99. Wang, H. B., Huang, Z. C., Wang, Q., Zhao, D. P., Hu, X. M., 2026. New insights into plateau-craton interactions from P and S wave tomography beneath the northeastern Tibetan plateau. Earth and Planetary Science Letters, 684, 120004, https://doi.org/10.1016/j.epsl.2026.120004

98.  Wei, H. Z., Palmer, M. R., Xu, Z. Q., Zhu, W. B., Xu, X.S., Williams-Jones, A., Zheng, B. H., Gao, J. G., Wang, Q., Ma, J., Yang, K., Lin, H. F., Zuo D. S., 2026. Coupled anatexis and extreme differentiation are the keys for producing giant lithium-rich pegmatites. PNAS, 123, e2517372123, https://doi.org/10.1073/pnas.2517372123.

97. Koptev, A., Lavecchia, A., Cloetingh, S., Pons, M., Marzotto, E., Brune, S., Kovács, I., Tesauro M., Beekman, F., Wang, Q., Sobolev, S. V., Faccenna, C., Jolivet, L., 2026. Numerical modeling of purely active (plume‐produced) continental rifting and break‐up. Journal of Geophysical Research: Solid Earth, 131, e2025JB033048. https://doi.org/10.1029/2025JB033048

96. 姚尧，王勤*. 2026. 大火成岩省对陆壳结构、大陆裂解和全球气候变化的影响[J]. 地球与行星物理论评（中英文），57（1）：27-50. doi：10.19975/j.dqyxx.2024-021

2025

95. Wang, L., Wang, Q., Ruan, Y.*, 2025. Monitoring dynamic magma movement in the lower crust during the 2015 eruption of Axial Seamount. Journal of Geophysical Research: Solid Earth, 130, e2024JB030481. https://doi.org/10.1029/2024JB030481

94. Zhao, J., Wang, Q.*, Ruan, Y., Jiang, W., Webb, A. A. G., 2025. Structure, serpentinization and seismic reflectivity of the crust‐mantle boundary at fast‐ and intermediate‐spreading ridges. Journal of Geophysical Research: Solid Earth, 130, e2025JB032120. https://doi.org/10.1029/2025JB032120

93. Hurlow, R., Su, W., Zhou, W.Y., Lin, F., Miyagi, L., Officer, T., Yu, T., Wang Y. B., Wu, M., Wang, Q., Zhang, J. S.*, 2025. In situ deformation of antigorite-olivine two-phase mixtures: Implications for dynamics and seismic anisotropy in the mantle wedge. Earth and Planetary Science Letters, 672, 119719. https://doi.org/10.1016/j.epsl.2025.119719

92. Zhu, H. H.*, Wang, J., Ruan, Y. Y., Wang, Q., Cheng, G., Tan, D. Y., Yang, J. X., Shi, B., 2025. Real-time campus resilience monitoring with distributed acoustic sensing: A case study. Science China Technological Sciences, 68(10): 2020704, https://doi.org/10.1007/s11431-025-3030-7

91. 冀胤霖*，张苏鹏，朱鸿鹄，张振宇，宋先知，王勤. 2025. 深地工程中岩体界面的摩擦-渗流耦合机理与调控技术: 综述与展望. 采矿与岩层控制工程学报, 7(6): 063541, 10.13532/j.jmsce.cn10-1638/td.2025-1186

90. Zhang, L.S., Hui, H. J., Wang, Q.*, Ionov, D. A., 2025. Partial melting-controlled water concentrations in the non-cratonic continental lithospheric mantle (Tariat region, Mongolia). Lithos, 516-517, 108258, https://doi.org/10.1016/j.lithos.2025.108258

89. Deng, X., Wang, Q.*, Lu, S., Wang, H., Lu, Z., Guo, X., Li, H. Q., Gao, R.*. (2025). Fossil subduction zone beneath the eastern Yangtze Craton: Evidence from seismic reflections in the upper mantle. Geophysical Research Letters, 52, e2025GL114975. https://doi.org/10.1029/2025GL114975

88. Wu, M., Wang, Q.*, Wang, H., 2025. Thermal structure, fluid activity and earthquake mechanisms of oceanic subduction zones. Science China Earth Sciences, 68, https://doi.org/10.1007/s11430-024-1514-4

87. Wang, Q., Kopylova, M.G.*, Chen, Y., Yan, H., Kilgore, M. L., Peslier, A. H., Yang, J. 2025. Fabric transition of olivine as the cause for an anisotropic seismic discontinuity in the mantle of the northern Slave craton, Canada. Tectonophysics, 903, 230704, https://doi.org/10.1016/j.tecto.2025.230704

86. Xu, Z. Q.*, Yin, A., Xiang, H., Wang, Q.*, Li, G. W., Dong, H. W., Cao, H., Gao, J. G., 2025. Top-to-south shear at the base of the eastern Tethyan Himalayan Sequence during the Eocene-Oligocene Himalayan orogeny. Tectonophysics, 895, 230552. https://doi.org/10.1016/j.tecto.2024.230552

2024

85. 左达昇，杨可，魏海珍，王勤，蒋少涌，林和丰，环淳，许志琴. 2024. 伟晶岩结晶动力学和热力学及稀有金属超常富集成矿机制．地质学报, 98(5), 1489-1506. 10.19762/j.cnki.dizhixuebao.2024065

84. Xu, Z. Q.*, Li, H. B., Tian, Y. T., Wang, Q.*, Yu, C. Q., Li, G. W., Ji, S. C., Faure, M., Chevalier, M. L., 2024. Formation, reactivation and exhumation of the extruded basement wedge in the southern Longmen Shan, eastern Tibetan plateau. Journal of the Geological Society, 181, https://doi.org/10.1144/jgs2023-088

83. Deng, T., Hu, X. M., Chew, D., Wang, Q., Yu, J. H., Drakou, F., 2024. Sedimentological Evidence for Pre-Early Permian Continental Subduction in the Dabie Orogen, Central-East China. Tectonics, 43, http://doi: 10.1029/2023TC007839

82. Shatsky, V. S., Wang, Q., Ragozin, A. L., Su, W. H., Ilyin, A. A. 2024. Connection between tectonothermal events of the Yakutian kimberlite province and assembly of the Siberian craton. Precambrian Research, 405, https://doi.org/10.1016/j.precamres.2024.107379

81. 张金晗，王勤*. 2024. 砂岩和页岩弹性波性质的实验研究进展. 地球物理学进展, 39(1), 141-161. https://doi.org/10.1016/j.precamres.2024.107379

80. 李沛东, 王勤*, 武梅千. 2024. 大陆俯冲隧道中的应变不均一分布:来自大别山超高压变质岩的记录. 地质学报, 98(1), 50-78. doi:10.19762/j.cnki.dizhixuebao.2023176

2023

79. 郑群凡, 张怀, 王勤, 张振, 石耀霖. 2023. 新生代华南及邻区上地幔各向异性深部动力学机制的数值模拟. 地球物理学报, 66(5): 2007-2018, doi: 10.6038/cjg2022P0780

78. Demouchy, S., Wang, Q., Tommasi, A., 2023. Deforming the upper mantle – Olivine mechanical properties and anisotropy. Elements, 19, 151-157. https://doi.org/10.2138/gselements.19.3.151

77. Su, W.H., Wang, Q.*, Kang, J., Song, X. Y., 2023. Proterozoic evolution of the Alxa block in western China: A wandering terrane during supercontinent cycles. Precambrian Research, 389, 107002, https://doi.org/10.1016/j.precamres.2023.107002

76. Wang, Q.,* Sun, W. D., Faure, M., Li, H., 2023. From the Yanshan orogeny to Late Mesozoic multi-plate convergence in East Asia. Tectonophysics, 856, 229839, https://doi.org/10.1016/j.tecto.2023.229839

2022

75. Zhang, Z., Zheng, Q. F., Zhang, H., Wang, Q., Shi, Y. L., 2022. Late Mesozoic multi-plate convergence in East Asia: Insights from 3-D global mantle flow models. Tectonophysics 845, 229636, https://doi.org/10.1016/j.tecto.2022.229636

74. Ramírez-Salazar, A., Zuo, J., Muller, T., Webb, A. A.G., Sorger, D., Piazolo, S., Haproff, P., Harvey, J., Wang, Q., Hauzenberger, C., Wong, T. K., 2022. Reply to Comment by A.P. Nutman et al. on “Tectonics of the Isua Supracrustal Belt 1: P-T-X-d Constraints of a Poly-Metamorphic Terrane” by A. Ramírez-Salazar et al. and “Tectonics of the Isua Supracrustal Belt 2: Microstructures Reveal Distributed Strain in the Absence of Major Fault Structures” by J. Zuo et al.. Tectonics, e2021TC007148. https://doi.org/10.1029/2021TC007148

73. Shatsky, V. S.*, Ragozi, A. L., Wang, Q., Wu, M.Q., 2022. Evidence of Eoarchean crustal remnants beneath the Yakutian kimberlite province in the Siberian craton. Precambrian Res., 106512.  https://doi.org/10.1016/j.precamres.2021.106512

72. 施斌, 王宝善, 张诚成, 顾凯, 阮友谊, 李广伟, 王勤, 魏广庆, 张丹, 朱鸿鹄, 程刚，陈颙，2022. 川西甲基卡锂矿3211 m科学深钻多物理量分布式光纤观测. 科学通报，67，2719-2726. https://doi.org/10.1360/TB-2021-1380

71. 卢靖雯，王勤*，刘春，2022. 花岗质岩浆侵位对围岩裂隙发育和热结构影响的数值模拟. 地质学报，96(10): 3619~3638, doi:10.19762/j.cnki.dizhixuebao.2022082

70. 陈瑶，王勤*，2022. 加拿大Slave 克拉通橄榄岩的平衡温压计算. 高校地质学报, 28, 457-472. doi:10.16108/j.issn1006-7493.2020199

69. 闫伟豪, 王勤, 李伟强*. 2022. 俯冲带中大理岩与榴辉岩的Mg-Fe-C-O同位素迁移. 地质学报, 95, doi:10.19762/j.cnki.dizhixuebao.2021169

2021

68. 金田龙，王勤，2021. 活动断裂带岩石的变形机制和摩擦性质——以圣·安德列斯断层为例. 地质学刊, 45, 375-383.

67. Jin, T. L., Wang, Q.*, Shatsky, V., Liao, Y., 2021. Water Content and Deformation of the Lower Crust beneath the Siberian Craton: Evidence from Granulite Xenoliths. Journal of Geology, 129, doi: 10.1086/716514

66. Xu, Z.*, Wang, Q.*, Dong, H., Cao, H., Li, G., Liang, F., Rai, S. M., Kylander-Clark, A., Adhikari, S., Ji, S., 2021. Middle Eocene-Oligocene anatexis and exhumation of the Greater Himalayan Sequence in central Nepal. Terra Nova, 00, 1–12. https://doi.org/10.1111/ter.12551

65. Hao, M., Zhang, J., Zhou, W.-Y., Wang, Q., 2021. Seismic visibility of eclogite in the Earth’s upper mantle—Implications from high pressure-temperature single-crystal elastic properties of omphacite. Journal of Geophysical Research: Solid Earth, 126, e2021JB021683. https://doi.org/10.1029/2021JB021683

64. Skuzovatov, S. Y., Shatsky, V. S., Wang, Q., Ragozin, A.L., Kostrovitsky, S. I., 2021. Multiple tectonomagmatic reactivation of the unexposed basement in the northern Siberian craton: from Paleoproterozoic orogeny to Phanerozoic kimberlite magmatism. International Geology Review, doi: 10.1080/00206814.2021.1916784

63. Zuo, J., Webb, A. A. G., Piazolo, S., Wang, Q., Müller, T., Ramírez-Salazar, A., Haproff, P. J., 2021. Tectonics of the Isua supracrustal belt 2: Microstructures reveal distributed strain in the absence of major fault structures. Tectonics, 40, e2020TC006514. https://doi.org/10.1029/2020TC006514

62. 许志琴, 郑碧海, 王勤．2021．从洋-陆俯冲到陆-陆碰撞: 回眸与展望． 地质学报, 95, 75-97．

2020

61. Gou, Y.R., Wang, Q.*, Li, Y., Wirth, R., 2020. Water Content in Garnet from Eclogites: Implications for Water Cycle in Subduction Channels. Minerals, 10, 410; doi:10.3390/min10050410.

60. Zhang, Y., Cai, Y. F., Qu, Y., Wang, Q., Gu, L., Li, G. J., 2020. Two-stage fluid pathways generated by volume expansion reactions: insights from the replacement of pyrite by chalcopyrite. Scientific Reports, https://doi.org/10.1038/s41598-020-76813-9.

59. 顾筱彤, 王勤*. 2020. 大别山超高压变质岩的显微构造与有效黏度. 高校地质学报, 26, 606-616.

58. 郑重，王勤*. 2020. 白云石有序度与流变特征的研究进展. 高校地质学报, 26, 197–208.

2019

57. Yu, M., Wang, Q*, Yang, J.S., 2019. Fabrics and water contents of peridotites in the Neotethyan Luobusa ophiolite, southern Tibet: implications for mantle recycling in supra-subduction zones. Journal of Geological Society, 176: 975-991. https://doi.org/10.1144/jgs2018-152.

56. Yao, Z., Qin, K., Wang, Q., Xue, S., 2019. Weak B‐type olivine fabric induced by fast compaction of crystal mush in a crustal magma reservoir. Journal of Geophysical Research: Solid Earth, 124. https://doi.org/10.1029/2018JB016728

55. Shatsky, V.S., Wang, Q., Skuzovatov, S.Yu., Ragozin, A.L., 2019. The crust-mantle evolution of the Anabar tectonic province in the Siberian Craton: Coupled or decoupled? Precambrian Research 332, 105388. https://doi.org/10.1016/j.precamres.2019.105388.

54. Ji, S., Wang, Q., Li, L., 2019. Seismic velocities, Poisson's ratios and potential auxetic behavior of volcanic rocks. Tectonophysics, 766, 270-282.

53. 徐翔，王勤*, 2019. 大别山花凉亭-弥陀剪切带与超高压变质岩片的斜向差异折返. 高校地质学报，25，182-196.

2018

52. Machev, P., O’Bannon, E.F., Bozhilov, K.N., Wang, Q., Dobrzhinetskaya, L., 2018. Not all moissanites are created equal: New constraints on moissanite from metamorphic rocks of Bulgaria. Earth and Planetary Science Letters, 498, 387-396.

51. Dobrzhinetskaya, L., Mukhin, P., Wang, Q., Wirth, R., O'Bannon, E., Zhao, W., 2018. Moissanite (SiC) with metal-silicide and silicon inclusions from tuff of Israel: Raman spectroscopy and electron microscope studies. Lithos, 310-311, 355-368.

50. Zhang, W., Wang, Q.*, 2018. Permeability anisotropy and gas slippage of shales from the Sichuan Basin in South China. International Journal of Coal Geology 194, 22-32.

49. Shatsky, V.S., Malkovets, V.G., Belousova, E.A., Tretiakova, I. G., Griffin, W.L., Ragozin, A.L., Wang, Q., Gibsher, A.A., O’Reilly, S.Y., 2018. Multi-stage modification of Paleoarchean crust beneath the Anbar tectonic province (Siberia craton). Precambrian Research 305, 125-144.

48. 许志琴*，王勤*，孙卫东，李忠海，2018. 地球的层圈结构与穿越层圈构造. 地质论评，64, 261-282.

47. 闫浩洁，王勤*. 2018. 电子背散射衍射和傅里叶变换红外光谱结合测量橄榄石的原位含水量. 高校地质学报, 24, 1-12.

2017

46. Ni, H.W., Zheng, Y.F., Mao, Z., Wang, Q., Chen, R.X., Zhang, L., 2017. Distribution, cycling and impact of water in the Earth’s interior. National Science Review, 4, 879–891.

45. Zhang, W., Wang, Q.*, Ye, J., Zhou, J., 2017. Fracture development and fluid pathways in shales during granite intrusion. International Journal of Coal Geology, 183, 25-37.

44. Liao, J., Wang, Q., Gerya, T., Ballmer, M. D., 2017. Modeling craton destruction by hydration-induced weakening of the upper mantle. Journal of Geophysical Research: Solid Earth, 122, doi.org/10.1002/2017JB014157

43. Xu, Z.Q., Yang, J.S., Wang, C.S., An, Z.S., Li, H.B., Wang, Q.*, Su, D.*, 2017. Fifteen years of the Chinese Continental Scientific Drilling Program. Scientific Drilling, 22, 1–18.

42. Webb, A. A.G., Guo, H., Clift, P.D., Husson, L., Müller, T., Costantino, D., Yin, A., Xu, Z.Q., Cao, H., Wang, Q., 2017. The Himalaya in 3D: Slab dynamics controlled mountain building and monsoon intensification. Lithosphere, doi:10.1130/L636.1.

2016

41. Wang, Q.*, 2016. Homologous temperature of olivine: Implications for creep of the upper mantle and fabric transition in olivine. Science China Earth Sciences, doi: 10.1007/s11430-016-5310-z.

40. Wang, Q.*, Bagdassarov, N., Shatsky, V.S., 2016. Origin of high-velocity anomalies beneath the Siberian craton: A fingerprint of multistage magma underplating since the Neoarchean. Russian Geology and Geophysics, 57, 713-722.

39. Shen, L.W., Yu, J.H., O’Reilly, S.Y., Griffin, W.L., Wang, Q., 2016. Widespread Paleoproterozoic basement in the eastern Cathaysia Block: Evidence from metasedimentary rocks of the Pingtan–Dongshan metamorphic belt, in southeastern China. Precambrian Research, 285, 91-108.

38. Li, X., Wang, Q.*, Zhang, W., Yin, H., 2016. Contact metamorphism of shales intruded by a granite dike: implications for shale gas preservation. International Journal of Coal Geology, 159, 96-106.

37. 许志琴，王勤，李忠海，李化启，蔡志慧，梁凤华，董汉文，曹汇，陈希节，黄学猛，吴婵，许翠萍，2016. 印度-亚洲碰撞：从挤压到走滑的构造转换.地质学报，90, 1-23.

2015

36. Xu, Z.*, Wang, Q.*, Cai, Z., Dong, H., Li, H., Chen, X., Duan, X., Cao, H., Li, J., Burg, J.-P., 2015. Kinematics of the Tengchong Terrane in SE Tibet from the late Eocene to early Miocene: Insights from coeval mid-crustal detachments and strike-slip shear zones. Tectonophysics 665, 127-148.

35. 张文，王勤*，杨晓松，段庆宝，叶建国，李霞，周洁，2015. 扬子地块古生界泥页岩孔隙度和渗透率特征. 天然气地球科学, 26, 1534-1539.

34. 李霞，王勤，黄志诚，2015. 页岩孔隙结构研究进展及下扬子古生界页岩孔隙特征. 地质学刊, 39, 13-24.

2014

33. Wang, Q.*, Bagdassarov, N., Xia, Q., Zhu, B., 2014. Water contents and electrical conductivity of peridotite xenoliths from the North China Craton: Implications for water distribution in the upper mantle. Lithos, 189, 105-126.

2013

32. Liao, J., Gerya, T., Wang, Q., 2013. Layered structure of the lithospheric mantle changes dynamics of craton extension. Geophysical Research Letters, 40, 5861–5866, doi:10.1002/2013GL058081.

31. Wang, Q.*, Bagdassarov, N., Ji, S., 2013. The Moho as a transition zone: A revisit from seismic and electrical properties of minerals and rocks. Tectonophysics, 609, 395-422.

30. Wang, Q.*, Xia, Q.K., O’Reilly, S.Y., Griffin, G.L., Beyer, E.E., Brueckner, H. K., 2013. Pressure- and stress-induced fabric transition in olivine from peridotites in the Western Gneiss Region (Norway): implications for mantle seismic anisotropy. Journal of Metamorphic Geology, 31, 91-111.

29. Xu, Z.Q.*, Wang, Q.*, Pêcher, A., Liang, F.H., Qi, X.X., Cai, Z.H., Li, H.Q., Zeng, L.S., Cao, H., 2013. Orogen-parallel extension and extrusion of the Greater Himalaya in the late Oligocene and Miocene. Tectonics, 32, doi:10.1002/tect.20021.

28. Yu, J.-H., Liu, Q., Hu, X.M., Wang, Q., O’Reilly, S.Y., 2013. Late Paleozoic magmatism in South China: Oceanic subduction or intracontinental orogeny? Chinese Science Bulletin 58, 788-795.

27. 门清波，王勤*，Bagdassarov, N，夏群科，樊祺诚，2013. 石榴辉石岩的电导率及对岩浆底侵的约束. 岩石矿物学杂志, 32, 652-662.

26. 许志琴; 王勤; 曾令森; 梁凤华; 李化启; 戚学祥; 蔡志慧; 李忠海; 曹汇，2013. 高喜马拉雅的三维挤出模式，中国地质, 3, 671-680.

2012

25. Mao, X.L., Wang, Q.*, Liu, S.W.*, Xu, M.J., Wang, L.S., 2012. Effective elastic thickness and mechanical anisotropy of South China and surrounding regions. Tectonophysics, 550-553, 47-56.

24. Liu, Q., Yu, J.-H., Wang, Q., Su, B., Zhou, M.-F., Xu, H., Cui, X., 2012. Ages and geochemistry of granites in the Pingtan–Dongshan Metamorphic Belt, Coastal South China: New constraints on Late Mesozoic magmatic evolution. Lithos 150, 268-286.

2011

23. 许海, 王勤*, 马中高, 周枫, 王良书, 2011. 华南地区典型岩石的地震波性质研究. 高校地质学报, 17, 469-478.

22. 刘潜, 于津海, 苏斌, 王勤, 唐红峰, 许海, 崔翔, 2011. 福建锦城187Ma 花岗岩的发现———对华南沿海早侏罗世构造演化的制约. 岩石学报, 27(12):3575 -3589.

2000-2010

21. Wang, Q., 2010. A review of water contents and ductile deformation mechanisms of olivine: implications for the lithosphere–asthenosphere boundary of continents. Lithos 120, 30-41.

20. Wang, Q.*, Burlini, L., Mainprice, D., Xu, Z.Q., 2009. Geochemistry, petrofabrics and seismic properties of eclogites from the Chinese Continental Scientific Drilling boreholes in the Sulu UHP terrane, eastern China. Tectonophysics, 475, 251-266.

19. Xu, Z.Q., Wang, Q.*, Tang, Z.M., Chen, F.Y., 2009. Fabric kinematics of ultrahigh-pressure metamorphic rocks from the main borehole of the Chinese Continental Scientific Drilling Project: implications for continental subduction and exhumation. Tectonophysics, 475, 235-250.

18. Xu, Z.Q., Yang, W.C., Ji, S.C., Zhang, Z.M., Yang, J.S., Wang, Q., Tang, Z.M., 2009. Deep root of a continent–continent collision belt: Evidence from the Chinese Continental Scientific Drilling (CCSD) deep borehole in the Sulu ultrahigh-pressure (HP–UHP) metamorphic terrane, China. Tectonophysics, 475, 204-219.

17. 许志琴，王勤，梁凤华，陈方远，许翠萍，2009. 电子背散射衍射（EBSD）技术在大陆动力学研究中的应用. 岩石学报, 25(7), 1721-1736.

16. 朱蓓蓓，王勤*，王良书，陈立辉，张宏福，2009. 河北阳原新生代玄武岩中橄榄岩捕虏体的含水量研究. 高校地质学报, 15(2), 263-272.

15. Ji, S.C., Wang, Q., Xu, Z.Q., 2007. Reply to the comments of S. Karato on “Petrofabrics and seismic properties of garnet peridotites from the UHP Sulu terrane (China)”. Tectonophysics, 429, 291-296.

14. 王勤*，嵇少丞，许志琴，2007. 橄榄石的晶格优选定向、含水量与地震波各向异性：对大陆俯冲带变形环境的约束. 岩石学报, 23, 3065-3077.

13. 嵇少丞，王茜，王勤，许志琴，2007. 苏鲁－大别超高压变质岩的弹性力学性质与密度的关系. 岩石学报, 23, 3054-3064.

12. 王勤*，2007. 岩石地震波性质的理论与实验研究. 矿物岩石地球化学通报, 26, 118-126.

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