姓名：刘佳

职称：研究员 硕士生导师

电子邮箱：liujia@cdut.edu.cn

研究室：古海洋古气候古生物研究室

个人简介：

刘佳，男，汉族，1987年12月生于陕西渭南。主要从事青藏高原及周边地区新生代古生物学研究，通过孢粉与植物大化石相结合探讨新生代青藏高原形成和演化及其气候效应对植物多样性的影响。近5年合作发表论文36篇，其中第一作者或通讯作者论文7篇。通过孢粉学和古植物学研究取得以下认识：古近纪青藏高原主要缝合带附近的低海拔盆地是热带、亚热带类群通过青藏高原进行交流的主要通道，新近纪高原现代地貌格局形成，成为喜热类群交流的障碍；新近纪高原北部隆升，季风气候增强，西风水汽通道关闭，导致亚洲内陆干旱化程度增强；系统总结青藏高原及其周边古近纪综合地层、生物群和生物地理学研究，发现始新世-渐新世气候转型期是中国西南地区植物现代化面貌的形成和演化的关键时期。

学历和工作背景：

2023.09–至今成都理工大学，沉积地质研究院，研究员(珠峰B类)

2019.06–2023.09中国科学院西双版纳热带植物园，助理研究员

2017.05–2019.05中国科学院西双版纳热带植物园，博士后，合作导师：周浙昆研究员

2009.09–2016.12兰州大学，资源环境学院，第四纪地质学，理学博士，导师：李吉均院士

2005.09–2009.06兰州大学，资源环境学院，地理学基地班，理学学士

主要研究领域：

通过孢粉与植物大化石相结合探讨青藏高原新生代形成和演化及其气候效应对植物多样性的影响。

获得的荣誉：

1.2019年度中国古生物学十大进展

2.2020年度中国古生物学十大进展

3.2023年云南省自然科学一等奖

主持/参与科研项目：

1.国家自然科学基金青年基金项目，西藏芒康始新世-渐新世气候转型期孢粉植物群及其古环境意义，2021–2023，30万，在研，主持；

2.中国科学院西部之光青年学者项目，孢粉壁紫外线吸收化合物重建青藏高原古高程，2019–2022，15万，已结题，主持；

3.中国科学院南京地质古生物研究所现代古生物学和地层学国家重点实验室开放课题，利用栎属植物花粉壁UV-B吸收化合物(UACs)重建青藏高原古高程，2019–2022，8万，已结题，主持；

4.云南省科技厅基础研究专项-青年项目，越南北部横蒲盆地新生代孢粉生物地层及古环境，2020–2023，5万，已结题，主持；

5.科技部重点研发计划，“白垩纪-古近纪深部碳循环与热室地球演变”-热室地球植被、植物多样性与生态响应，2022–2027，550万，在研，骨干；

6.科技部“第二次青藏高原综合科学考察研究“专项，“生物与高原隆升协同演化”（子专题4），2019–2023，500万，在研，骨干；

7.国家自然科学基金面上项目，云南建水盆地晚古近纪古气候、古植被及植物多样性演变，2024–2027，53万，在研，参与；

8.国家自然科学基金面上项目，多倍体成功进化的表型和遗传基础，2022–2025，58万，在研，参与；

9.国家自然科学基金面上项目，云南晚始新世-早渐新世之交的植物多样性及其古环境，2021–2024，61万，在研，参与。

代表性文章：

1.刘佳*,宋艾,丁林,苏涛,周浙昆*. 2024.青藏高原及其周边古近纪综合地层、古生物群与古地理演化.中国科学:地球科学, 54: 1–35.

2.Liu, J.*, Song, A., Ding, L., Su, T., Zhou, Z.* 2024. Paleogene integrative stratigraphy, biotas and paleogeographical evolution of the Qinghai-Tibetan Plateau and its surrounding regions. Science China Earth Sciences, 67: 1–36.

3.李树峰,赵佳港, Alex, F., Paul, V.,刘佳,黄健,周浙昆,苏涛. 2023.新生代青藏高原生长对东亚水循环及生态系统影响评述.科学通报, 68: 1567–1579.

4.周浙昆,刘佳,陈琳琳, Spicer, R.A.,李树峰,黄健,张世涛,黄永江,贾林波,胡瑾瑾,苏涛. 2023.西藏新生代植物近十年来的重要发现、认识及其意义.中国科学：地球科学, 53: 193–215.

5.Gao, Y., Song, A., Deng, W.Y.D., Chen, L.L.,Liu, J., Li, W.C., Srivastava, G., Spicer, R.A., Zhou, Z.K., Su, T. 2023. The oldest fossil record ofBauhiniass (Fabaceae) from the Tibetan Plateau sheds light on its evolutionary and biogeographic implications. Journal of Systematic Palaeontology, 21: 2244495.

6.Halaçlar, K., Rummy, P.,Liu, J., Hunt, A.P., Van Do, T., Minh, N.T., Deng, T. 2023. Exceptionally well-preserved crocodilian coprolites from the Late Eocene of Northern Vietnam: Ichnology and paleoecological significance. iScience, 26: 107607.

7.Hui, Z.*,Liu, J.*, Chevalier, M., Wei, X., Chen, P., Zhan, J., Peng, T., Zhou, X. 2023. Multiple forcing on Late Miocene East Asian Summer Monsoon Precipitation Variability in NE Tibetan Plateau. CATENA, 221: 106752.

8.Zhou, Z.,Liu, J., Chen, L., Spicer, R.A., Li, S., Huang, J., Zhang, S., Huang, Y., Jia, L., Hu, J., Su, T. 2023. Cenozoic plants from Tibet: An extraordinary decade of discovery, understanding and implications. Science China Earth Sciences, 66: 205–226.

9.杨久成,刘佳*,李雨,苏涛,李树峰,贾林波,周浙昆,张世涛*. 2022.滇东南普阳盆地含煤地层孢粉组合特征及其年代.生物多样性, 30: 21504.

10.Chen, P.R., Del Rio, C., Huang, J.,Liu, J., Zhao, J.G., Spicer, R.A., Li, S.F., Wang, T.X., Zhou, Z.K., Su, T. 2022. Fossil Capsular Valves ofKoelreuteria(Sapindaceae) from the Eocene of Central Tibetan Plateau and Their Biogeographic Implications. International Journal of Plant Sciences, 183: 307–319.

11.Han, T.S., Hu, Z.Y., Du, Z.Q., Zheng, Q.J.,Liu, J., Mitchell-Olds, T., Xing, Y.W. 2022. Adaptive responses drive the success of polyploid yellowcresses (Rorippa, Brassicaceae) in the Hengduan Mountains, a temperate biodiversity hotspot. Plant Diversity, 44: 455–467.

12.Huang, J., Spicer, R.A., Li, S.F.,Liu, J., Do, T.V., Nguyen, H.B., Zhou, Z.K., Su, T. 2022. Long-term floristic and climatic stability of northern Indochina: Evidence from the Oligocene Ha Long flora, Vietnam. Palaeogeography, Palaeoclimatology, Palaeoecology, 593: 110930.

13.Jia, L.B., Hu, J.J., Zhang, S.T., Su, T., Spicer, R.A.,Liu, J., Yang, J.C., Zou, P., Huang, Y.J., Zhou, Z.K. 2022.Bauhinia(Leguminosae) Fossils from the Paleogene of Southwestern China and Its Species Accumulation in Asia. Diversity, 14: 173.

14.Li, W.C., Huang, J., Chen, L.L., Spicer, R.A., Li, S.F.,Liu, J., Gao, Y., Wu, F.X., Farnsworth, A., Valdes, P.J., Zhou, Z.K., Su, T. 2022.Podocarpium(Fabaceae) from the late Eocene of central Tibetan Plateau and its biogeographic implication. Review of Palaeobotany and Palynology, 305: 104745.

15.Song, A.,Liu, J., Liang, S.Q., Van Do, T., Nguyen, H.B., Deng, W.Y.D., Jia, L.B., Del Rio, C., Srivastava, G., Feng, Z., Zhou, Z.K., Huang, J., Su, T. 2022. Leaf fossils ofSabalites(Arecaceae) from the Oligocene of northern Vietnam and their paleoclimatic implications. Plant Diversity, 44: 406–416.

16.Zhang, X., Gélin, U., Spicer, R.A., Wu, F., Farnsworth, A., Chen, P., Del Rio, C., Li, S.,Liu, J., Huang, J., Spicer, T.E.V., Tomlinson, K.W., Valdes, P.J., Xu, X., Zhang, S., Deng, T., Zhou, Z., Su, T. 2022. Rapid Eocene diversification of spiny plants in subtropical woodlands of central Tibet. Nature Communications, 13: 3787.

17.宋艾,杨久成,丁文娜,刘佳*. 2021.青藏高原高寒区生物地理学研究进展.冰川冻土, 43: 786–797.

18.Aung, A.T., Del Rio, C., Wang, T.X.,Liu, J., Spicer, T.E.V., Su, T. 2021. Fossil fruits and pollen grains ofTrapafrom the Upper Pliocene of the Sanying Formation (Yunnan, China). Review of Palaeobotany and Palynology, 293: 104498.

19.Del Rio, C., Wang, T.X., Xu, X.T., Sabroux, R., Spicer, T.E.,Liu, J., Chen, P.R., Wu, F.X., Zhou, Z.K., Su, T. 2021.Ventilago(Rhamnaceae) Fruit from the Middle Eocene of Central Tibet, China. International Journal of Plant Sciences, 182: 638–648.

20.Gao, X., Liu, J.H., Ruan, Q.J., Ge, J., Huang, Y.,Liu, J., Li, S., Guan, Y., Shen, H., Wang, Y. 2021. 300,000-year-old wooden tools from Gantangqing, southwest China. Biological Sciences, https://doi.org/10.21203/rs.3.rs-226285/v1.

21.Li, S.F., Valdes, P.J., Farnsworth, A., Davies-Barnard, T., Su, T., Lunt, D.J., Spicer, R.A.,Liu, J., Deng, W.Y.D., Huang, J., Tang, H., Ridgwell, A., Chen, L.L., Zhou, Z.K. 2021. Orographic evolution of northern Tibet shaped vegetation and plant diversity in eastern Asia. Science Advances, 7: eabc7741.

22.Liu, J., Wang, T.X., Zhang, X.W., Song, A., Li, S.F., Huang, J., Spicer, T., Spicer, R.A., Wu, F.X., Su, T., Zhou, Z.K. 2021. Snapshot of the Pliocene environment of West Kunlun region, Northwest China. Palaeobiodiversity and Palaeoenvironments, 101: 163–176.

23.Wang, T.X., Del Rio, C., Manchester, S.R.,Liu, J., Wu, F.X., Deng, W.Y.D., Su, T., Zhou, Z.K. 2021. Fossil fruits ofIlligera(Hernandiaceae) from the Eocene of central Tibetan Plateau. Journal of Systematics and Evolution, 59: 1276–1286.

24.周浙昆,王腾翔,黄健,刘佳,李仕虎,邓成龙,苏涛. 2020.西藏芒康似勾儿茶叶属(鼠李科)化石及其生物地理学意义.中国科学:地球科学, 50: 233–244.

25.Aung, A.T., Huang, J., Van Do, T., Song, A.,Liu, J., Zhou, Z.K., Su, T. 2020. Three new fossil records ofEquisetum(Equisetaceae) from the Neogene of south-western China and northern Vietnam. PhytoKeys, 138: 3–15.

26.Del Rio, C., Wang, T.X.,Liu, J., Liang, S.Q., Spicer, R.A., Wu, F.X., Zhou, Z.K., Su, T. 2020.Asclepiadospermumgen. nov., the earliest fossil record of Asclepiadoideae (Apocynaceae) from the early Eocene of central Qinghai-Tibetan Plateau, and its biogeographic implications. American Journal of Botany, 107: 126–138.

27.Deng, W., Su, T., Wappler, T.,Liu, J., Li, S., Huang, J., Tang, H., Low, S.L., Wang, T., Xu, H., Xu, X., Liu, P., Zhou, Z. 2020. Sharp changes in plant diversity and plant-herbivore interactions during the Eocene–Oligocene transition on the southeastern Qinghai-Tibetan Plateau. Global and Planetary Change, 194: 103293.

28.Guo, B., Peng, T., Yu, H., Hui, Z., Ma, Z., Li, X., Feng, Z.,Liu, J., Liu, S., Zhang, J., Ye, X., Song, C., Li, J. 2020. Magnetostratigraphy and Palaeoclimatic Significance of the Late Pliocene Red Clay-Quaternary Loess Sequence in the Lanzhou Basin, Western Chinese Loess Plateau. Geophysical Research Letters, 47: e2019GL086556.

29.Ma, Z., Li, X., Peng, T., Zhang, J., Dou, L., Yu, H.,Liu, J., Ye, X., Feng, Z., Li, M., Guo, B., Song, C., Zhao, Z., Li, J. 2020. Landscape evolution of the Dabanshan planation surface: Implications for the uplift of the eastern tip of the Qilian Mountains since the Late Miocene. Geomorphology, 356: 107091.

30.Su, T., Spicer, R.A., Wu, F.X., Farnsworth, A., Huang, J., Del Rio, C., Deng, T., Ding, L., Deng, W.Y.D., Huang, Y.J., Hughes, A., Jia, L.B., Jin, J.H., Li, S.F., Liang, S.Q.,Liu, J., Liu, X.Y., Sherlock, S., Spicer, T., Srivastava, G., Tang, H., Valdes, P., Wang, T.X., Widdowson, M., Wu, M.X., Xing, Y.W., Xu, C.L., Yang, J., Zhang, C., Zhang, S.T., Zhang, X.W., Zhao, F., Zhou, Z.K. 2020. A Middle Eocene lowland humid subtropical “Shangri-La” ecosystem in central Tibet. Proceedings of the National Academy of Sciences, 117: 32989–32995.

31.Tang, H., Li, S.F., Su, T., Spicer, R.A., Zhang, S.T., Li, S.H.,Liu, J., Lauretano, V., Witkowski, C.R., Spicer, T.E.V., Deng, W.Y.D., Wu, M.X., Ding, W.N., Zhou, Z.K. 2020. Early Oligocene vegetation and climate of southwestern China inferred from palynology. Palaeogeography, Palaeoclimatology, Palaeoecology, 560: 109988.

32.Zhou, Z., Wang, T., Huang, J.,Liu, J., Deng, W., Li, S., Deng, C., Su, T. 2020. Fossil leaves ofBerhamniphyllum(Rhamnaceae) from Markam, Tibet and their biogeographic implications. Science China Earth Sciences, 63: 224–234.

33.Liu, J., Su, T., Spicer, R.A., Tang, H., Deng, W.Y.D., Wu, F.X., Srivastava, G., Spicer, T., Van Do, T., Deng, T., Zhou, Z.K. 2019. Biotic interchange through lowlands of Tibetan Plateau suture zones during Paleogene. Palaeogeography, Palaeoclimatology, Palaeoecology, 524: 33–40.

34.Su, T., Farnsworth, A., Spicer, R.A., Huang, J., Wu, F.X.,Liu, J., Li, S.F., Xing, Y.W., Huang, Y.J., Deng, W.Y.D., Tang, H., Xu, C.L., Zhao, F., Srivastava, G., Valdes, P.J., Deng, T., Zhou, Z.K. 2019a. No high Tibetan Plateau until the Neogene. Science Advances, 5: eaav2189.

35.Su, T., Spicer, R.A., Li, S.H., Xu, H., Huang, J., Sherlock, S., Huang, Y.J., Li, S.F., Wang, L., Jia, L.B., Deng, W.Y.D.,Liu, J., Deng, C.L., Zhang, S.T., Valdes, P.J., Zhou, Z.K. 2019b. Uplift, Climate and Biotic Changes at the Eocene-Oligocene Transition in Southeast Tibet. National Science Review, 6: 495–504.

36.Tang, H.,Liu, J., Wu, F.X., Spicer, T., Spicer, R.A., Deng, W.Y.D., Xu, C.L., Zhao, F., Huang, J., Li, S.F., Su, T., Zhou, Z.K. 2019. Extinct genusLagokarposreveals a biogeographic connection between Tibet and other regions in the Northern Hemisphere during the Paleogene. Journal of Systematics and Evolution, 57: 670–677.