张谦---中国科学院地质与地球物理研究所

第一/共一作者论文（*代表通讯作者）：

1.Zhang, Q.W.L., Chen, Y.*, Su, B., Liu, J.-H., Li, Q.-L. and Li, X.-H., 2025. Long-term radiogenic heating by abortively erupted basalts triggers 120ma lunar volcanism. Geophysical Research Letters, 52(14): e2024GL114438.

2.Zhang, Q.W.L., Su, B., Lanari, P., Liu, J.-H., Hao, J.-L., Liu, Y., Chen, L.-Y., Zhang, D., Yuan, J.-Y., Wang, J., Li, X.-H. and Li, Q.-L.*, 2025. Compositional complexity of heterogeneous impact glasses in lunar soils: significance and pitfalls. Contributions to Mineralogy and Petrology, 180(4): 29.

3.Zhang, Q.W.L., Yang, M.H., Li, Q.L.*, Liu, Y., Yue, Z.Y., Zhou, Q., Chen, L.Y., Ma, H.X., Yang, S.H., Tang, X., Zhang, G.L., Ren, X. and Li, X.H., 2025. Lunar farside volcanism 2.8 billion years ago from Chang'e-6 basalts. Nature, 643(8071): 356–360.

4.Wang, B.-W.†(共同一作), Zhang, Q.W.L.†(共同一作), Chen, Y., Zhao, W., Liu, Y., Tang, G.-Q., Ma, H.-X., Su, B., Hui, H., Delano, J.W., Wu, F.-Y., Li, X.-H., He, Y.* and Li, Q.-L.*, 2024. Returned samples indicate volcanism on the Moon 120 million years ago. Science, 385(6713): 1077–1080.

5.Zhang, Q.W.L., Chen, L.-Y., Sun, J.-X., Tu, J.R., Cui, Z., Yu, H.-M., Xu, J.-J., Zhang, D., Liu, Y., Tang, G.-Q. and Li, Q.-L.*, 2024. A synthetic glass reference material (LMG-4) analogous to Chang’e-5 soil compositions for SIMS U-Pb and Si-O isotopic analyses. Atomic Spectroscopy, 45(5): 358–364.

6.张谦, 杨慕涵, 李秋立* and 李献华, 2024. 嫦娥六号玄武岩揭秘月背岩浆活动. 科学通报, 69(35): 5076–5078 (科普文章).

7.Zhang, Q.W.L., Chen, Y.C.*, Li, Z.M.G., Liu, J.H., Zhang, Q. and Wu, C.M., 2022. Identification of continental fragments in orogen: an example from Dunhuang Orogenic Belt, northwestern China. Science Bulletin, 67(15): 1549–1552.

8.Zhang, Q.W.L., Chen, Y.C.*, Shi, M.Y., Li, Z.M.G., Liu, J.H. and Wu, C.M., 2022. Permian-Triassic magmatic and thermal events in the Dunhuang orogenic belt: implications for subduction records of the Paleo-Asian Ocean. International Geology Review, 64(16): 2306–2329.

9.Zhang, Q.W.L., Li, Z.M.G., Shi, M.Y., Chen, Y.C., Liu, J.H. and Wu, C.M.*, 2021. ⁴⁰Ar/³⁹Ar dating of hornblende and U-Pb dating of zircon in the Aketashitage orogen, NW China: Constraints on exhumation and cooling in the Paleoproterozoic. Precambrian Research, 352: 106018.

10.Zhang, Q.W.L., Liu, J.H., Li, Z.M.G., Shi, M.Y., Chen, Y.C. and Wu, C.M.*, 2021. Juxtaposition of diverse, subduction-related tectonic blocks with contrasting metamorphic features and ages in the Paleoproterozoic Aketashitage orogen, NW China: Implications for Precambrian orogeny. Geological Society of America Bulletin, 133(7–8): 1483–1504.

11.Zhang, Q.W.L., Wang, H.Y.C., Liu, J.H., Shi, M.Y., Chen, Y.C., Li, Z.M.G. and Wu, C.M.*, 2020. Diverse subduction and exhumation of tectono-metamorphic slices in the Kalatashitage area, western Paleozoic Dunhuang Orogenic Belt, northwestern China. Lithos, 360–361.

12.Zhang, Q.W.L., Liu, J.H., Wang, H.Y.C., Shi, M.Y., Chen, Y.C., Li, Z.M.G., Zhang, H.C.G., Pham, V.T. and Wu, C.M.*, 2019. Amphibolite facies metamorphism and geochronology of the Paleoproterozoic Aketashitage Orogenic Belt, northwestern China. Precambrian Research, 328: 146–160.

共同作者论文：

1.Yang, M.-H., Zhang, Q.W.L., Carlson, R.W., Wang, B.-W., Ouyang, D. and Li, Q.-L., 2026. The moon's formation time recorded in lunar mare basalts. Icarus, 447: 116889.

2.Li, H., Zhang, Q.W.L., Li, Q.-L., Yue, Z., Chen, Y., Yang, M.-H., Su, B., Han, B., Lin, Y.-T., Li, X.-H. and Wu, F.-Y., 2025. Giant impacts trigger crustal recycling as witnessed by sulfur isotopes in lunar basalts. Communications Earth & Environment.

3.Liu, J.-H., Kaempf, J., Huang, M., Riel, N., Guo, J., Huang, G., Chen, L., Jiao, S., Mao, M., Clark, C., Wang, J., Zhang, Q.W.L. and Peng, P., 2025. Thermal Structure of a Paleoproterozoic Orogen: A Case Study from the Wutai–Fuping Crustal Section. Journal of Petrology, 66(5): egaf043.

4.Liu, J.-H., Lanari, P., Tamblyn, R., Dominguez, H., Hermann, J., Rubatto, D., Forshaw, J.B., Piccoli, F., Zhang, Q.W.L., Markmann, T.A., Reynes, J., Li, Z.M.G., Jiao, S. and Guo, J., 2025. Ultra-fast metamorphic reaction during regional metamorphism. Geochimica et Cosmochimica Acta, 394: 106–125.

5.Su, B., Chen, Y., Chen, H., Wang, Z., Gou, S., Zhang, Q.W.L., Zhang, D., Yue, Z., Li, X.-H. and Wu, F.-Y., 2025. Crust–mantle architecture of the Moon’s South Pole–Aitken basin from Chang’e-6 samples. Communications Earth & Environment.

6.Wang, B.-W., Zhang, Q.W.L., Delano, J.W., Zhang, D., Ouyang, D., Yang, M.-H., Wu, S.-T. and Li, Q.-L., 2025. Size matters: Chemical representativeness of lunar impact-generated glass beads. Atomic Spectroscopy(2): 119–130.

7.Yang, M.-H., Zhang, Q.W.L., Li, Q.-L., Mitchell, R.N., Carlson, R.W., Chu, Z.-Y., Liu, Y., Chen, Y., Guo, S., Xue, D.-S., Su, B., Tang, X., Yuan, J.-Y. and Li, X.-H., 2025. 2.2-billion-year-old KREEP-rich volcanism on the Moon. Science Bulletin, 70(19): 3265–3271.

8.Sun, J.-X., Chen, L.-Y., Zhang, Q.W.L., Liu, Y., Tang, G.-Q., Tu, J.-R. and Li, Q.-L., 2024. Matrix effect calibration of U–Pb analysis on glasses by sims. Atomic Spectroscopy, 46(2): 119–130.

9.Wang, G.-D., Li, Z.M.G., Zhang, Q.W.L., Wang, J. and Shao, F.-L., 2024. Neoproterozoic Buchan-type metamorphism of the northwestern margin of the Yangtze Craton and tectonothermal implications. Precambrian Research, 401.

10.Chen, Y., Liu, J., Zhou, R., Xiao, W., Zhang, J.e., Zhang, Z., Zhang, Q.W.L., Li, Z.M.G. and Wu, C., 2022. Extensional magmatism caused by strain partitioning: insights from the mafic dikes hosted in Biesituobie batholith in West Junggar, CAOB. International Journal of Earth Sciences, 112(1): 33–49.

11.Chen, Y., Liu, J., Zhou, R., Xiao, W., Zhang, J.e., Zhang, Z., Zhang, Q.W.L., Li, Z.M.G. and Wu, C., 2022. Constraint on the temperature of A-type magma from contact metamorphic aureole, Biesituobie batholith, West Junggar in NW China, Central Asian Orogenic Belt. GSA Bulletin, 135(5-6): 1265–1279.

12.Li, Z.M.G., Chen, Y.C., Zhang, Q.W.L., Liu, J.H. and Wu, C.M., 2022. conditions and timing of metamorphism of the Yuanmou area, southern Neoproterozoic Kang-Dian Orogenic Belt, southwest China. Precambrian Research, 374: 106642.

13.Wang, H., Xiao, W., Windley, B.F., Zhang, Q.W.L., Tan, Z., Wu, C. and Shi, M., 2022. Diverse P‐T‐t paths reveal high‐grade metamorphosed forearc complexes in NW China. Journal of Geophysical Research: Solid Earth, 127(6): e2022JB024309.

14.Chen, Y.C., Zhang, J.E., Xiao, W.J., Zhou, R.J., Song, S.H., Zhang, Z.Y., Ao, S.J., Sang, M., Zhang, Q.W.L., Li, R., Li, Z.M.G., Liu, Y., Zhang, H.C.G., Liu, J.H. and Wu, C.M., 2021. Late Silurian to early Devonian development of the Chingiz accretion arc, West Junggar: Insights into accretion arc evolution in the Central Asia Orogenic Belt. International Geology Review, 63(17): 2083–2103.

15.Li, Z., Wang, H., Zhang, Q., Shi, M.Y., Lu, J.S., Liu, J.H. and Wu, C.M., 2021. Ultra-high pressure metamorphism and geochronology of garnet clinopyroxenite in the Paleozoic Dunhuang Orogenic Belt, northwestern China. Minerals, 11(2): 117.

16.Li, Z.M.G., Chen, Y.C., Zhang, Q.W.L., Liu, J.H. and Wu, C.M., 2021. U-Pb dating of metamorphic monazite of the Neoproterozoic Kang-Dian Orogenic Belt, southwestern China. Precambrian Research, 361: 106262.

17.Liu, J.H., Chen, Y.C., Li, Z.M.G., Zhang, Q.W.L., Lan, T.G., Zhang, Q. and Wu, C.M., 2021. Temperature and timing of ductile deformation of the Longquanguan shear zone, Trans-North China Orogen. Precambrian Research, 359.

18.Liu, J.H., Li, Z.M.G., Zhang, Q.W.L., Zhang, H.C.G., Chen, Y.C. and Wu, C.M., 2021. New ⁴⁰Ar/³⁹Ar geochronology data of the Fuping and Wutai Complexes: Further constraints on the thermal evolution of the Trans-North China Orogen. Precambrian Research, 354.

19.Liu, J.H., Wang, J., Li, Z.M.G., Zhang, Q.W.L. and Wu, C.M., 2021. Paleoproterozoic medium to high pressure metamorphism in the Wanzi supracrustal association, Trans-North China Orogen: New insights from the gedrite-bearing gneiss, gedrite-free gneiss, and amphibolite. Precambrian Research, 360.

20.Shi, M.Y., Hou, Q.L., Wu, C.M., Yan, Q.R., Cheng, N.N., Zhang, Q.W.L. and Wang, H.Y.C., 2021. Origins of the meta-mafic rocks in the southern Dunhuang Block (NW China): Implication for tectonic framework of the southernmost Central Asian Orogenic Belt. Geological Journal, 56(8): 3959–3973.

21.梁爽, 张谦, 刘嘉惠, 李真, 闫全人 and 吴春明, 2021. 西峡-内乡地区秦岭岩群变质独居石和锆石的U-Pb定年. 岩石学报, 37(12): 3797–3814.

22.石梦岩, 程南南, 侯泉林, 吴春明, 闫全人, 张国成, 张谦 and 王浩, 2021. 敦煌北部岩浆-变质杂岩构造环境初步探讨：对中亚造山带南缘扩展方式的启示. 岩石学报, 37(12): 3673–3686.

23.Chen, H.X., Liu, J.H., Zhang, Q.W.L., Wang, H.Y.C. and Wu, C.M., 2020. A long-lived tectono-metamorphic event in the late Paleoproterozoic: Evidence from SIMS U-Th-Pb dating of monazite from metapelite in central-south Trans-North China Orogen. Precambrian Research, 336: 105497.

24.Liu, J.H., Zhang, Q.W.L., Wang, J., Zhang, H.C.G. and Wu, C.M., 2020. Metamorphic evolution and SIMS U–Pb geochronology of orthopyroxene‐bearing high‐P semipelitic granulite in the Fuping area, middle Trans‐North China Orogen. Journal of Metamorphic Geology, 39(3): 297–320.

25.Liu, J.H., Zhang, Q.W.L., Li, Z.M.G., Zhang, H.C.G., Chen, Y.C. and Wu, C.M., 2020. Metamorphic evolution and U-Pb geochronology of metapelite, northeastern Wutai Complex: Implications for Paleoproterozoic tectonic evolution of the Trans-North China Orogen. Precambrian Research, 350.

26.Shi, M.Y., Hou, Q.L., Wu, C.M., Yan, Q.R., Wang, H.Y.C., Cheng, N.N., Zhang, Q.W.L. and Li, Z.M.G., 2020. Paleozoic Sanweishan arc in the northern Dunhuang region, NW China: The Dunhuang block is a Phanerozoic orogen, not a Precambrian block. Journal of Asian Earth Sciences, 194: 103954.

27.Zhang, H.C.G., Peng, T., Liu, J.H., Wang, J., Chen, Y.C., Zhang, Q.W.L. and Wu, C.M., 2020. New geochronological evidences of late Neoarchean and late Paleoproterozoic tectono-metamorphic events in the Miyun area, North China Craton. Precambrian Research, 345: 105774.

28.Liu, J.H., Zhang, Q.W.L., Zhang, H.C.G., Wang, H.Y.C., Chen, H.X., Pham, V.T., Peng, T. and Wu, C.M., 2019. Metamorphic evolution and SHRIMP U-Pb geochronology of mafic granulites with double symplectites in the Fuping metamorphic complex, middle Palaeoproterozoic Trans-North China Orogen. Precambrian Research, 326: 142–154.

29.Zhang, H.C.G., Liu, J.H., Chen, Y.C., Zhang, Q.W.L., Tho Pham, V., Peng, T., Li, Z.M.G. and Wu, C.M., 2019. Neoarchean metamorphic evolution and geochronology of the Miyun metamorphic complex, North China Craton. Precambrian Research, 320: 78–92.

30.Wang, H.Y.C., Zhang, Q.W.L., Chen, H.X., Liu, J.H., Zhang, H.C.G., Van Tho, P., Peng, T. and Wu, C.M., 2018. Paleozoic subduction of the southern Dunhuang Orogenic Belt, northwest China: metamorphism and geochronology of the Shuixiakou area. Geodinamica Acta, 30(1): 63–83.

31.Wang, H.Y.C., Zhang, Q.W.L., Lu, J.S., Chen, H.X., Liu, J.H., Zhang, H.C.G., Pham, V.T., Peng, T. and Wu, C.M., 2018. Metamorphic evolution and geochronology of the tectonic mélange of the Dongbatu and Mogutai blocks, middle Dunhuang orogenic belt, northwestern China. Geosphere, 14(2): 883–906.

32.范文寿, 王浩, 张谦, 刘嘉惠, 石梦岩, 李真 and 吴春明, 2018. 敦煌造山带长山子地区变质演化及年代学研究. 岩石学报, 34(09): 2773–2792.

33.石梦岩, 侯泉林, 吴春明, 王浩, 程南南, 张谦 and Tho, P.V., 2018. 敦煌造山带南部红柳峡混杂带基质的沉积学、地球化学和年代学特征及其大地构造意义. 岩石学报, 34(07): 2099–2118.

34.Meng, J., Peng, T., Liu, J.H., Zhang, H.C.G., Wang, G.D., Lu, J.S., Chen, H.X., Wang, H.Y.C., Zhang, Q.W.L. and Wu, C.M., 2017. Metamorphic evolution and SIMS zircon U-Pb geochronology of mafic granulite and amphibolite enclaves of the Pingyang trondhjemitic pluton, Fuping terrane, North China. Precambrian Research, 303: 75–90.

35.Wang, H.Y.C., Chen, H.X., Zhang, Q.W.L., Shi, M.Y., Yan, Q.R., Hou, Q.L., Zhang, Q., Kusky, T. and Wu, C.M., 2017. Tectonic mélange records the Silurian–Devonian subduction-metamorphic process of the southern Dunhuang terrane, southernmost Central Asian Orogenic Belt. Geology, 45(5): 427–430.

36.Wang, H.Y.C., Wang, J., Wang, G.-D., Lu, J.-S., Chen, H.-X., Peng, T., Zhang, H.C.G., Zhang, Q.W.L., Xiao, W.-J., Hou, Q.-L., Yan, Q.-R., Zhang, Q. and Wu, C.-M., 2017. Metamorphic evolution and geochronology of the Dunhuang orogenic belt in the Hongliuxia area, northwestern China. Journal of Asian Earth Sciences, 135: 51–69.