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田芳

时间:2020-04-14


田芳  博士,副教授,博士生导师

性别:    

籍贯:山西大同    

出生年月:1980.04

研究方向:孢粉、环境DNA、古生态、古气候、第四纪环境    

招生方向:自然地理学-全球气候环境变化    

邮箱:tianfang@cnu.edu.cn    

 

教育工作经历    

2018.10今:首都师范大学    

2016.062017.08:德国马克斯·普朗克气象学研究所,博士后(兼职)    

2015.072018.08:德国阿尔弗里德·魏格纳极地与海洋研究所,博士后    

2010.102015.07:德国波茨坦大学,古生态学,博士    

2007.092010.06:河北师范大学,自然地理学,硕士    

2002.092006.06:河北师范大学,地理科学,学士    

     

教学工作    

中国自然地理、水文学、第四纪环境学、沉积学原理与沉积环境等课程教学工作    

     

科研项目    

国家自然科学面上基金(2025.1–2028.12):青藏高原东缘末次冰消期以来林线迁徙及其对植物多样性的影响(主持    

国家自然科学面上基金(2021.1–2024.12):青藏高原湖泊沉积物环境DNA对植被指示意义的现代过程研究(主持    

国际(地区)合作与交流项目(2021.01–2023.12)青藏高原和西伯利亚北部多尺度气候-土壤-生态系统-人类交互作用(参与)    

国际(地区)合作与交流项目(2016.1–2018.12):基于花粉的8000年以来中国北温带地区人类活动引起的土地覆被变化对气候模拟的影响(参与)    

国家文物局(2023.03–2027.12):云南元谋猿人遗址考古工作计划(参与)    

Palmod program funded by German Ministry of Education and Science (2015.07-2018.08, 参与)    

国家自然科学基金面上项目(2014.1– 2017.12):中国北方森林区主要乔木植物花粉产量研究(参与)    

国家自然科学基金重点项目(2008.1–2011.12):中国人工和人工扰动植被花粉组合及人类活动强度研究(参与)    

国家自然科学基金面上项目(2006.1– 2008.12):中国北方季风气候区典型内陆湖泊花粉源区面积、花粉沉积动力和花粉沉积通量研究(参与)    

河北省自然科学基金(2009.1–2011.12):河北省不同类型湖泊花粉来源及沉积动力(参与)    

     

发表论文    

第一或通讯作者(下划线表示学生第一作者)    

1.   Tian, F.*, Chen, M., Jia, W., Herzschuh, U., Cao, X., 2023. Complementarity of lacustrine pollen and sedimentary DNA in representing vegetation on the central-eastern Tibetan Plateau. Frontiers of Earth Science, 17(4): 1037-1048.

2.    Tian, F.*, Chen, M., Xu, Q., Cao, X., 2023. A cool-arid climate with large temperature seasonality implied by arboreal pollen in the early Holocene, north-central China. Journal of Earth Science, 34(5): 1629-1631.

3.    Chen, M.,Tian, F.*, Cao, X., Zhang, W., Plessen, B., Mischke, S., 2023. Hydrological variations in the Yellow River Source area (NE Tibetan Plateau) during the last 7.4 ka inferred from stable isotopes of ostracod valves. Catena, 232: 107328.

4.    Cao, X., Wang, N., Cao, Y., Liu, L., Zhang, Y., Hou, X., Zhao, W., Li, Y., Tian, F.*, 2023. Hostile climate during the Last Glacial Maximum caused sparse vegetation on the north-eastern Tibetan Plateau. Quaternary Science Reviews, 301: 107916.

5.    Tian, F.*, Wang, W., Rudaya, N., Liu, X., Cao, X., 2022. Wet mid-late Holocen in central Asia supported prehistoric intercontinental cultural communication: clues from pollen data. Catena, 209: 105852.

6.    Tian, F.*, Qin, W., Zhang, R., Herzschuh, U., Ni, J., Zhang, C., Mischke, S., Cao, X., 2022. Palynological evidence for the temporal stability of the plant community in the Yellow River Source Area over the last 7400 years. Vegetation History and Archaeobotany, 31: 549–558.

7.    Tian, F.*, Cao, X., Zhang, R., Xu, Q., Ding, W., Liu, X., Pan, B., Chen, J., 2020. Spatial homogenization of soil-surface pollen assemblages improves the reliability of pollen-climate calibration-set. Science China Earth Sciences, 63: 1758–1766.

8.    Zhang, K.,Qin, W., Tian, F.*, Cao, X., Li, Y., Xiao, J., Ding, W., Herzschuh, U., Xu, Q., 2020. Influence of plant coverage and environmental variables on pollen productivities: evidence from northern China. Frontiers of Earth Science, 14: 789–802.

9.    Zhang, R., Tian, F.*, Xu, Q., Zhou, X., Liu, X., Cao, X., 2020. Representation of modern pollen assemblage to vertical variations of vegetation and climate in the Yadong area, eastern Himalaya. Quaternary International, 536: 45–51.

10.  Tian, F.*, Cao, X., Dallmeyer, A., Lohmann, G., Zhang, X., Ni, J., Andreev, A., Anderson, P.M., Lozhkin, A.V., Bezrukova, E., Rudaya, N., Xu, Q., Herzschuh, U., 2018. Biome changes and their inferred climatic drivers in northern and eastern continental Asia at selected times since 40 cal ka BP. Vegetation History and Archaeobotany, 27: 365–379.

11.  Tian, F., Cao, X., Dallmeyer, A., Zhao, Y., Ni, J., Herzschuh, U.*, 2017. Pollen-climate relationships in time (9 ka, 6 ka, 0 ka) and space (upland vs. lowland) in eastern continental Asia. Quaternary Science Reviews, 156: 1-11.

12.  Cao, X., Tian, F.*, Telford, R. J., Ni, J., Xu, Q., Chen, F., Liu X., Stebich M., Zhao Y., Herzschuh, U.*, 2017. Impacts of the spatial extent of pollen-climate calibration-set on the absolute values, range and trends of reconstructed Holocene precipitation. Quaternary Science Reviews, 178: 37-53.

13.  Tian, F., Cao, X., Dallmeyer, A., Ni, J., Zhao, Y., Wang, Y., Herzschuh, U.*, 2016. Quantitative woody cover reconstructions from eastern continental Asia of the last 22 kyr reveal strong regional peculiarities. Quaternary Science Reviews, 137: 33-44.

14.  Tian, F.*, Herzschuh, U., Telford, R. J., Mischke, S., Van der Meeren, T., Krengel, M., 2014. A modern pollen–climate calibration set from central‐western Mongolia and its application to a late glacial–Holocene record. Journal of Biogeography, 41(10): 1909-1922.

15.  Tian, F.*, Herzschuh, U., Mischke, S., Schlütz, F., 2014. What drives the recent intensified vegetation degradation in Mongolia–Climate change or human activity?. The Holocene, 24(10): 1206-1215.

16.  Tian, F.*, Herzschuh, U., Dallmeyer, A., Xu, Q., Mischke, S., Biskaborn, B. K., 2013. Environmental variability in the monsoon–westerlies transition zone during the last 1200 years: lake sediment analyses from central Mongolia and supra–regional synthesis. Quaternary Science Reviews, 73: 31-47.

17.  Tian, F., Cao, X., Xu, Q.*, Li, Y., 2009. A laboratorial study on influence of alkaline and oxidative environment on preservation of Pinus tabulaeformis pollen. Frontiers of Earth Science in China, 3: 226-230.

18.  Tian, F., Xu, Q.*, Li, Y., Cao, X., Wang, X., Zhang, L., 2008. Pollen assemblage characteristics of lakes in the monsoon fringe area of China. Chinese Science Bulletin, 53(21): 3354-3363.

19.  简安璟, 李昀卿, 刘斯瑶, 陈美娇, 曹维予, 孙喆, 侯居峙 田芳*, 2024. 青藏高原南部湖泊记录的晚全新世植被演化过程. 第四纪研究, 44(3): 742-754.

20.  张润鑫, 张心语, 姚昕, 王文轩, 秦问, 田芳*, 曹现勇, 2023. 喜马拉雅山脉中段南坡孢粉垂直分布特征及影响因素. 第四纪研究, 43(1): 300–309.

21.  王怡璇, 田芳*, 倪健, 曹现勇. 2023. 神经网络算法在生物群区重建中的可靠性及应用. 地理科学, 43(5): 889–898.

22.  李昀卿, 姚昕, 秦问, 刘祎, 庞宇欣, 张欣烨, 田芳*, 2024. 湖泊沉积物粒度揭示的河北坝上高原全新世环境演变. 地球环境学报(网络首发). https://link.cnki.net/urlid/61.1482.X.20241011.1123.002

23.  田芳*, 曹现勇, 张冉, 许清海, 丁伟, 刘兴起, 潘宝林, 陈建徽, 2020. 表层土壤孢粉组合的空间均质化可提高气候预测的可靠性. 中国科学:地球科学, 50(10): 1468-1476.


24.  田芳, 许清海*, 李月从, 曹现勇, 2010. 白洋淀湖泊表层花粉通量特征及来源途径分析. 地理科学, 30(06): 955-961.

     

合作作者论文    

25.  Wu, K., Li, K.*, Jia, W. Kathleen R. Stoof-Leichsenring, Herzschuh, U., Ni, J., Liao, M., Fang T., 2024. Application of plant DNA metabarcoding of lake sediments for monitoring vegetation compositions on the Tibetan Plateau. Sci. China Earth Sci. 67, 3594–3609 (2024). https://doi.org/10.1007/s11430-023-1358-0.

26. Li, W., Wang, N.*, Liang, C., Yu, S., Tian, F., Cao, X.*, 2023. Regional peculiarities in the importance of precipitation and temperature on mid-to-late Holocene arboreal degradation on the eastern Tibetan Plateau. Global and Planetary Change, 229: 104252.

27.  Cao, X.*, Tian, F., Herzschuh, U., Ni, J., Xu, Q., Li, W., Zhang, Y., Luo, M., Chen, F., 2022. Human activities have reduced plant diversity in eastern China over the last two millennia. Global Change Biology, 28(16): 4962–4976.

28.  Cao, X.*, Chen, J., Tian, F., Xu, Q., Herzschuh, U., Telford, R., Huang, X., Zheng, Z., Shen, C., Li, W., 2022. Long-distance modern analogues bias results of pollen-based precipitation reconstructions. Science Bulletin, 67: 1115–1117.

29.  Li, W., Tian, F., Rudaya, N., Herzschuh, U., Cao, X.*, 2022. Pollen-based Holocene thawing-history of permafrost in northern Asia and its potential impacts on climate change. Frontiers in Ecology and Evolution, 10: 894471.

30.  Jia, W., Anslan, S., Chen, F., Cao, X., Dong, H., Dulias, K., Gu, Z., Heinecke, L., Jiang, H., Kruse, S., Kang, W., Li, K., Liu, S., Liu, X., Liu, Y., Ni, J., Schwalb, A., Stoof-Leichsenring, K., Shen, W., Tian, F., Wang, J. Wang, Y., Wang, Y., Xu, H., Yang X., Zhang, D., Herzschuh, U.*, 2022. Sedimentary ancient DNA reveals past ecosystem and biodiversity changes on the Tibetan Plateau: Overview and prospects. Quaternary Science Reviews, 293: 107703.

31.  Cao, X.*, Tian, F., Li, K., Ni, J., Yu, X., Liu, L., Wang, N., 2021. Lake surface-sediment pollen dataset for the alpine meadow vegetation type from the eastern Tibetan Plateau and its potential in past climate reconstructions. Earth System Science Data Discussions, 2021: 1-22.

32.  Cao, X., Tian, F., 2021. Pollen-based biome reconstruction in R. DOI: 10.5281/zenodo.5031250.

33.  Cao, X.*, Tian, F., Li, K., Ni, J., Yu, X., Liu, L., Wang, N., 2021. Lake surface sediment pollen dataset for the alpine meadow vegetation type from the eastern Tibetan Plateau and its potential in past climate reconstructions. Earth System Science Data, 13: 3525–3537.

34.  Cao, X.*, Tian, F., Andreev, A., Anderson, P.M., Lozhkin, A.V., Bezrukova, E., Ni, J., Rudaya, N., Stobbe, A., Wieczorek, M., Herzschuh, U.*, 2020. A taxonomically harmonized and temporally standardized fossil pollen dataset from Siberia covering the last 40 kyr. Earth System Science Data, 12: 119–135.

35.  Cao, X.*, Tian, F., Andreev, A., Anderson, P. M., Lozhkin, A. V., Bezrukova, E., Ni J., Rudaya N., Stobbe A., Wieczorek M., Herzschuh, U.*, 2020. A taxonomically harmonized and temporally standardized fossil pollen dataset from Siberia covering the last 40 kyr. Earth System Science Data, 12(1): 119-135.

36.  Cao, X.*, Tian, F., Li, F., Gaillard, M. J., Rudaya, N., Xu, Q., Herzschuh, U.*, 2019. Pollen-based quantitative land-cover reconstruction for northern Asia covering the last 40 ka cal BP. Climate of the Past, 15(4): 1503-1536.

37.  Herzschuh, U.*, Cao, X.*, Laepple, T., Dallmeyer, A., Telford, R., Ni, J., Chen, F., Kong, Z., Liu, G., Liu, K.-B., Liu, X., Stebich, M., Tang, L., Tian, F., Wang, Y., Wischnewski, J., Xu, Q., Yan, S., Yang, Z., Yu, G., Zhang, Y., Zhao, Y., Zheng, Z., 2019. Position and orientation of the westerly jet determined Holocene rainfall patterns in China. Nature Communications, 10: 2376.

38.  Cao, X.*, Tian, F., Dallmeyer, A., Herzschuh, U.*, 2019. Northern Hemisphere biome changes (>30°N) since 40 cal ka BP and their driving factors inferred from model-data comparisons. Quaternary Science Reviews, 220: 291–309.

39.  Cao, X.*, Tian, F., Li, F., Gaillard, M.-J., Rudaya, N., Herzschuh, U., 2019. Pollen-based quantitative land-cover reconstruction for northern Asia during the last 40 ka. Climate of the Past, 15: 1503–1536.

40.  Cao, X.*, Tian, F., Ding, W., 2018. Improving the quality of pollen-climate calibration-sets is the primary step for ensuring reliable climate reconstructions. Science Bulletin, 63: 1317–1318.

41. Heinecke, L.*, Fletcher, W. J., Mischke, S., Tian, F., Herzschuh, U.*, 2018. Vegetation change in the eastern Pamir Mountains, Tajikistan, inferred from Lake Karakul pollen spectra of the last 28 kyr. Palaeogeography, palaeoclimatology, palaeoecology, 511: 232-242.

42.  Xu, Q.*, Zhang, S., Gaillard, M. J., Li, M., Cao, X., Tian, F., Li, F., 2016. Studies of modern pollen assemblages for pollen dispersal-deposition-preservation process understanding and for pollen-based reconstructions of past vegetation, climate, and human impact: A review based on case studies in China. Quaternary Science Reviews, 149: 151-166.

43.  Zhang, S., Xu, Q.*, Gaillard, M. J., Cao, X., Li, J., Zhang, L., Li Y., Tian F., Zhou L., Lin, F., Yang, X., 2016. Characteristic pollen source area and vertical pollen dispersal and deposition in a mixed coniferous and deciduous broad-leaved woodland in the Changbai mountains, northeast China. Vegetation history and archaeobotany, 25: 29-43.

44.  Mischke, S.*, Lai, Z., Long, H., Tian, F., 2016. Holocene climate and landscape change in the northeastern Tibetan Plateau foreland inferred from the Zhuyeze Lake record. The Holocene, 26(4): 643-654.

45.  Xu, Q.*, Cao, X., Tian, F., Zhang, S., Li, Y., Li, M., Li, J., Liu, Y., Liang, J., 2014. Relative pollen productivities of typical steppe species in northern China and their potential in past vegetation reconstruction. Science China Earth Sciences, 57: 1254-1266.

46. Herzschuh, U.*, Borkowski, J., Schewe, J., Mischke, S., Tian, F., 2014. Moisture-advection feedback supports strong early-to-mid Holocene monsoon climate on the eastern Tibetan Plateau as inferred from a pollen-based reconstruction. Palaeogeography, Palaeoclimatology, Palaeoecology, 402: 44-54.

47.  Zibulski, R.*, Herzschuh, U., Pestryakova, L. A., Wolter, J., Müller, S., Schilling, N., Wetterich, S., Schirrmeister, L., Tian, F., 2013. River flooding as a driver of polygon dynamics: modern vegetation data and a millennial peat record from the Anabar River lowlands (Arctic Siberia). Biogeosciences, 10(8): 5703-5728.

48. Xu, Q.*, Tian, F., Bunting, M. J., Li, Y., Ding, W., Cao, X., He, Z., 2012. Pollen source areas of lakes with inflowing rivers: modern pollen influx data from Lake Baiyangdian, China. Quaternary Science Reviews, 37: 81-91.

49.  Xu, Q.*, Xiao, J., Li, Y., Tian, F., Nakagawa, T., 2010. Pollen-based quantitative reconstruction of Holocene climate changes in the Daihai Lake area, Inner Mongolia, China. Journal of Climate, 23: 2856-2868.

50. Xu, Q.*, Li, Y., Bunting, M. J., Tian, F., Liu, J., 2010. The effects of training set selection on the relationship between pollen assemblages and climate parameters: Implications for reconstructing past climate. Palaeogeography, Palaeoclimatology, Palaeoecology, 289(1-4): 123-133.

51.  Cao, X., Xu, Q.*, Jing, Z., Tang, J., Li, Y., Tian, F., 2010. Holocene climate change and human impacts implied from the pollen records in Anyang, central China. Quaternary International, 227(1): 3-9.

52.  Wang, X., Li, Y.*, Xu, Q., Cao, X., Zhang, L.,Tian, F., 2010. Pollen assemblages from different agricultural units and their spatial distribution in Anyang area. Chinese Science Bulletin, 55(6): 544-554.

53. Xu, Q.*, Li, Y., Tian, F., Cao, X., Yang, X., 2009. Pollen assemblages of tauber traps and surface soil samples in steppe areas of China and their relationships with vegetation and climate. Review of Palaeobotany and Palynology, 153(1-2): 86-101.

54. Cao, X., Tian, F., Xu, Q.*, Li, Y., Chen, L., Bai, X., 2009. A laboratorial study of the effect of oxygenation environment on the preservation of pinus tabulaef ormis pollen. Journal of Glaciology and Geocryology, 31(3): 571-575.

55.  李洁, 许清海*, 曹现勇, 田芳, 丁伟, 梁剑. 2014. 晋冀低山丘陵区人工扰动植被花粉组合特征. 古地理学报, 16(02): 227-238.

56.  李月从*, 许清海, 葛亚汶, 李英, 吕素青, 曹现勇, 田芳, 郝利生, 2014.黄土高原中东部沙尘与非沙尘天气花粉组成及来源范围. 地理研究, (12):2367-2381.

57.  王学丽, 李月丛*, 许清海, 曹现勇, 张丽艳, 田芳, 2010. 安阳地区不同农业单元表土花粉组合及空间分异. 科学通报, (19): 1914-1923.

58.  曹现勇, 田芳, 许清海*, 李月丛, 陈利, 白旋, 2009. 氧化环境对油松花粉保存影响实验研究. 冰川冻土, 31(03):571-575.

59.  许清海*, 田芳, 李月丛, 阳小兰, 2009. 中国北方草原区捕捉器样品与表土样品花粉组合及其与植被和气候的关系. 古地理学报, 11(01): 81-90.

60.  张丽艳, 许清海*, 李月丛, 王学丽, 曹现勇, 田芳, 2009. 长白山针阔叶混交林带花粉通量及垂直散布年际对比. 古生物学报, 48(02): 222-227.

61.  郑振华, 田芳, 曹现勇, 许清海*, 李月丛, 阳小兰, 2008. 中原地区不同植被类型花粉组合特征及对周围植被的代表性. 地理与地理信息科学, (04): 92-97.

62.  曹现勇, 田芳, 许清海*, 李月丛, 张振卿, 贾红娟, 张丽艳, 王学丽, 2007. 阴山山脉东段花粉通量及其与表土花粉比较研究. 古生物学报, (04): 411-418.