学士(B. E.) 1981.9-1985.7 华东水利学院（现河海大学） 陆地水文 硕士(M. E.) 1989.9-1993.7 同上 水文与水资源 博士(D. S.) 1995.4-1999.6 名古屋大学 大气水圈科学

助教(Assistant Prof.) 1985.8-1991.11 河海大学(Hohai Univ.) 讲师(Lecture) 1991.12-1993.10 同上 研究员(Research Scientist) 2000.2-2007.3 海洋研究开发机构 主任研究员(Senior Scientist) 2007.4-2016.5 同上 团队副首席(Sub Leader) 2005.12-2009.3 同上 团队首席(Team Leader) 2009.4-2014.Ⴕ୔

主要项目 起止时间 项目性质和来源 经费总额 参与人数 具体职位和任务 2007.4-2009.12 中日合作研究(JSPS-NSFC) 412万日元 3 日方负责人 2010.4-2015.3 温暖化评价方法的开发与指南的制定(环境省委托特别研发项目) 2566万日元 4 参与编写气候变化评价指南 2010.10-2015.3 气候变化与河流水资源管理系统的开发(文科省委托温暖化对策重点研发项目) 1亿1995万日元 4 子课题负责人 2010.4-2015.3 用于城市暑热环境短期暴雨适应对策的降尺度模型的开发(文科省委托温暖化对策重点研发项目) 4820万日元 4 子课题负责人 2010.4-2015.3 日本海沿岸地区随温暖化带来的降雪变化预测与适应对策的降尺度技术手法的开发(文科省委托温暖化对策重点研发项目) 1亿841万日元 4 参与气候变化对水资源影响的评价 2014.10-2019.3 用于智能农作物气象预测技术的开发(内阁府委托新一代农林水产业创造技术重点研发项目) 3621万日元 2 子课题负责人 2015.12-2020.3 气候变化适应技术应用与推广(文科省委托温暖化对策重点研发项目) 14亿5千万日元 40 参与动力学降尺度技术研究开发 2019.1-2022.12 国家自然科学基金面上项目：基于CMIP6的澜沧江流域水-能源-粮食关系链研究 62万 9 主持

1. X. Ma and W. Cheng, 1996: A modeling of hydrological processes in a large low plain area including lakes and ponds，J. Japan Soc. Hydrol. & Water Resour., 9, 320-329. doi: 10.3178/jjshwr.9.320. 2. X. Ma, T. Hiyama, Y. Fukushima and T. Hashimoto, 1998: A numerical model of the heat transfer for permafrost regions, J. Japan Soc. Hydrol. & Water Resour. 11, 346-359. doi: 10.3178/jjshwr.11.346. 3. X. Ma, Y. Fukushima, T. Hashimoto, T. Hiyama and T. Nakashima, 1999: Application of a simple SVAT model in a mountain catchment under temperate humid climate, J. Japan Soc. Hydrol. & Water Resour. 12, 285-294. doi:10.3178/jjshwr.12.285. 4. X. Ma, Y. Fukushima, T. Hiyama, T. Hashimoto and T. Ohata, 2000: A macro-scale hydrological analysis of the Lena River basin, Hydrol. Process., 14, 639-651. doi: 10.1002/(SICI)1099-1085(20000228)14:3<639::AID-HYP959>3.0.CO;2-0. 5. X. Ma, Y. Fukushima and T. Ohata, 2001: Hydrological modelling of river ice processes in cold region. IAHS Publ., 270, 327-331. 6. X. Ma and Y. Fukushima, 2002: A numerical model of the river freezing process and its application to the Lena River. Hydrol. Process., 16, 2131-2140. doi: 10.1002/hyp.1146. 7. L.C. Bowling, D.P. Lettenmaier, B. Nijssen, L.P. Graham, D.B. Clark, M.E. Maayar, R. Essery, S. Goers, F. Habets, B. Hurk, J. Jin, D. Kahan, D. Lohmann, X. Ma, S. Mahanama, D. Mocko, O. Nasonova, P. Samuelsson, A.B. Shmakin, K. Takata, D. Verseghy, P. Viterbo, Y. Xia, Y. Xue, Z. Yang, 2003: Simulation of high latitude hydrological processes in the Torne-Kalix basin: PILPS Phase 2(e) 1: Experiment description and summary intercomparisons. Global and Planetary Change, 38, 1-30. doi: 10.1016/S0921-8181(03)00003-1. 8. B. Nijssen, L.C. Bowling, D.P. Lettenmaier, D.B. Clark, M.E. Maayar, R. Essery, S. Goers, F. Habets, B. Hurk, J. Jin, D. Kahan, D. Lohmann, X. Ma, S. Mahanama, D. Mocko, O. Nasonova, P. Samuelsson, A.B. Shmakin, K. Takata, D. Verseghy, P. Viterbo, Y. Xia, Y. Xue, Z. Yang, 2003: Simulation of high latitude hydrological processes in the Torne-Kalix basin: PILPS Phase 2(e) 2: Comparison of model results with observations. Global and Planetary Change, 38, 31-53. doi:10.1016/S0921-8181(03)00004-3. 9. X. Ma, T. Yasunari, T. Ohata, L. Natsagdorj, G. Davaa and D. Oyunbaatar, 2003: Hydrological regime of the Selenge River basin, Mongolia. Hydrol. Process., 17, 2929-2945. doi: 10.1002/hyp.1442. 10. X. Ma, T. Yasunari, T. Ohata, and Y. Fukushima, 2005: The influence of river ice on spring runoff in the Lena River, Siberia. Ann. Glaciol., 40, 123-127. doi: 10.3189/172756405781813744. 11. Y. Sato, X. Ma, M. Matsuoka and Y. Fukushima, 2007: Impacts of human activity on long-term water balance in the middle-reaches of the Yellow River basin. IAHS Publ., 315, 85-91. 12. Y. Sato, X. Ma, J. Xu, M. Matsuoka, H. Zheng, C. Liu and Y. Fukushima, 2008: Analysis of long-term water balance in the source area of the Yellow River basin. Hydrol. Process., 22, 1618-1629. doi: 10.1002/hyp.6730. 13. Y. Sato, A. Onishi, Y. Fukushima, X. Ma, J. Xu, M. Matsuoka and H. Zheng, 2009: An integrated hydrological model for the long-term water balance analysis of the Yellow River basin, China. In: From Headwaters to the Ocean: Hydrological changes and watershaeds mangment (eds. ), Taylor and Francis, London, pp. 209-215. 14. X. Ma, Y. Fukushima, T. Yasunari, M. Matsuoka, Y. Sato, F. Kimura and H. Zheng, 2010: Examination of the water budget in upstream and midstream regions of the Yellow River, China. Hydrol. Process., 24, 618-630. doi:10.1002/hyp.7556. 15. X. Ma, T. Yoshikane, M. Hara, Y. Wakazuki, H. Takahashi, F. Kimura, 2010: Hydrological response to future climate change in the Agano River basin, Japan. Hydrol. Res. Lett., 4, 25-29. doi: 10.3178/HRL.4.25. 16. T. Yoshikane, M. Hara, X. Ma, H. Kawase and F. Kimura, 2011: Simulated Snow Water Equivalent Change between the 1980s and 1990s in the Sea of Japan Side Area Using a Regional Climate Model. J. Meteorol. Soc. Jpn., 89(3), 269-282. doi:10.2151/jmsj.2011-307. 17. H. Takahashi, N. Ishizaki, H. Kawase, M. Hara, T. Yoshikane, X. Ma and F. Kimura, 2013: Potential impact of sea surface temperature on winter precipitation over the Japan Sea side of Japan: A regional climate modeling study. J. Meteorol. Soc. Jpn., 91(4), 471-488. doi:10.2151/jmsj.2013-404. 18. X. Ma, H. Kawase, S. Adachi, M. Fujita, H. G. Takahashi, M. Hara, N. Ishizaki, T. Yoshikane, H. Hatsushika, Y. Wakazuki and F. Kimura, 2013: Simulating river discharge in a snowy region of Japan using output from a regional climate model. Adv. Geosci., 35, 55-60. doi:10.5194/adgeo-35-55-2013. 19. Y. Wakazuki, M. Hara, M. Fujita, C. Suzuki, X. Ma and F. Kimura, 2015: Effect of climate change on the snow disappearance date in mountainous areas of central Japan. Hydrol. Res. Lett., 9, 20-26. doi: 10.3178/hrl.9.20. 20. H. Takahashi, S. Adachi, T. Sato, M. Hara, X. Ma and F. Kimura, 2015: An oceanic impact of the Kuroshio on surface air temperature on the Pacific coast of Japan in summer: Regional H2O greenhouse gas effect. J. Clim., 28, 7128-7144. doi:10.1175/JCLI-D-14-00763.1. 21. Y. Wakazuki, M. Hara, M. Fujita, X. Ma, F. Kimura and T. Koike, 2015: Probabilistic climate change projection in Kanto and Japan Alps regions using incremental dynamical downscaling. J. Japan Society of Civil Engineers, Ser. B1, Vol. 72, No.4. 22. S. Adachi, F. Kimura, H. Takahashi, M. Hara, X. Ma and H. Tomita, 2016: Impact of high-resolution sea surface temperature and urban data on estimations of surface air temperature in a regional climate. J. Geophys. Res. Atmos., 121, 10,486-10,504. doi: 10.1002/2016JD024961. 23. Y. Li, A. Feng, W. Liu, X. Ma and G. Dong, 2017: Variation of aridity index and the role of climate variables in the Southwest China. Water, 9, 743. doi: 10.3390/w9100743. 24. W. Shao, Y. Su, Z. Yang, X. Ma and J. Langhammer, 2018: Quantify the pore water velocity distribution by a celerity function. Geofluids, doi: 10.1155/2018/1054730. 25. Y. Zhu, Y. Liu, X. Ma, L. Ren and V. P. Singh, 2018: Drought analysis in the Yellow River basin based on a short-scalar Palmer drought severity index. Water, 10, 1526. doi: 10.3390/w10111526. 26. W. Shao, Z. Yang, J. Ni, Y. Su, W. Nie and X. Ma, 2018: Comparison of single- and dual-permeability models in simulating the unsaturated hydro-mechanical behavior in a rainfall-triggered landslide. Landslides, 15, 2449-2464. doi: 10.1007/s10346-018-1059-0. 27. S. Wang, H. Zuo, Y. Yin, C. Hu, J. Yin, X. Ma and J. Wang, 2019: Interpreting rainfall anomalies using rainfall’s nonnegative nature. Geophys. Res. Lett., 46,426–434. doi:10.1029/2018GL081190. 28. Y. Li, W. Yu, K. Wang and X. Ma, 2019: Comparison of the aridity index and its drivers in eight climatic regions in China in recent years and in future projections. Int. J. Climatol., 39(14), 5256-5272. doi: 10.1002/joc.6137. 29. S. Wang, H. Zuo, Y. Yin and X. Ma, 2019: Asymmetric impact of East Asian jet’s variation on midsummer rainfall in North China and Yangtze River Valley. Clim. Dynam., 53, 6199–6213. doi: 10.1007/s00382-019-04923-w. 30. Y. Zhu, Y. Liu, W. Wang, V. P. Singh, X. Ma and Z. Yu, 2019: Three dimensional characterization of meteorological and hydrological droughts and their probabilistic links. J. Hydrol., 578, 124016. doi: 10.1016/j.jhydrol.2019.124016. 31. 张建梅、马燮铫、李艳忠，2020：1980-2016年黄河中游河龙区间植被动态及其对径流的影响。南水北调与水利科技。（已录用） 32. M. Liu, Y. Yin, X. Ma, Z. Zhang, G. Wang and S. Wang, 2020: Encounter probability and risk of flood and drought under future climate change in the two tributaries of the Rao River basin, China. Water, 12(1), 104. doi: 10.3390/w12010104. 33. 严昌盛、朱德华、马燮铫、徐胜、王凯，2020：基于雷达短时临近降雨预报的王家坝洪水预报研究。水利水电技术。（已录用）

1. X. Ma and Y. Fukushima, 2002. Numerical model of river flow formation from small to large scale river basins, In: Mathematical Models of Watershed Hydrology (eds. V. P. Singh, D.K. Frevert), Water Resources Publications, Littleton, Colorado, pp. 433-470. 2. X. Ma and Y. Fukushima, 2002. SVAT&HYCY, In: MathMod1 (CD-ROM with 16 modeling programs), Water Resources Publications, Littleton, Colorado. 3. X. Ma and H. Kawase, 2009. Effect of irrigation on runoff and local cloud system in the Yellow River basin. In Arid Environments and Wind Erosion (eds. A. Fernandez-Bernal and M. A. De La Rosa), Nova Science Publishers, Inc., Hauppauge, NY, pp. 75-91. 4. X. Ma, Y. Sato, T. Yoshikane, M. Hara, F. Kimura and Y. Fukushima, 2012. Hydrological analysis of the Yellow River basin, China. In: C.R. Goldman, M. Kumagai and R.D. Robarts (eds) Climatic Change and Global Warming of Inland Waters: Impacts and Mitigation for Ecosystems and Societies, Wiley-Blackwell, Chichester, pp.67-78. 5. 郑红星，马燮铫，王中根，吴险峰，2006. SVAT&HYCY模型及其应用。流域水循环分布式模拟(刘昌明，郑红星，王中根编)，黄河水利出版社，pp. 152-163. 6. 馬燮銚（2008）：領域モデルによる大気水収支法の適用とその結果。黄河の水環境問題（福嶌·谷口編）、学報社。pp.76-80. 7. 馬燮銚（2013）：大陸スケールの河川と水循環。地球環境の事典（吉崎正憲ら編）、朝倉書店。pp.148-149.