生态学博士，中国科学院生态环境研究中心特聘研究员，中国科学院大学博士研究生指导教师，云南大学和长安大学外聘研究生导师。主要从事景观与区域生态学、旱区生态修复、生态水文与水土保持研究，以往科研经历多集中于探讨脆弱山地降雨特性和下垫面土地利用/景观格局演变的生态水文响应机制。先后主持国家重点研发计划课题、国家自然科学基金联合重点基金项目、面上基金项目、重点基金课题、重大基金专题、科技支撑计划专题、环保部生态环境评估课题累计20余项。发表论文130余篇（SCI论文60多篇），主编专著2部，参编专著6项，国家专利9项。在人地耦合与作用关系、降雨格局定量分类、极端气候事件的发生规律及其驱动、土地利用/植被演替的生态影响、旱区植被恢复与水土保持的时空调控策略、地表水土流失多尺度效应等方面有系统研究和长期积累。同时关注典型区域、国家尺度和全球尺度梯田景观分布格局及其对生态水文过程、生态系统服务和人类福祉的综合影响，并着力探讨其可持续性。

教育经历：

1997.09-2001.06：西北农林科技大学，农学学士

2001.09-2004.06：西北农林科技大学，理学硕士

2004.09-2007.06：中国科学院生态环境研究中心，理学博士

工作经历：

2007.07-2011.03：中国科学院生态环境研究中心，城市与区域生态国家重点实验室，助理研究员

2011.03-2018.02：中国科学院生态环境研究中心，城市与区域生态国家重点实验室，副研究员 （期间2015.08-2016.08: 美国普渡大学地球科学系， 访问学者）

2018.02- 中国科学院生态环境研究中心，城市与区域生态国家重点实验室，研究员

 

《生态学杂志》、《环境生态学》、国际SCI期刊《Land》等杂志编委，国际梯田景观联盟组织创刊期刊《the Journal of Terraced Landscapes》杂志科学委员会委员；重庆缙云山三峡库区森林生态系统国家定位监测站学术委员会委员；中国生态学学会区域生态专业委员会副主任委员兼秘书长、中国生态学学会生态水文学专业委员会委员、中国水土保持学会林草生态修复工程专业委员会常务委员、中国水土保持学会水土保持学科建设和人才培养专业委员会委员、中国土壤学会土壤侵蚀与水土保持专业委员会委员、中国地理学会会员、国际梯田景观联盟组织（ITLA）成员/中国区联络人，国家自然科学基金委/北京市自然科学基金委项目函评专家。曾任祁连山国家公园和普达措国家公园现场核查暨评估验收专家组成员。2022年8月被国家林草局认定为《联合国荒漠化防治公约》科学与政策交互平台国际独立专家（Independent Scientist for UNCCD Science & Policy Interface）。  

ORCiD: https://orcid.org/0000-0003-0887-3204  

1. 十四五国家重点研发课题：“黄土高原缓坡丘陵区油松和柠条林水土保持及碳汇功能提升技术”（2022-2026）（批准号：2022YFF1300403），课题负责人；
2. 国家自然科学基金联合重点项目：“甘肃黄土区梯田工程的水-碳-粮-能服务效应与耦合机制”（2022-2025）（批准号：U21A2011）,项目负责人；
3. 国家自然科学基金面上项目：“黄土高原小流域植被恢复与坡改梯工程耦合的生态水文机理”（2020—2023）（批准号：40971129），项目负责人；
4. 十三五国家重点研发计划课题：“典型脆弱生态修复与保护研究”重点专项：“黄土高原水土流失综合防治技术示范”（2016—2021），课题负责人；
5. 国家自然科学基金重大项目专题：“干旱半干旱地区水循环变化对生态系统的影响机制”（2020-2024）（课题号：41991233），专题负责人；
6. 中科院青促会优秀会员专项：“坡改梯工程的生态服务效应”（2019-2021），项目负责人；
7. 国家部委项目：“基于特定风险防控的景观格局优化方案”（2019-2020），专题负责人；
8. 陕西省科技项目：“典型县域水土保持项目生态效益评估”（2019-2020），课题负责人；
9. 国家自然科学基金面上项目：“黄土丘陵区坡面尺度不同整地方式的生态水文效应”（2014—2017）（批准号：41371123），项目负责人；
10. 国家重大基金专题：“黄土高原草灌生态系统与土壤水分的相互作用机理”（2014—2018），专题负责人；
11. 国家重点基金课题：“城市景观格局演变的暴雨径流效应及面源污染防控”（2013—2017），课题负责人；
12. 国家科技支撑专题：“区域植被生态系统可持续性评估与恢复技术试验示范”（2014—2018），专题负责人；
13. 国家生态十年评估重大课题：“环渤海沿海地区生态环境十年变化遥感调查与评估” （2011—2013），课题负责人；
14. 中科院青促会会员项目：（2014—2018），项目负责人；
15. 国家重点实验室项目：（2014—2020），课题负责人；
16. 国家自然科学基金青年项目：“黄土小流域水蚀过程对降雨和土地利用格局演变的响应机制”（2009—2011）（批准号：40801041），项目负责人。 

 

1.Liu ZM, Rong L, Wei W*, 2023. Impacts of land use/cover change on water balance by using the SWAT model in a typical loess hilly watershed of China. Geography and Sustainability. 4: 19–28. 

2.Wei W*, Pan DL, Feng J, 2022.Tradeoffs between soil conservation and soil-water retention: the role of vegetation pattern and density. Land Degradation & Development. 33：18-27. Doi:10.1002/ldr.4123

3.Wei W*, Pan DL, Yang Y, 2021. Effects of terracing measures on water retention of pinus Tabulaeformis forest in the dryland loess hilly region of China. Agricultural and Forest Meteorology.308-309,108544. 

4.Chen D, Wei W*, Chen LD,2021. Effects of terracing on soil properties in three key mountainous regions of China. Geography and Sustainability. 2:195-206. https://doi.org/10.1016/j.geosus.2021.08.002

5.Qi YL, Wei W*, Li JR, Chen CG, Huang YY, 2020. Effects of terracing on root distribution of Pinus tabulaeformis Carr. forest and soil properties in the Loess Plateau of China. Science of the Total Environment. https://doi.org/10.1016/j.scitotenv.2020.137506

6.Feng J, Wei W*, Pan DL, 2020. Effects of rainfall and terracing-vegetation combinations on water erosion in a loess hilly area, China. Journal of Environmental Management. https://doi.org/10.1016/j.jenvman.2020.110247

7.Zhang QD, Wei W*, Chen LD, Yang L, Luo YQ , Cai AD, 2020. Plant traits in influencing soil moisture in semiarid grasslands of the Loess Plateau, China. Science of the Total Environment. https://doi.org/10.1016/j.scitotenv.2020.137355

8.Chen D, Wei W*, Chen LD, 2020. How can terracing impact on soil moisture variation in China A meta-analysis. Agricultural Water Management 227, 105849. https://doi.org/10.1016/j.agwat.2019.105849

9.Chen D, Wei W*, Stefani D, Paolo T, 2020. Does terracing enhance soil organic carbon sequestration A national-scale data analysis in China. Science of the Total Environment. https://doi.org/10.1016/j.scitotenv.2020.137751

10.Liu W, Feng Q, Deo RC, Yao L,Wei W*, 2020. Experimental study on the rainfall-runoff responses of typical urban surfaces and two green infrastructures using scale-Based Models. Environmental Management 66:683–693.

11.Wei W, Feng XR, Yang L, Chen LD*, Feng TJ, Chen D, 2019. The effects of terracing and vegetation on soil moisture retention in a dry hilly catchment in China. Science of the Total Environment 647: 1323-1332.

12.Zhang QD, Wei W*,Chen LD, Yang L, 2019. The joint effects of precipitation gradient and afforestation on soil moisture across the Loess Plateau of China. forests 10(3), 285

13.Zhang QD,Wei W*,?Chen LD, Yang L, Chen HY, Luo YQ, 2019. Soil Water Availability Drives Changes in Community Traits along a Hydrothermal Gradient in Loess Plateau Grasslands. Rangeland Ecology and Management in press.

14.Feng TJ, Wei W*, Chen LD, Jes s R, Yang L, Yu Y, 2019. Combining land preparation and vegetation restoration for optimal soil eco-hydrological services in the Loess Plateau, China. Science of the Total Environment 657: 535-547.

15.Qi YL, Wei W*, Chen CG, Chen LD, 2019. Plant root-shoot biomass allocation over diverse biomes: A global synthesis. Global Ecology and Conservation 18: 1-14.

16.Yu Y, Wei W*, Chen LD, Feng TJ, Stefani D, 2019. Quantifying the effects of precipitation, vegetation, and land preparation techniques on runoff and soil erosion in a loess watershed of China. Science of the Total Environment 652: 755-764.

17.Feng TJ, Wei W*, Chen LD, Jes s R, Chen D, Feng XR, Ren KM, Eric C. B., Yu Y, 2018. Assessment of the impact of different vegetation patterns on soil erosion processes on semiarid loess slopes. Earth Surface Processes and Landforms. 43: 1860-1870. DOI: 10.1002/esp.4361

18.Feng TJ, Wei W*, Chen LD, S.D. Keesstra and Yu Y, 2017. Effects of land preparation and plantings of vegetation on soil moisture in a hilly loess catchment in China. Land Degradation & Development, DOI: 10.1002/ldr.2867

19.Chen D, Wei W*, Chen LD, 2017. Effects of terracing practices on water erosion control in China: A meta-analysis. Earth-Science Reviews, 173: 109-121.

20.Zhang HD, Wei W*, Chen LD, Wang LX, 2017. Effects of terracing on soil water and canopy transpiration of Pinus tabulaeformis in the Loess Plateau of China. Ecological Engineering, 102: 557-564.

21.Zhang HD, Wei W*, Chen LD, Yang L, 2017. Evaluating canopy transpiration and water use of two typical planted tree species in the dryland Loess Plateau of China. Ecohydrology, 10: 1-10.

22.Yu Y, Wei W*, Chen LD, Feng TJ, Stefani D, Wang LX, 2017. Land preparation and vegetation type jointly determine soil conditions after long-term land stabilization measures in a typical hilly catchment, Loess Plateau of China.Journal of soils and sediments, 17: 144-156.

23.Yao L, Chen LD, Wei W*, 2017. Exploring the Linkage between Urban Flood Risk and Spatial Patterns in Small Urbanized Catchments of Beijing, China. International Journal of ER& PH, 14:239-255.

24.Wei W, Chen D, Wang LX, Stefani D, Chen LD*, Yu Y, Lu YL, Sun G, Feng TJ, 2016. Global synthesis of the classifications, distributions, benefits and issues of terracing. Earth-Science Reviews, 159: 388-403.

25.Yao L, Wei W, Chen LD*, 2016. How does imperviousness impact the urban rainfall-runoff process under various storm cases? Ecological Indicators, 60: 893–905.

26.Wang DC, Chen WG, Wei W*, Broxton W. B, Zhang LH, Sang MQ, and Wang QQ, 2016. Research on the Relationship between Urban Development Intensity and Eco-Environmental Stresses in Bohai Rim Coastal Area, China. Sustainability 2016, 8(4), 406; doi:10.3390/su8040406.

27.Wei W, Yu Y, Chen LD*, 2015. Response of surface soil hydrology to the micro-pattern of bio-crust in a dryland loess environment, China. Plos One, 1-17.

28.Wei W*, Chen LD, Zhang HD,Chen J, 2015. Effect of rainfall variation and landscape change on runoff and sediment yield from a loess hilly catchment in China. Environmental Earth Sciences, 73:1005-1016.

29.Yao L, Chen LD, Wei W*, 2015. Potential reduction in urban runoff by green spaces in Beijing: a scenario analysis. Urban Forestry & Urban Greening, 14: 300-308.

30.Yao L, Chen LD, Wei W*, 2015. Assessing the effectiveness of imperviousness on storm-water runoff in micro urban catchments by model simulation. Hydrological Processes, 30: 1836-1848.

31.Yu Y, Wei W*, Chen LD, Jia FY, Yang L, Zhang HD, and Feng TJ, 2015. Responses of vertical soil moisture to rainfall pulses and land uses in a typical loess hilly area, China. Solid Earth, 6: 595-608.

32.Yang L, Chen LD*, Wei W, 2015. Effects of vegetation restoration on the spatial distribution of soil moisture at the hillslope scale in semi-arid regions. Catena, 124: 138-146.

33.Wei W, Jia FY, Yang L, Chen LD*, Zhang HD, Yu Y, 2014. Effects of surficial condition and rainfall intensity on runoff in a loess hilly area, China. Journal of Hydrology, 513: 115-126.

34.Wei W*, Chen LD, Zhang HD, Yang L, Yu Yang, Chen J, 2014, Effects of crop rotation and rainfall on water erosion on a gentle slope in the hilly loess area, China. Catena, 123: 205-214.

35.Yang L, Chen LD, Wei W*, Yu Y, Zhang HD, 2014. Comparison of deep soil moisture in two re-vegetation watersheds in semi-arid regions. Journal of Hydrology, 513: 314-321.

36.Yang Lei, Wei W, Chen LD*, Chen WL, Wang JL, 2014. Response of temporal variation of soil moisture to vegetation restoration in semi-arid Loess Plateau, China. Catena 115: 123–133.

37.Wei W*, Chen LD, Yang L,Samadani F, Sun G, 2012. Microtopography recreation benefits ecosystem restoration. Environmental Science and Technology 46, 10875？10876.

38.Wei W, Chen LD*, Yang L, Fu BJ, Sun RH, 2012. Spatial scale effects of water erosion dynamics: Complexities, variabilities, and uncertainties. Chinese Geographical Science 22 (2): 127-143.

39.Yang L, Wei W*, Chen LD, Jia FY, Mo BR, 2012. Spatial variations of shallow and deep soil moisture in the semiarid Loess Plateau, China. Hydrology and Earth System Sciences 16: 3199-3217.

40.Yang L, Wei W*, Chen LD, Mo BR, 2012. Response of deep soil moisture to land use and afforestation in the semi-arid Loess Plateau,China. Journal of Hydrology 475:111-122.

41.Wei W, Chen LD*, Fu BJ, Chen J, 2010. Water erosion response to rainfall and land use in different drought-level years in a loess hilly area of China. Catena, 81: 24-31.

42.Wei W, Chen LD*, Fu B, Lu YH, Gong J, 2009. Responses of water erosion to rainfall extremes and vegetation types in a loess semiarid hilly area, NW China. Hydrological Processes, 23: 1780-1791.

43.Wei W, Chen LD*, Fu BJ, 2009. Effects of rainfall change on water erosion processes in terrestrial ecosystems: a review. Progress in Physical Geography, 33 (3): 307-318.

44.Wei W, Chen LD*, Fu BJ, Huang ZL, Wu DP, Gui LD, 2007. The effect of land uses and rainfall regimes on runoff and soil erosion in the semi-arid loess hilly area, China. Journal of Hydrology, 335: 247-258．

45.Chen LD, Wei W, Fu BJ*, L YH, 2007. Soil and water conservation on the Loess Plateau in China: Review and Prospective. Progress in Physical Geography,31 (4): 389-403．

46.Chen LD*, Yang Lei, Wei Wei, Wang ZT, Mo BR, Cai GJ, 2013. Towards Sustainable Integrated Watershed Ecosystem Management: A Case Study in Dingxi on the Loess Plateau, China. Environmental Management,51:126-137.

47.L YH, Fu BJ*, Wei W, Yu XB, Sun RH, 2011. Major ecosystems in China. Dynamics and challenges for sustainable development. Environmental Management 48:13-27.

48.Chen LD*, Wang JP, Wei W, Fu BJ, Wu DP, 2009. Effects of landscape restoration on soil water storage and water use in the Loess Plateau Region, China. Forest Ecology and Management 259(7): 1291-1298.

49.Li ZX,YuanRF,Feng Q,Zhang BJ,Lv YM,Li YG,Wei W,et al., 2019. Climate background, relative rate, and runoff effect of multiphase water transformation in Qilian Mountains, the third pole region. Science of The Total Environment 663:315-328.

50.Cao B, Yu L, Naipal V, Ciais P, Li W, Zhao Y, Wei W, Chen D, Liu Z, and Gong P, 2021. A 30m terrace mapping in China using Landsat 8 imagery and digital elevation model based on the Google Earth Engine. Earth Syst. Sci. Data, 13, 2437–2456.

51.Liu W, Feng Q, Chen WP, Wei W, Si JH, XiHY, 2019. Runoff retention assessment for extensive green roofs and prioritization of structural factors at runoff plot scale using the Taguchi method. Ecological Engineering 138:281-288.

52.Liu W, Wei W, Chen WP,Deo RC, Si JH,Xia HY, Li BF, Feng Q, 2019. The impact of substrate and vegetation on stormwater runoff quality from extensive green roofs. Journal of Hydrology 576: 575-582.

53.Liu W, Feng Q, Chen WP, Wei W, Deo RC, 2019. The influence of structural factors on stormwater runoff retention of extensive green roofs: new evidence from scale-based models and real experiments. Journal of Hydrology 569: 230-238.

54.L YH, Fu BJ*, Chen LD, Liu GH, Wei W, 2007. Nutrient transport associated with water erosion: progress and prospect. Progress in Physical Geography, 31(6): 607-620.

55.Gong J, Chen LD*, Fu BJ, Wei W, 2007．Integrated effects of slope aspect and land use on soil nutrients in a small catchment in hilly loess area, China．International Journal of Sustainable Development & World Ecology, 14: 1-10.

56.卫伟等著.环渤海沿海地区生态环境评估.北京:科学出版社,2017.01.

57.卫伟等著.黄土高原生态修复的水土效应.北京:科学出版社,2020.11.