie Co area, central Tibet: Crust-derived magma mixing and melt extraction.?Lithos,?350-351：105199~105220,?https://doi.org/10.1016/j.lithos.2019.105199.

175.?Tang, G.-J.,?Wang, Q., Wyman, D.A., and Dan, W. 2019.?Crustal maturation through chemical weathering and crustal recycling revealed by Hf–O–B isotopes.?Earth and Planetary Science Letters,?524:?115709~115718,?https://doi.org/10.1016/j.epsl.2019.115709.

176.?Ma, L.*, Kerr, A.C.,?Wang, Q.*, Jiang, Z.-Q., Tang, G.-J., Yang, J.-H., Xia, X.-P., Hu, W.-L., Yang, Z.-Y., and Sun, P. 2019. Nature and Evolution of Crust in Southern Lhasa, Tibet: Transformation From Microcontinent to Juvenile Terrane.?Journal of Geophysical Research: Solid Earth, 124: 6452-6474?https://doi.org/10.1029/2018JB017106.

177.?Wang, Z., Li, J., Wei, G., Deng, W., Chen, X., Zeng, T., Wang, X., Ma, J., Zhang, L., Tu, X.,?Wang, Q., and McCulloch, M. 2019.?Biologically controlled Mo isotope fractionation in coral reef systems.?Geochimica et Cosmochimica Acta, 262, 128-142,?https://doi.org/10.1016/j.gca.2019.07.037.

178.?Hao, L.-L.,?Wang, Q.*, Wyman, D.A., Yang, J.-H., Huang, F., and Ma, L. 2019. Crust-mantle mixing and crustal reworking of southern Tibet during Indian continental subduction: Evidence from Miocene high-silica potassic rocks in Central Lhasa block. Lithos, 342-343: 407-419,?https://doi.org/10.1016/j.lithos.2019.05.035.

179.?Hu, W.-L.,?Wang, Q.*, Yang, J.-H., Zhang, C., Tang, G.-J., Ma, L., Qi, Y., Yang, Z.-Y., and Sun, P. 2019.?Late early Cretaceous peraluminous biotite granites along the Bangong–Nujiang suture zone, Central Tibet: Products derived by partial melting of metasedimentary rocks??Lithos, 344-345: 147-158,?https://doi.org/10.1016/j.lithos.2019.06.005.

180.?Wang, J.,?Wang, Q.*, Dan*, W., Yang, J.-H., Yang, Z.-Y., Sun, P., Qi, Y., Hu, W.-L. 2019.?The role of clinopyroxene in amphibole fractionation of arc magmas: Evidence from?mafic intrusive rocks within the Gangdese arc, southern Tibet.?Lithos,?338–339, 174-188,?https://doi.org/10.1016/j.lithos.2019.04.013.

181.?Wu, H., Chen,J.W.,?Wang, Q., Yu, Y.P. 2019.?Spatial and temporal variations in the geochemistry of Cretaceous high-Sr/Y rocks in central Tibet.?American Journal of Science, 319:105-121, doi: 10.2475/02.2019.02.

182.?Ou, Q.,?Wang, Q.*, Wyman, D. A., Zhang, C., Hao, L.-L., Dan, W., Jiang, Z.Q., Wu, F.-Y., Yang, J.-H., Zhang, H.-X., Xia, X.-P., Ma, L., Long, X.-P, Li, J. 2019. Postcollisional delamination and partial melting of enriched lithospheric mantle: Evidence from Oligocene (ca. 30 Ma) potassium-rich lavas in the Gemuchaka area of the central Qiangtang Block, Tibet.?Geological Society of American Bulletin, 2019, 131(7/8): 1385–1408, doi.org/10.1130/B31911.1.

183.?Hao, L.-L.,?Wang, Q.*,?Zhang, C., Ou, Q., Yang, J.-H., Dan, W., Jiang, Z.-Q. 2019.?Oceanic plateau subduction?during closure of?Bangong-Nujiang?Tethys: Insights from Central Tibetan volcanic rocks.?Geological Society of American Bulletin, 131(5/6), 864–880,?doi:?10.1130/B32045.1.

184.?Ma, Y.*,?Wang, Q.*, Wang, J., Yang, T., Tan, X., Dan, W., Zhang,X.Z., Ma, L., Wang, Z.L.,? Hu,W.L., Zhang, S.H., Wu, H.C., Li, H.Y., Cao, L.W. 2019. Paleomagnetic constraints on the origin and drift history of the North Qiangtang terrane in the Late Paleozoic.?Geophysical Research Letters, 46, 689–697.?https://doi.org/10.1029/2018GL080964.

185.?Yan, H., Long, X., Li, J.,?Wang, Q., Zhao, B., Shu, C., Gou, L., and Zuo, R. 2019. Arc andesitic rocks derived from partial melts of mélange diapir in subduction zones: evidence from whole-rock geochemistry and Sr-Nd-Mo isotopes of the Paleogene Linzizong volcanic succession in southern Tibet.?Journal of Geophysical Research: Solid Earth, 124, 456–475. https://doi.org/10.1029/2018JB016545.

186.?Hao, L.-L.,?Wang, Q.*, Wyman, D. A., Ma, L., Wang, J., Xia, X.-P., and Ou, Q. 2019. First identification of postcollisional A-type magmatism in the Himalayan-Tibetan orogen.?Geology, 47 (2): 187–190，https://doi.org/10.1130/G45526.1.

187.?Dan, W.,?Wang, Q., Li, X.-H., Tang, G.-J., Zhang, C., Zhang, X.-Z., and Wang, J. 2019.?Low δ¹⁸O magmas in the carboniferous intra-oceanic arc, central Tibet: Implications for felsic magma generation and oceanic arc accretion.?Lithos, 326-327, 28-38.

188.?Yang, Z.-Y.,?Wang, Q.*, Zhang, C., Yang, J.-H., Ma, L., Wang, J., Sun, P., and Qi, Y. 2019.?Cretaceous (~100?Ma) high-silica granites in the Gajin area, Central Tibet: Petrogenesis and implications for collision between the Lhasa and Qiangtang Terranes.?Lithos, 324-325, 402-417.

2018

189.?Ma, Y., Yang, T., Bian, W., Jin, J.,?Wang, Q., Zhang, S., Wu, H., Li, H., Cao, L. 2018. A stable southern margin of Asia during the Cretaceous: Paleomagnetic constraints on the Lhasa-Qiangtang collision and the maximum width of the Neo-Tethys.?Tectonics, 37, 3853–3876, DOI: 10.1029/2018TC005143.

190.?Shen, X. M., Zhang,H. X.,?Wang, Q., Saha, A., Ma, L. 2018. Zircon U-Pb geochronology and geochemistry of Devonian plagiogranites in the Kuerti area of southern Chinese Altay, northwest China: Petrogenesis and tectonic evolution of late Paleozoic ophiolites.?Geological Journal, 53(5): 1886-1905.

191.?Wang, J.,?Wang, Q.*,?Zhang, C.,?Dan, W.*, Qi, Y., Zhang, X.-Z.,?Xia, X.-P. 2018.?Late Permian bimodal volcanic rocks in the northern Qiangtang Terrane, central Tibet: evidence for interaction between the Emeishan plume and the Paleo-Tethyan subduction system.?Journal of Geophysical Research: Solid Earth, 123, 123, 6540–6561, DOI:10.1029/2018JB015568.

192.?Yang, Q., Xia, X., Zhang, W., Zhang, Y., Xiong, B., Xu, Y.,?Wang, Q., and Wei, G. 2018. An evaluation of precision and accuracy of SIMS oxygen isotope analysis.?Solid Earth Sciences, 3, 81-86.

193.?Hao, L.L.,?Wang, Q.*, Wyman, D. A., Qi, Y., Ma, L., Huang, F., Zhang, L., Xia, X. P., Ou, Q. 2018. First identification of mafic igneous enclaves in Miocene lavas?of southern Tibet with implications for?Indian continental subduction.?Geophysical Research Letters, 45, 8205–8213, doi: 10.1029/2018GL079061.

194.?Yang, Z. Y.,?Wang, Q.*, Zhang, C., Dan, W., Zhang, X. Z., Qi, Y.,?Xia, X.-P.,?Zhao, Z. H. 2018.?Rare earth element tetrad effect and negative Ce anomalies of the granite porphyries in southern Qiangtang Terrane, central Tibet: New insights into the genesis of highly evolved granites.?Lithos,?312–313, 258–273. doi: 10.1016/j.lithos.2018.04.018.

195.?Dan, W.,?Wang, Q., Zhang, X.-Z., Zhang, C., Tang, G.-J., Wang, J., Ou, Q., Hao, L.-L., and Qi, Y., 2018, Magmatic record of Late Devonian arc-continent collision in the northern Qiangtang, Tibet: Implications for the early evolution of East Paleo-Tethys Ocean.?Lithos, 308-309, 104-117.

196.?Qi, Y., Gou, G.-N.,?Wang, Q.*, Wyman, D.A., Jiang, Z.-Q., Li, Q.-L., and Zhang, L., 2018, Cenozoic mantle composition evolution of southern Tibet indicated by Paleocene (~64Ma) pseudoleucite phonolitic rocks in central Lhasa terrane.?Lithos, 302-303, 178-188,?DOI:?10.1016/j.lithos.2017.12.021.

198.?Wang, J., Gou, G.-N.,?Wang, Q.*, Zhang, C., Dan, W.?*, Wyman, D.A., and Zhang, X.-Z., 2018, Petrogenesis of the Late Triassic diorites in the Hoh Xil area, northern Tibet: Insights into the origin of the high-Mg# andesitic signature of continental crust.?Lithos, 300-301, 348-360, DOI: 10.1016/j.lithos.2017.12.007.

199.?Dan, W.,?Wang, Q., White, W.M., Zhang, X.-Z., Tang, G.-J., Jiang, Z.-Q., Hao, L.-L., and Ou, Q. 2018. Rapid formation of eclogites during a nearly closed ocean: Revisiting the Pianshishan eclogite in Qiangtang, central Tibetan Plateau.?Chemical Geology, 477, 112-122., DOI: 10.1016/j.chemgeo.2017.12.012.

200.?Ma, L.*, Kerr, A.C.,?Wang, Q.*, Jiang, Z.Q., Hu, W.L. 2018. Early Cretaceous (~140 Ma) aluminous A-type granites in the Tethyan Himalaya, Tibet: products of crust-mantle interaction during lithospheric extension.?Lithos, 300-301, 212-226,?DOI: 10.1016/j.lithos.2017.11.023

201.?Wu, H., Qiangba, Z., Li, C.,?Wang, Q., Gesang, W., Ciren, O., and Basang, D. 2018. Geochronology and Geochemistry of Early Cretaceous Granitic Rocks in the Dongqiao Area, Central Tibet: Implications for Magmatic Origin and Geological Evolution.?The Journal of Geology, 126, 249-260,?DOI: 10.1086/695702.

2017

202.?Ma, L.*,?Wang, Q.*, Kerr, A.C., Yang, J.-H., Xia, X.-P., Ou, Q., Yang, Z.-Y., Sun, P. 2017. Paleocene (c. 62 Ma) Leucogranites in Southern Lhasa, Tibet: Products of Syn-collisional Crustal Anatexis during Slab Roll-back??Journal of Petrology, 58(11), 2089–2114, doi: 10.1093/petrology/egy001.

203.?Ma, Y., Yang, T., Bian, W., Jin, J.,?Wang, Q., Zhang, S., Wu, H., Li, H., Cao, L., Yuan, H., and Ding, J. 2017.?Paleomagnetic and Geochronologic Results of Latest Cretaceous Lava Flows From the Lhasa Terrane and Their Tectonic Implications.?Journal of Geophysical Research: Solid Earth, 122, 8786-8809,?DOI: 10.1002/2017JB014743.

204.?Zhang, X.-Z.,?Wang, Q.*, Dong, Y.-S., Zhang, C., Li, Q.-Y., Xia, X.-P., and Xu, W. 2017.?High-Pressure Granulite Facies Overprinting During the Exhumation of Eclogites in the Bangong-Nujiang Suture Zone, Central Tibet: Link to Flat-Slab Subduction.?Tectonics, 36, 2918-2935, doi:10.1002/2017TC004774.

205.?Tang, G.-J., Cawood, P. A., Wyman, D. A.,?Wang, Q., & Zhao, Z.-H. 2017. Evolving mantle sources in postcollisional early Permian-Triassic magmatic rocks in the heart of Tianshan Orogen (western China).?Geochemistry, Geophysics, Geosystems,?18, 4110–4122. doi:10.1002/2017GC006977.

206.?Tang, G.-J.,?Q. Wang, C. Zhang, D. A. Wyman, W. Dan, X.-P. Xia, H.-Y. Chen, and Z.-H. Zhao. 2017.?Sr-Nd-Hf-O isotope geochemistry of the Ertaibei pluton, East Junggar, NW China: Implications for development of a crustal-scale granitoid pluton and crustal growth,?Geochemistry Geophysics Geosystems,?18, 3340–3358, doi:10.1002/2017GC006998.

207.?Huang, C.-C., Guo, H.-F., Li, J.,?Wang, Q.*, Zhang, C., Wyman, D., and Tang, G.-J. 2017.?Re–Os isotope geochronology of the Shangbao pyrite–flourite deposit in southeastern Hunan, South China: Evidence for multiple mineralization events and the role of crust–mantle interaction in polymetallic deposits.?Solid Earth Sciences, 2, 109-122, doi: 10.1016/j.sesci.04.001

208.?Chen, B., Long, X., Wilde, S.A., Yuan, C.,?Wang, Q., Xia, X., and Zhang, Z. 2017. Delamination of lithospheric mantle evidenced by Cenozoic potassic rocks in Yunnan, SW China: A contribution to uplift of the Eastern Tibetan Plateau.?Lithos, 284-285, 709-729, DOI:?10.1016/j.lithos.2017.05.019.

209.?Gou, G.-N.,?Wang, Q.*, Wyman, D.A., Xia, X.-P., Wei, G.-J., and Guo, H.-F. 2017.?In situ boron isotopic analyses of tourmalines from Neogene magmatic rocks in the northern and southern margins of Tibet: Evidence for melting of continental crust and sediment recycling.?Solid Earth Sciences, 2, 43-54, doi: 10.1016/j.sesci.2017.03.003.

210.?Tang, G.-J.,?Wang, Q., Wyman, D.A., Chung, S.-L., Zhao, Z.-H. 2017.?Genesis of pristine adakitic magmas by lower crustal melting: A perspective from amphibole composition.?Journal Geophysical Research-Solid Earth, 122,?1934–1948,?doi:10.1002/2016JB013678.

211.?Tang, G.-J., Chung, S.-L., Hawkesworth, C.J., Cawood, P.A.,?Wang, Q., Wyman, D.A., Xu, Y.-G., Zhao, Z.-H. 2017. Short episodes of crust generation during protracted accretionary processes: Evidence from Central Asian Orogenic Belt, NW China.?Earth and Planetary Science Letters?464, 142–154, doi: 10.1016/j.epsl.2017.02.022.

212.?Ou, Q.,?Wang, Q.*, Wyman, D. A., Zhang, H.-X.*, Yang, J.-H., Zeng, J.-P., Hao, L.-L., Chen, Y.-W., Liang, H., and Qi, Y. 2017.?Eocene adakitic porphyries in the central-northern Qiangtang Block, centralTibet: Partial melting of thickened lower crust and implications for initial surface uplifting of the plateau.?Journal of Geophysical Research—Solid Earth, 122, 1025–1053, doi:10.1002/2016JB013259.

213.?He, Y., Wu, H., Ke, S., Liu, S.-A., and?Wang, Q.?2017. Iron isotopic compositions of adakitic and non-adakitic granitic magmas: Magma compositional control and subtle residual garnet effect.?Geochimica et Cosmochimica Acta, 203, 89-102.

214.?Zhang, X.-Z.*, Dong,?Y.-S.,?Wang, Q.*, Dan , W., Zhang, C., Xu, W., Huang, M.-L. 2017.?Metamorphic records for subduction erosion and subsequent underplating processes revealed by garnet-staurolite-muscovite schists in central Qiangtang, Tibet.?Geochemistry Geophysics Geosystems, 18, 266-279,?DOI:10.1002/2016GC006576.

215.?Ma, L.,?Wang, Q.*, Li, Z.-X., Wyman, D. A., Yang, J.-H., Jiang, Z.-Q., Liu, Y.-S., Gou, G.-N., Guo, H.-F. 2017.?Subduction of Indian continent beneath southern Tibet in the latest Eocene (~ 35 Ma): insights from the Quguosha gabbros in southern Lhasa block.?Gondwana Research, 41, 77–92,?http://dx.doi.org/10.1016/j.gr.2016.02.005.

2016

216.?Wang, Q.*, Hawkesworth, C. J.?*, Wyman, D., Chung, S.-L., Wu, F.-Y. Li, X.-H., Li, Z.-X., Gou, G.-N., Zhang, X.-Z., Tang, G.-J., Dan, W., Ma, L., Dong, Y.-H. 2016. Pliocene–Quaternary crustal melting in central and northern Tibet and insights into crustal flow.?Nature Communications, 7:11888, doi: 10.1038/ncomms11888.

217.?Hao, L.-L.,?Wang, Q.*, Wyman, D. A., Ou, Q., Dan, W., Jiang, Z.-Q., Yang, J.-H., Long, X.-P., Li, J. 2016.?Partial melting of the mélange for the growth of andesitic crust indicated by the Early Cretaceous arc dioritic/andesitic rocks in southern Qiangtang, central Tibet.?Geochemistry Geophysics Geosystems,?17, doi:10.1002/2016GC006248.

218.?Hao, L.-L.,?Wang, Q.*, Wyman, D. A., Ou, Q., Dan, W., Jiang, Z.-Q., Wu, F.-Y., Yang, J.-H., Long, X.-P., and Li, J. 2016. Underplating of basaltic magmas and crustal growth in a continental arc: Evidence from Late Mesozoic intermediate–felsic intrusive rocks in southern Qiangtang, central Tibet.?Lithos, 245, 223-242,?doi:10.1016/j.lithos.2015.1009.1015.

219.?Dan, W.*, Li, X.-H.,?Wang, Q.*, Wang, X.-C., Wyman, D. A., and Liu, Y. 2016. Phanerozoic amalgamation of the Alxa Block and North China Craton: Evidence from Paleozoic granitoids, U–Pb geochronology and Sr–Nd–Pb–Hf–O isotope geochemistry.?Gondwana Research, 32，105-121，doi:10.1016/j.gr.2015.1002.1011.

220.?Zhang, X. Z.*, Dong, Y. S.,?Wang, Q.*, Dan, W., Zhang, C., Deng, M.R., Xu, W., Xia, X.P., Zeng, J.P. and Liang, H. 2016. Carboniferous and Permian evolutionary records for the Paleo-Tethys Ocean constrained by newly discovered Xiangtaohu ophiolites from central Qiangtang, central Tibet.?Tectonics, 35(7), 1670-1686.

221.?Yan, H., Long, X., Wang, X.-C., Li, J.,?Wang, Q., Yuan, C., and Sun, M. 2016. Middle Jurassic MORB-type gabbro, high-Mg diorite, calc-alkaline diorite and granodiorite in the Ando area, central Tibet: Evidence for a slab roll-back of the Bangong-Nujiang Ocean.?Lithos, 264, 315-328.

2015

222.?Ma, L.,?Wang, Q.*, Wyman, D. A., Jiang, Z.-Q., Wu, F.-Y., Li, X.-H., Yang, J.-H., Gou, G.-N., Guo, H.-F. 2015. Late Cretaceous back-arc extension and arc system evolution in the Gangdese area, southern Tibet: Geochronological, petrological, and Sr-Nd-Hf-O isotopic evidence from Dagze diabases.?Journal of Geophysical Research, 120, 6159–6181，doi: 10.1002/2015JB011966.

223.?Dan, W.?*,?Wang, Q.*, Wang, X.-C., Liu, Y., Wyman, D. A., Liu, Y.-S. 2015.?Overlapping Sr–Nd–Hf–O isotopic compositions in Permian mafic enclaves and host granitoids in Alxa Block, NW China: Evidence for crust–mantle interaction and implications for the generation of silicic igneous provinces.?Lithos, 230，133–145.

224.?Jiang, Z.,?Wang, Q.*, Wyman, D., Shi, X., Yang, J.-H., Ma, L., and Gou, G. 2015. Zircon U–Pb geochronology and geochemistry of Late Cretaceous–Early Eocene granodiorites in the southern Gangdese Batholith of Tibet: Petrogenesis and implications for geodynamics and Cu ± Au ± Mo mineralization.?International Geology Review,?57(3), 373–392, DOI: 10.1080/00206814.2015.1009503.

225.?Li, J., Wang, X.-C., Xu, J.-F., Xu, Y.-G., Tang, G.-J.,?Wang., Q.?2015.?Disequilibrium-induced initial Os isotopic heterogeneity in gramaliquots of single basaltic rock powders: Implications for dating and source tracing. Chemical Geology 406, 10–17.

226.?Long, X., Wilde, S. A.,?Wang, Q., Yuan, C., Wang, X.-C., Li, J., Jiang, Z., and Dan, W. 2015.?Partial melting of thickened continental crust in central Tibet: Evidence from geochemistry and geochronology of Eocene adakitic rhyolites in the northern Qiangtang Terrane.?Earth and Planetary Science Letters, 414(0), 30-44.

2014

227.?Dan, W.*, Li, X.-H.,?Wang, Q.*, Wang, X.-C., Liu, Y., and Wyman, D. A. 2014.?Paleoproterozoic S-type granites in the Helanshan Complex, Khondalite Belt, North China Craton: Implications for rapid sediment recycling during slab break-off.?Precambrian Research, 254, 59–72, DOI: 10.1016/j.precamres.2014.1007.1024.

228.?Guan, Y., Yuan, C., Sun, M., Wilde, S., Long, X., Huang, X., and?Wang, Q.?2014. I-type Granitoids in the Eastern Yangtze Block: Implications for the Early Paleozoic Intracontinental Orogeny in South China.?Lithos,?206-207, 34-51,?DOI: 10.1016/j.lithos.2014.1007.1016.

229.?Shen, X.-M., Zhang, H.-X.,?Wang, Q., Ma, L., and Yang, Y.-H. 2014. Early Silurian (~440Ma) adakitic, andesitic and Nb-enriched basaltic lavas in the southern Altay Range, Northern Xinjiang (western China): Slab melting and implications for crustal growth in the Central Asian Orogenic Belt.?Lithos, 206-207: 234-251,?DOI: 10.1016/j.lithos.2014.1007.1024.

230.?Tang, G.-J., Chung, S.-L.,?Wang, Q., Wyman, D. A., Dan, W., Chen, H.-Y., and Zhao, Z.-H. 2014.?Petrogenesis of a Late Carboniferous mafic dike–granitoid association in the western Tianshan: Response to the geodynamics of oceanic subduction.?Lithos?202–203, 85-99.

231.?Jiang, Z.Q.,?Wang, Q.*, Wyman, D. A., Li, Z. X., Yang, J. H., Shi, X.B., Ma, L., Tang, G. J., Gou, G. N., Jia, X. H., Guo, H. F. 2014. Transition from oceanic to continental lithosphere subduction in southern Tibet: Evidence from the Late Cretaceous–Early Oligocene (~ 91–30 Ma) intrusive rocks in the Chanang–Zedong area, southern Gangdese.?Lithos,?196-197, 213-231,?doi:?10.1016/j.lithos.2014.03.001.

232.?Ma, L., Wang, B. D., Jiang, Z. Q.,?Wang, Q.*, Li, Z. X., Wyman, D. A., Zhao, S. R., Yang, J. H., Gou, G. N., Guo, H. F. 2014.?Petrogenesis of the Early Eocene adakitic rocks in the Napuri area, southern Lhasa:?partial melting of thickened lower crust?during slab break-off and implications for crustal thickening in southern Tibet.?Lithos,?196-197, 321-338,?doi:?10.1016/j.lithos.2014.02.011.

233.?Dan, W.?*, Li, X. H.,?Wang, Q.*, Tang, G. J., Liu, Y. 2014.?An Early Permian (ca. 280 Ma) silicic igneous province in the Alxa Block, NW China: A magmatic flare-up triggered by a mantle-plume??Lithos,?204, 144-158, doi: 10.1016/j.lithos.2014.01.018.

234.?Dan, W., Li, X.H.,?Wang, Q., Wang, X.C., Liu, Y. 2014.?NEOPROTEROZOIC S-TYPE GRANITES IN THE ALXA BLOCK,WESTERNMOST NORTH CHINA AND TECTONIC IMPLICATIONS:IN SITU ZIRCON U-Pb-Hf-O ISOTOPIC AND GEOCHEMICAL CONSTRAINTS.?American Journal of Science, 314, 110-153, DOI 10.2475/01.2014.04.

2013

235.?Huang Z.Y., Long X.P., Kr?ner A., Yuan C.,?Wang Q., Sun M., Zhao G.C., Wang Y.J. 2013. Geochemistry, zircon U–Pb ages and Lu–Hf isotopes of early Paleozoic plutons in the northwestern Chinese Tianshan: Petrogenesis and geological implications.?Lithos,?182-183, 48-66.

236.?Tang, G.J.,?Wang, Q.*, Wyman, D.A., Sun, M., Zhao, Z.H., Jiang, Z.Q. 2013. Petrogenesis of gold-mineralized magmatic rocks of the Taerbieke area, northwestern Tianshan (western China): Constraints from geochronology, geochemistry and Sr-Nd-Pb-Hf isotopic compositions.?Journal of Asian Earth Science,?74, 113-128.

237.?Ma, L.,?Wang, Q.*, Wyman, D.A., Li, Z.X., Jiang, Z.Q., Yang, J.H., Gou, G.N., Guo, H.F. 2013. Late Cretaceous (100-89 Ma) magnesian charnockites with adakitic affinities in the Milin area, eastern Gangdese: partial melting of subducted oceanic crust and implications for crustal growth in southern Tibet.?Lithos, 175–176, 315-332，doi: 10.1016/j.lithos.2013.04.006.

238.?Ma, L.,?Wang, Q.*, Li, Z.X., Wyman, D.A., Jiang, Z.Q., Yang, J.H., Gou, G.N., Guo, H.F., 2013. The early Late Cretaceous (ca. 93 Ma) norites and hornblendites in the Milin area, eastern Gangdese: lithosphere-asthenosphere interaction during slab roll-back and an insight into early Late Cretaceous (ca. 100–80 Ma) magmatic “flare-up” in southern Lhasa (Tibet).?Lithos,?172–173, 17–30, 10.1016/j.lithos.2013.03.007.

239.?Ma, L.,?Wang, Q.*, Wyman, D.A., Jiang, Z.Q., Yang, J.H., Li, Q.L., Gou, G.N., Guo, H.F., 2013. Late Cretaceous crustal growth of southern Tibet: Petrological and Sr-Nd-Hf-O isotopic evidence from the Zhengga diorite-gabbro suites in the Gangdese area.?Chemical Geology,?349–350, 54–70, 10.1016/j.chemgeo.2013.04.005.

2012

240.?Ali, K. A., Moghazi, A.K. M., Maurice, A. E., Omar, S. A.,?Wang, Q., Wilde, S. A., Moussa, E.M., Manton, W. I., Stern, R.J. 2012. Composition, age, and origin of the ~620?Ma Humr Akarim and Humrat Mukbid A-type granites: no evidence for pre-Neoproterozoic basement in the Eastern Desert, Egypt.?International Journal of Earth Sciences, 101(7), 1705-1722,?doi:10.1007/s00531-012-0759-2.

241.?Wang Q., Chung S.L., Li X.H., Wyman D., Li Z.X., Sun W.D., Qiu H.N., Liu Y.S., Zhu Y.T. 2012. Crustal melting and flow beneath northern Tibet: Evidence from Mid-Miocene to Quaternary strongly peraluminous rhyolites in southern Kunlun Range.?Journal of Petrology, 53(12), 2523-2566, doi: 10.1093/petrology/egs058.

242.?Tang, G.J.,?Wang Q.*, Wyman, D.A., Li, Z.X., Xu, Y.G., Zhao, Z.H. 2012. Metasomatized lithosphere-asthenosphere interaction during slab roll-back: Evidence from Late Carboniferous gabbros in the Luotuogou area, Central Tianshan.?Lithos, 155, 67–80，doi: 10.1016/j.lithos.2012.08.015.

243.?Wang Q., Li X.H ., Jia X.H ., Wyman D.A., Tang G.J., Li Z.X., Yang Y.H., Jiang Z.Q., Ma L, Gou G.N. 2012. Late Early Cretaceous adakitic granitoids and associated magnesian and potassium–rich mafic enclaves and dikes in the Tunchang–Fengmu area, Hainan Province (South China): partial melting of lower crust and mantle, and magma hybridization.?Chemical Geology, 328, 222–243, doi:10.1016/j.chemgeo.2012.04.029.

244.?Jiang Z.Q.,?Wang Q.*, Li Z.X., Wyman D.A., Tang G.J., Jia X.H., Yang Y.H. 2012. Late Cretaceous (ca. 90 Ma) adakitic intrusive rocks in the Kelu area, Gangdese belt (southern Tibet): Slab melting and implications for Cu-Au mineralization.?Journal of Asian Earth Science, 53: 67-81, doi:10.1016/j.jseaes.2012.02.010.

245.?Tang G..J.,?Wang Q.*, Wyman D.A., Li Z.-X., Zhao Z.-H., Yang Y.-H. 2012. Late Carboniferous high εNd(t)-εHf(t) granitoids, enclaves and dikes in western Junggar, NW China: ridge-subduction-related magmatism and crustal growth.?Lithos?140-141: 86–102, doi:10.1016/j.lithos.2012.01.025

246.?Tang G..J., Wyman D.A.,?Wang Q.*, Li J., Li Z.X., Zhao ZH., Sun W.D. 2012. Asthenosphere–lithosphere interaction triggered by a slab window during ridge subduction: Trace element and Sr-Nd-Hf-Os isotopic evidence from Late Carboniferous tholeiites in the western Junggar area (NW China).?Earth and Planetary Science Letters?329-330, 84–96, doi:10.1016/j.epsl.2012.02.009.

247.?Tang, G.J.,?Wang Q.*, Wyman D.A., Li Z.X., Xu Y.G., and Zhao Z.H. 2012. Recycling oceanic crust for continental crustal growth: Sr-Nd-Hf isotope evidence from granotoids in the western Junggar region, NW China.?Lithos?128-131, 73-83, dio:10.1016/j.lithos.2011.11.003.

2011

248.?Wang Q., Li Z.X., Chung S.L., Wyman D. A., Sun Y.L., Zhao Z.H., Zhu Y.T., Qiu H.N. 2011. Late Triassic high-Mg andesite/dacite suites from northern Hohxil, North Tibet: Geochronology, geochemical characteristics, petrogenetic processes and tectonic implications.?Lithos?126(1-2), 54-67, doi: 10.1016/j.lithos.2011.06.002

249.?Shen X.M., Zhang H.X.,?Wang Q., Wyman D.A., Yang Y.H. 2011. Late Devonian-Early Permian A-type granites in the southern Altay Range, Northwest China: Petrogenesis and implications for tectonic setting of “A₂-type” granites.?Journal of Asian Earth Sciences?42(5), 986-1007, doi:10.1016/j.jseaes.2010.10.004.

2010

250.?Wang Q., Wyman D.A., Li Z.X., Sun W.D., Chung S.L., Vasconcelos P.M., Zhang Q.Y., Dong H., YuY.S., Pearson N., Qiu H.N., Zhu T.X., Feng X.T. 2010. Eocene north-south trending dikes in central Tibet: New constraints on the timing of east-west extension with implications for early plateau uplift？Earth and Planetary Science Letters,?298: 205–216, doi:10.1016/j.epsl.2010.07.046.

251.?Wang Q., Wyman D.A., Li Z.X., Bao Z.W., Zhao Z.H., Wang Y.X., Jian P., Yang Y.H., Chen L.L. 2010. Petrology, geochronology and geochemistry of ca. 780 Ma A-type granites in South China: Petrogenesis and implications for crustal growth during the breakup of supercontinent Rodinia.?Precambrian Research, 178:185–208, doi:10.1016/j.precamres.2010.02.004.

252.?Tang G.J.,?Wang Q.*, Wyman D.A., Li Z.X., Zhao Z.H., Jia X.H., Jiang Z.Q. 2010. Ridge subduction and crustal growth in the Central Asian Orogenic Belt: Evidence from Late Carboniferous adakites and high-Mg diorites in the western Junggar region, northern Xinjiang (west China).?Chemical Geology,?277: 281–300,?doi:10.1016/j.chemgeo.2010.08.012.

253.?Tang G.J.,?Wang Q.*, Wyman D.A., Sun M., Li Z.X., Zhao Z.H., Sun W.D., Jia X.H., Jiang Z.Q. 2010. Geochronology and geochemistry of Late Paleozoic magmatic rocks in the Lamasu-Dabate area, northwestern Tianshan (west China): evidence for a tectonic transition from arc to post-collisional setting.?Lithos,?119: 393–411,?doi:10.1016/j.lithos.2010.07.010.

2009

254.?Zhao ZH,?Wang Q, Xiong XL, Niu HC, Zhang HX, Qiao YL. 2009. Magnesian andesites in north Xinjiang, China.?International Journal of Earth Science, 98, 1325–1340.

255.?Zhao ZH, Xiong XL,?Wang Q, Bai ZH, Qiao YL, 2009. Late Paleozoic underplating in North Xinjiang: Evidence from shoshonites and adakites.?Gondwana Research, 16, 216-226.

2008

256.?Wang, Q., Wyman, D.A., Xu, J.F., Dong, Y.H., Vasconcelos, P. M., Pearson, N., Wan, Y.S., Dong, H., Li, C.F., Yu, Y.S., Zhu, T.X., Feng, X.T., Zhang, Q.Y., Zi, F., Chu, ZY. 2008. Eocene melting of subducting continental crust and early uplifting of central Tibet: evidence from central-western Qiangtang high-K calc-alkaline andesites, dacites and rhyolites.?Earth and Planetary Science Letters,?272, 158-171, doi: 10.1016/j.epsl.2008.04.034.

257.?Wang Q., Wyman A., Xu J.F., Wan Y.S., Li C.F., Zi F., Jiang Z.Q., Qiu H.N., Chu Z.Y., Zhao Z.H., Dong Y.H. 2008. Triassic Nb-enriched basalts, magnesian andesites, and adakites of the Qiangtang terrane (Central Tibet): evidence for metasomatism by slab-derived melts in the mantle wedge.?Contributions to Mineralogy and Petrology, 155, 473–490.?DOI 10.1007/s00410-007-0253-1.

258.?Bao ZW,?Wang Q,?Bai GD, Zhao ZH, Song YW, Liu XM. 2008. Geochronology and geochemistry of the Fangcheng Neoproterozoic alkali-syenites in East Qinling orogen and its geodynamic implications.?Chinese Science Bulletin, 53?(13),?2050-2061

259.?Zhao, Z.H., Xiong, X.L.,?Wang, Q., Wyman, D.A., Bao, Z.W., Bai, Z.H., and Qiao, Y.L. 2008. Underplating-related adakites in Xinjiang Tianshan, China.?Lithos,?102(1-2): 374-391.

2007

260.?Wang Q., Wyman A., Xu J. F., Jian P., Zhao Z. H., Li C.F., Xu W., Ma J. L., He B. 2007. Early Cretaceous adakitic granites in the Northern Dabie complex, central China: implications for partial melting and delamination of thickened lower crust.?Geochimica et Cosmochimica Acta, 71(10), 2609-2636.

261.?Wang Q.,?Wyman D.A., Zhao Z.H., Xu J.F., Bai Z.H., Xiong X.L., Dai T.M., Li C.F., Chu Z.Y. 2007. Petrogenesis of Carboniferous adakites and Nb-enriched arc basalts in the Alataw area, northern Tianshan Range (western China): Implication for Phanerozoic crustal growth of Central Asia Orogenic Belt.?Chemical Geology,?236(1-2), 42-64.

262.?Wang Q.,?Wyman D. A., Xu J. F., Zhao Z. H., Jian P., Zi F. 2007. Partial melting of thickened or delaminated lower crust in the middle of eastern China: implications for Cu-Au mineralization.?The Journal of Geology, 115(2), 149-161.

2006

263.?Wang Q., Wyman D. A., Xu J. F., Zhao Z. H., Jian P., Xiong X. L., Bao Z.W., Li C. F., Bai Z. H. 2006. Petrogenesis of Cretaceous adakitic and shoshonitic igneous rocks in the Luzong area, Anhui Province (eastern China): Implications for geodynamics and Cu-Au mineralization.?Lithos, 89(3-4), 424-446.

264.?Wang Q.,?Xu J. F., Jian P., Bao Z. W., Zhao Z. H., Li C. F., Xiong X. L., Ma J. L. 2006. Petrogenesis of adakitic porphyries in an extensional tectonic setting, Dexing, South China: implications for the genesis of porphyry copper mineralization.?Journal of Petrology, 47(1), 119-144.

2005

265.?Wang Q., Li J. W., Jian P., Zhao Z. H., Xiong X. L., Bao Z. W., Xu J. F., Li C. F., Ma J. L. 2005.?Alkaline syenites in eastern Cathaysia (South China): link to Permian-Triassic transtension.?Earth and Planetary Science Letters, 230(3-4), 339-354.

266.?Wang Q., McDermott F., Xu J. F., Bellon H., Zhu Y. T. 2005.?Cenozoic K-rich adakitic volcanic rocks in the Hohxil area, northern Tibet: lower crustal melting in an intracontinental setting.?Geology, 33(6), 465-468.

2004

267.?Wang Q., Zhao Z. H., Bao Z. W., Xu J. F., Liu W., Li C. F., Bai Z. H., and Xiong X. L. 2004. Geochemistry and petrogenesis of the Tongshankou and Yinzu adakitic intrusive rocks and the associated porphyry copper-molybdenum mineralization in southeast Hubei, east China.?Resource Geology, 54(2), 137-152.

268.?Wang Q., Xu J. F., Zhao Z. H., Bao Z. W., Xu W., and Xiong X. L. 2004. Cretaceous high-potassium intrusive rocks in the Yueshan-Hongzhen area of east China: adakites in an extensional tectonic regime within a continent.?Geochemical Journal, 38(5), 417-434.

269.?Xu Y. G., Huang X. L., Ma J. L., Wang Y. B., Iizuka Y., Xu J. F.,?Wang Q., Wu X. Y. 2004.?Crust-mantle interaction during the tectono-thermal reactivation of the North China Craton: constraints from SHRIMP zircon U–Pb chronology and geochemistry of Mesozoic plutons from western Shandong.?Contributions to Mineralogy and Petrology, 147, 750–767.

270.?Zhao, Z H, Xiong X L,?Wang Q, Bai Z H, Xu J F, and Qiao Y L. 2004.?The Association of Late Paleozoic Adakitic Rocks and Shoshonitic Volcanic Rocks in Western Tianshan, China.?Acta Geologica Sinica, 78(1), 68-72.

2003

271.?Wang Q., Zhao Z. H., Bai Z. H., Bao Z. W., Xu J. F., Xiong X. L., Mei H. J., Wang Y. X. 2003.?Carboniferous adakites and Nb-enriched arc basaltic rocks association in the Alataw Mountains, north Xinjiang: interactions between slab melt and mantle peridotite and implications for crustal growth.?Chinese Science Bulletin, 48 (19), 2108-2115.

272.?Wang Q., Zhao Z. H., Xu J. F., Li X. H., Bao Z. W., Xiong X. L., Liu Y. M. 2003. Petrologenesis and metallogenesis of the Yanshanian adakite-like rocks in the Eastern Yangtze Block,?Science in China, Series D, 2003, 46(Supp), 164-176

273.?Wang Q., Xu J. F., Zhao Z. H., Xiong X. L., Bao Z. W. 2003.?Petrogenesis of the Mesozoic intrusive rocks in the Tongling Area, Anhui Province, China and constraint to Geodynamics process.?Science in China, Series D, 46(8) , 801-815.

274.?Zhao Z. H., Xiong X. L.,?Wang Q., Bao Z. W. 2003. Alkaline-rich igneous rocks and related large-super large gold-copper mineralization in China.?Science in China, Series D, 46(Supp) , 1-13.

275.?Xiong X. L., Li X. H., Xu J. F., Li W. X., Zhao Z. H.,?Wang Q.?and Chen X. M. 2003. Extremely high-Na adakite-like magmas derived from alkali-rich basaltic underplate: The Late Cretaceous Zhantang andesites in the Huichang Basin, SE China.?Geochemical Journal, 37: 233-252.

276.?Liu Y. M., Xu J. F., Dai T. M., Li X. H., Deng X. G.,?Wang Q. 2003.?⁴⁰Ar/³⁹Ar isotopic ages of Qianlishan granite and their geologic implications.?Science in China, Series D, 2003, 46(Supp), 50-59.

2002

277.?Xu J. F., Shinjio R., Defant M. J.,?Wang Q., Rapp R. P. 2002. Origin of Mesozoic adakitic intrusive rocks in the Ningzhen area of east China: partial melting of delaminated lower continental crust??Geology, 30, 1111-1114.?

278.?Defant M. J., Xu J. F., Kepezhinskas P.,?Wang Q., Zhang Q., Xiao L. 2002.?Adakites: Some Variations on a Theme.?Acta Petrologica Sinica, 18(2), 129-142.

279.?Zhao Z. H., Xiong X. L., Han X. D., Wang Y. X.,?Wang Q., Bao Z. W. 2002.?Controls on the REE tetrad effect in granites: Evidence from the Qianlishan and Baerzhe granites, China.?Geochemical Journal, 36, 527-543.

2001

280.?Wang Q., Zhao Z. H., Qiu J. X., Wang R. J., Xu J. F. 2001.?The Formation of Yanshanian granitic magma in Dabie Mountains: Dehydration or aquifer melting – with Tiantanzhai and Jiuzihe granites as examples.?Continental Dynamics, 6(2), 39-47.

281.?Xiong X. L., Zhao Z. H., Bai Z. H., Mei H. J., Wang Y. X.,?Wang Q., Xu J. F., Bao Z. W. 2001.?Adakite-type sodium-rich rocks in Awulale Mountain of west Tianshan: Significance for the vertical growth of continental crust.?Chinese Science Bulletin, 46(10), 811-817.

282.?Xu J. F., Mei H. J., Yu X. Y., Bai Z. H., Niu H. C., Chen F. R., Zhen Z. P.,?Wang Q. 2001.?Adakites related to subduction in the northern margin of Junggar arc for the Late Paleozoic: Products of slab melting,?Chinese Science Bulletin, 46(15), 1312-1316.

2000

283.?Wang Q.,?Xu J., Wang J., Zhao Z., Qiu J., Wang R., Xiong X., Sang L., Peng L. 2000.?The recognization of adakite-type gneisses in the North Dabie Mountains and its implication to ultrahigh pressure metamorphic geology.?Chinese Science Bulletin, 45(21), 1927-1933.

284.?Xu J. F.,?Wang Q., Yu X. Y. 2000.?Geochemistry of high-Mg Andesite and Adakitic andesite from the Sanchazi block of the Mian-Lue ophiolitic melange in the Qinling Mountains, central China: Evidence of partial melting of the subducted Paleo-Tethyan crust and its implication.?Geochemical Journal,?34, 359-377.

1. 2024–2028，深地國家科技重大專項課題“特提斯構造域巖石圈匯聚過程與淺層響應” (2024ZD1001103)。

2. 2025–2029, 國家基金委重點項目，“東昆侖大格勒古生代鎂鐵質?超鎂鐵質巖?正長巖?碳酸巖雜巖體成因及動力學、成礦意義”(41630208)。