第一作者及通讯作者：

1.  Yang, Y.*, Galy, A., Fang, X., France-Lanord, C., Wan, S., Yang, R., Zhang, J., Zhang, R., Yang, S., Miao, Y., Liu, Y., Ye, C., 2021. East Asian monsoon intensification promoted weathering of the magnesium-rich southern China upper crust and its global significance. Science China Earth Sciences, 64(7), 1155-1170.

[杨一博, Galy A, 方小敏, France-Lanord C, 万世明, 杨戎生, 张健, 张冉, 杨松, 苗运法, 刘玉东, 叶程程. 2021. 东亚季风增强加剧中国南部富Mg上地壳化学风化及其全球意义. 中国科学: 地球科学, 51(8): 1289–1305]

2.  Yang, Y.*, Galy, A., Fang, X.*, Yang, R., Zhang, W., Song, B., Liu, Y., Han, W., Zhang, W., Yang, S., 2021. Neodymium isotopic constraints on Cenozoic Asian dust provenance changes linked to the exhumation history of the northern Tibetan Plateau and the Central Asian Orogenic Belt. Geochimica et Cosmochimica Acta, 296, 38–55. [Chosen to be featured in Research Highlights of Nature Reviews Earth & Environment, “Dust records mountain growth”, https://doi.org/10.1038/s43017-021-00141-3]

3.  Yang, Y.*, Ye, C., Galy, A., Fang, X.*, Xue, Y., Liu, Y., Yang, R., Zhang, R., Han, W., Zhang, W., Ruan, X., 2021. Monsoon Enhanced Silicate Weathering as a New Atmospheric CO₂ Consumption Mechanism Contributing to Fast Late Miocene Global Cooling. Paleoceanography and Paleoclimatology, 36, e2020PA004008.

4.  Yang, Y.*, Ye, C., Yang, R., Fang, X.*, 2021. Revisiting clay-sized mineral and elemental records of the silicate weathering history in the northern Tibetan Plateau during the late Cenozoic: The role of aeolian dust. Terra Nova, 33, 252–261. [Cover image of Terra Nova volume 33, number 3]

5.   Ye, C., Yang, Y.*, Fang, X.*, Zhang, W., Song, C., Yang, R., 2020. Paleolake salinity evolution in the Qaidam Basin (NE Tibetan Plateau) between~ 42 and 29 Ma: Links to global cooling and Paratethys sea incursions. Sedimentary Geology, 409, 105778.

6. Liu, X., Dong, S.*, Yue, Y.*, Guan, Q., Sun, Y., Chen, S., Zhang, J., Yang, Y.*, 2020. ⁸⁷Sr/⁸⁶Sr isotope ratios in rocks determined using inductively coupled plasma tandem mass spectrometry in O₂ mode without prior Sr purification. Rapid Communications in Mass Spectrometry, 34(8), e8690.

7.  Ye, C., Yang, Y.*, Fang, X.*, Zan, J., Tan, M., Yang, R., 2020. Chlorite weathering linked to magnetic enhancement in Red Clay on the Chinese Loess Plateau. Palaeogeography Palaeoclimatology Palaeoecology, 538, 109446.

8. Song, B., Yang, Y.*, Yang, R.*, Galy, A., Zhang, K., Ji, J., Liu, Y., Ai, C., Wang, C., Hou, Y., 2020. Miocene ⁸⁷Sr/⁸⁶Sr ratios of ostracods in the northern Qaidam Basin, NE Tibetan Plateau, and links with regional provenance, weathering and eolian input. Palaeogeography Palaeoclimatology Palaeoecology, 552, 109775.

9. Ruan, X., Yang, Y.*, Galy, A., Fang, X.*, Jin, Z., Zhang, F., Yang, R., Deng, L., Meng, Q., Ye, C., Zhang, W., 2019. Evidence for early (≥12.7 Ma) eolian dust impact on river chemistry in the northeastern Tibetan Plateau. Earth and Planetary Science Letters, 515, 79–89.

10. Ye, C., Yang. Y.*, Fang, X.*, Hong, H., Wang, C., Yang, R., Zhang, W., 2018. Chlorite chemical composition change in response to the Eocene-Oligocene climate transition on the northeastern Tibetan Plateau. Palaeogeography Palaeoclimatology Palaeoecology, 512, 23–32.

11. 杨一博, 方小敏, Albert Galy, 杨戎生，2018. 柴达木盆地西部第四纪气候变化和流域风化. 第四纪研究, 38(1): 76–85.

12. 阮笑白, 杨一博*, 方小敏, 杨戎生, 叶程程, 2018. 醋酸提取沉积物非碳酸盐来源Mg的实验探究—以西宁盆地中中新世-上新世沉积地层为例. 第四纪研究, 38(1): 118–129.

13. Yang, Y.*, Yang, R., Li, X., Han, W., Fang, X., Appel, E., Galy, A., Wu, F., Song Yang, Zan, J., Zhang, Z., Zhang, W., Ye, C., 2017. Glacial–interglacial climate change on the northeastern Tibetan Plateau over the last 600 kyr. Palaeogeography Palaeoclimatology Palaeoecology, 476, 181–191.

14. Yang, Y.*, Galy, A., Fang, X.*, Yang, R., Zhang, W., Zan, J., 2017. Eolian dust forcing of river chemistry on the northeastern Tibetan Plateau since 8 Ma. Earth and Planetary Science Letters, 464, 200–210.

15. Ye, C., Yang, Y.*, Fang, X., Zhang, W., 2016. Late Eocene clay boron–derived paleosalinity in the Qaidam Basin and its implications for regional tectonics and climate. Sedimentary Geology, 346, 49–59.

16. Yang, Y.*, Fang, X., Galy, A., Jin, Z., Wu, F., Yang, R., Zhang, W., Zan, J., Liu, X., Gao, S., 2016. Plateau uplift forcing climate change around 8.6 Ma on the northeastern Tibetan Plateau: evidence from an integrated sedimentary Sr record. Palaeogeography Palaeoclimatology Palaeoecology, 461, 418–431.

17. Yang Y.*, Fang, X., Koutsodendris, A., Ye, C., Yang, R., Zhang, W., Liu, X., Gao, S., 2016. Exploring Quaternary paleolake evolution and climate change in the western Qaidam Basin based on the bulk carbonate geochemistry of lake sediments. Palaeogeography Palaeoclimatology Palaeoecology, 446, 152–161.

18. Yang, Y.*, Fang, X., Galy, A., Zhang, G, Liu, S., Zan, J., Wu, F., Meng, Q., Ye, C., Yang, R., Liu, X., 2015. Carbonate composition and its impact on fluvial geochemistry in the NE Tibetan Plateau region. Chemical Geology, 410, 138–148.

19. Yang, Y.*, Fang, X., Li, M., Galy, A., Koutsodendris, A., Zhang, W., 2015. Paleoenvironmental implications of uranium concentrations in lacustrine calcareous clastic–evaporite deposits in the western Qaidam Basin. Palaeogeography Palaeoclimatology Palaeoecology, 417, 422–431.

20. Yang, Y.*, Fang, X., Galy, A., Li, M., Appel, E., Liu, X., 2014. Paleoclimatic significance of rare earth element record of the calcareous lacustrine sediments from a long core (SG–1) in the western Qaidam Basin, NE Tibetan Plateau. Journal of Geochemical Exploration, 145, 223–232.

21. Yang, Y., Fang, X.*, Galy, A., Appel, E., Li, M., 2013. Quaternary paleolake nutrient evolution and climatic change in the western Qaidam Basin deduced from phosphorus geochemistry record of deep drilling core SG–1. Quaternary International, 313–314, 156–167.

22.  Yang, Y., Fang, X.*, Appel, E., Galy, A., Li, M., Zhang, W., 2013. Late Pliocene–Quaternary evolution of redox conditions in the western Qaidam paleolake (NE Tibetan Plateau) deduced from Mn geochemistry in the drilling core SG–1. Quaternary Research, 80, 586–595.

其他合作论文：

23.  Zhao, Y., Yang, Y. B. Guo, Y., Ren, G. Y., Zhang, F. C., 2021. Stable carbon isotope composition of bone hydroxylapatite: significance in paleodietary analysis, Palaeoworld, https://doi.org/10.1016/j.palwor.2021.02.004

24.  Lü, S., Ye, C., Fang, X., Appel, E., Han, F., Yan, M., Zhang, W., Zhang, T., Yang Y., Han, W., 2020. Middle to late Eocene chemical weathering history in the southeastern Tibetan Plateau and its response to global cooling. Palaeogeography Palaeoclimatology Palaeoecology, 562, 110136.

25.  Song, B.*, Spicer, R. A., Zhang, K.*, Ji, J., Farnsworth, A., Hughes, A. C., Yang Y., Han, F., Xu, Y., Spicer, T., Shen, T., Lunt, D.J., Shi, G.*, 2020. Qaidam Basin leaf fossils show northeastern Tibet was high, wet and cool in the early Oligocene. Earth and Planetary Science Letters, 537, 116175.

26. Fang, X., Galy, A., Yang, Y., Zhang, W., Ye, C., Song, C., 2019. Paleogene global cooling–induced temperature feedback on chemical weathering, as recorded in the northern Tibetan Plateau. Geology, 47(10), 992–996.

27. Song, B.*, Zhang, K.*, Hou, Y., Ji, J., Wang, J., Yang, Y., Yang, T., Wang, C., Shen, T., 2019. New insights into the provenance of Cenozoic strata in the Qaidam Basin, northern Tibet: Constraints from combined U-Pb dating of detrital zircons in recent and ancient fluvial sediments. Palaeogeography Palaeoclimatology Palaeoecology, 533, 109254.

28. Zhang, J*., Wang, Y., Fang, X., Wang, C., Yang, Y., 2019. Large dry-humid fluctuations in Asia during the Late Cretaceous due to orbital forcing: A modeling study. Palaeogeography Palaeoclimatology Palaeoecology, 533, 109230.

29. Yang, R., Yang, Y., Fang, X.*, Ruan, X., Galy, A., Ye, C., Meng Q., Han, W., 2019. Late Miocene intensified tectonic uplift and climatic aridification on the northeastern Tibetan Plateau: Evidence from clay mineralogical and geochemical records in the Xining Basin. Geochemistry Geophysics Geosystems, 20, 829–851.

30. Han W.*, Lü, S., Appel, E., Berger, A., Madsen, D., Vandenberghe, J., Yu, L., Han, Y., Yang, Y., Zhang, T., Teng, X., Fang, X., 2019. Dust storm outbreak in central Asia after ~3.5 kyr BP. Geophysical Research Letters, 46, 7624–7633.

31. Mao, Z., Meng, Q*., Fang, X.*, Zhang, T., Wu, F., Yang, Y., Zhang, W., Zan, J., Tan, M., 2019. Recognition of tuffs in the middle-upper Dingqinghu Fm., Lunpola Basin, central Tibetan Plateau: Constraints on stratigraphic age and implications for paleoclimate. Palaeogeography Palaeoclimatology Palaeoecology, 525, 44–56.

32. Zhang W.*, Appel, E., Wang, J., Fang, X., Zan, J., Yang, Y., Miao, Y., Yan, X., 2019. New paleomagnetic constraints for Platybelodon and Hipparion faunas in the Linxia Basin and their ecological environmental implications. Global and Planetary Change, 176, 71–83.

33. Miao, Y.*, Wu, F.*, Warny, S., Fang, X., Lu, H., Fu, B., Song, C., Yan, X., Escarguel, G., Yang. Y., Meng, Q., Shi, P., 2019. Miocene fire intensification linked to continuous aridification on the Tibetan Plateau. Geology, 47, 303–307.

34. Bao, J., Song, C*., Yang, Y., Fang, X., Meng, Q., Feng, Y., He, P., 2019. Reduced chemical weathering intensity in the Qaidam Basin (NE Tibetan Plateau) during the Late Cenozoic. Journal of Asian Earth Sciences, 170, 155–165.

35. Teng, X., Fang, X.*, Kaufman, A., Liu, C., Wang, J., Zan, J., Yang, Y., Wang, C., Xu, H., Schulte, R., Piatak, N., 2019. Sedimentological and mineralogical records from drill core SKD1 in the Jianghan Basin, Central China, and their implications for late Cretaceous-early Eocene climate change. Journal of Asian Earth Sciences, 182, 103936.

36. Li, X., Jiang, D.*, Tian, Z., Yang, Y., 2018. Mid-Pliocene global land monsoon from PlioMIP1 simulations. Palaeogeography Palaeoclimatology Palaeoecology, 512, 56–70.

37. Ye, C., Yang, Y., Fang, X.*, Hong, H., Zhang, W., Yang, R., Song, B., Zhang, Z., 2018. Mineralogical and geochemical discrimination of the occurrence and genesis of palygorskite in Eocene sediments on the northeastern Tibetan Plateau. Geochemistry Geophysics Geosystems, 19, 567–581.

38. Yang, X., Cai, M.*, Ye, P.*, Yang, Y., Wu, Z., Zhou, Q., Li C., Liu, X., 2018. Late Pleistocene paleolake evolution in the Hetao Basin, Inner Mongolia, China. Quaternary International, 464, 386–396.

39. Yang, R., Fang, X.*, Meng, Q., Zan, J., Zhang, W., Deng, T., Yang, Y., Ruan, X., Yang, L., Li, B., 2017. Paleomagnetic Constraints on the Middle Miocene–Early Pliocene Stratigraphy in the Xining Basin, NE Tibetan Plateau, and the Geologic Implications. Geochemistry Geophysics Geosystems, 18(11), 3741–3757.

40. Zhang, D., Yan, X.*, Fang, X., Yang, Y., Zhang, T., Zan, J., Zhang, W., Liu, C., Yang, Q., 2018. Magnetostratigraphic study of the potash–bearing strata from drilling core ZK2893 in the Sakhon Nakhon Basin, eastern Khorat Plateau. Palaeogeography Palaeoclimatology Palaeoecology, 489, 40–51.

41. Zhao, Y., Wu. F.*, Fang, X., Yang, Y., 2017. Altitudinal variations in the bulk organic carbon isotopic composition of topsoil in the Qilian Mountains area, NE Tibetan Plateau, and its environmental significance. Quaternary International, 454, 45–55.

42. Fang X.*, Wang, J., Zhang, W., Zan, J., Song, C., Yan, M., Appel, E., Zhang, T., Wu, F., Yang, Y., Lu, Y., 2016. Tectonosedimentary evolution model of an intracontinental flexural (foreland) basin for paleoclimatic research. Global and Planetary Change, 145, 78–97.

43. Li, J.*, Li, M.*, Fang, X., Wang, Z., Zhang, W., Yang, Y., 2016. Variation of gypsum morphology along deep core SG–1, western Qaidam Basin (northeastern Tibetan Plateau) and its implication to depositional environments. Quaternary International, 430, 71–81.

44. Zhao, Y., Wu, F.*, Fang, X., Yang, Y., 2015. Topsoil C/N ratios in the Qilian Mountains area: implications for the use of subaqueous sediment C/N ratios in paleo–environmental reconstructions to indicate organic sources. Palaeogeography Palaeoclimatology Palaeoecology, 426, 1–9.

45. Cai, M.*, Wei, M.*, Yang, Y., Wang, J., Xu, D., 2014. Long–term cooling/drying record of North China since the middle Pleistocene from geochemical evidence of a 150 m deep drill core, Beijing plain, China. Quaternary International, 349, 419–427.

46. Zhang, J.*, Feng, J–L., Hu, G., Wang, J., Yang, Y., Lin, Y., Jiang, T., Zhu, L., 2014. Holocene proglacial loess in the Ranwu valley, southeastern Tibet, and its paleoclimatic implications. Quaternary International, 372, 9–22.

47. Li, M., Fang, X.*, Wang, J., Song, Y., Yang, Y., Liu, X., 2013. Evaporite minerals of the lower 538.5 m sediments in a long core from the Western Qaidam Basin, Tibet. Quaternary International, 298, 123–133.

48. 潘佳秋，宋春晖，鲍晶，马丽芳，颜茂都，方小敏，应红，杨一博，2015. 羌塘盆地侏罗系元素地球化学特征与成盐层位分析. 地质学报，89(11): 2152–2160.

49. 吴福莉，赵艳，方小敏，孟庆泉，杨一博，2015. 兰州盆地44~15Ma地层的有机碳同位素记录. 第四纪研究，35(4): 847–855.

50. 贾丽敏，陈秀玲，杨一博，李金婵，2014. 伊犁盆地昭苏黄土不同粒径和相态稀土元素特征及其物源指示意义. 地球环境学报, 5(2): 93–101.

51. 刘艳蕊, 杨一博, 方小敏, 宋春晖, 刘晓明, 2014. 沉积相变迁对内陆湖泊沉积易溶盐作为古环境指标的影响：以西宁盆地为例. 沉积学报, 32(1): 101–109.

52. 闫晓丽, 杨一博, 方小敏, 苗运法, 宋春晖, 2012. 临夏盆地晚中新世沉积物中赤铁矿和针铁矿的含量特征及其意义. 兰州大学学报 (自然科学版), 48(1): 55–61.

53. 李香钰, 方小敏, 杨一博, 昝金波, 2012. 3Ma以来黄土高原朝那黄土–红粘土序列赤铁矿记录及其古气候意义. 第四纪研究, 32(4): 700–708.

54. 昝金波, 杨胜利, 方小敏, 李香钰, 杨一博, 迟云平, 2010. 极端干旱区黄土土壤容重的测量及其古气候意义. 海洋地质与第四纪地质, 30(2): 127–132.