●基本信息
邳华伟,男,博士,杰出人才特区计划第四层次教授,博士生导师。
Email:huawei.pi@wsu.edu/pihuawei11@mails.ucas.ac.cn
●教育背景
2014/09 - 2017/07,中国科学院大学,自然地理学,博士
2011/09 - 2014/07,中国科学院大学,自然地理学,硕士
2006/09 - 2011/07,济南大学,资源环境与城乡规划管理,学士
●工作经历
2017/08 - 2020/12,美国华盛顿州立大学,作物与土壤科学系,博士后
(美国农业部西北农业生态系统可持续发展研究所兼职研究员)
2021/01-至今,河南大学,黄河文明与可持续发展研究中心
●研究方向
土壤风蚀与土地退化、大气环境、大气边界层物理学
●代表性成果
1.研究项目
(1)美国农业部农业生态系统可持续发展综合研究(Amillion per year),Long-Term Agroecosystem Research (LTAR) for Dryland Cropping Systems of the Northwest,2015.09-2020.08,参与。
(2)美国国家风蚀研究网络,(National Wind Erosion Research Network), 2016-2020,参与。
2.研究论文
(1)Zhang, Xiuli, Huawei Pi*, Larry E. Wagner, Fred Fox, and Sisi Li. 2024. Evaluating the ability of the Wind Erosion Prediction System (WEPS) to simulate near-surface wind speeds in the Inland Pacific Northwest, USA." Scientific Reports 14, no. 1: 23712.
(2)Li, Jiahui, Sisi Li, and Huawei Pi*. 2024. Interaction effects of various impact factors on the snow over the Yangtze and Yellow River headwater region, China." Ecological Indicators 166: 112330.
(3)Pi, Huawei, Xiuli Zhang, Sisi Li*, and Nicholas P. Webb. "Influence of crop rotation, irrigation, fertilization, and tillage on the aggregate property and soil wind erosion potential in the floodplain of the Yellow River." Aeolian Research 67 (2024): 100925.
(4)Pi, Huawei, Brandon L. Edwards, and Bailiang Li. 2023. Understanding soil wind erosion and control practices in arid and semiarid environments." Frontiers in Environmental Science 11: 1119742.
(5)Li, Sisi, and Huawei Pi*. Deconstruction of dryness and wetness patterns with drought condition assessment over the Mun River Basin, Thailand. 2022. Land 11.12: 2244.
(6)Pi, Huawei, Nicholas P. Webb, David R. Huggins, and Sisi Li*. "Effects of secondary soil aggregates on threshold friction velocity and wind erosion. 2023. Land Degradation & Development 34, no. 1: 16-27.
(7)Pi, H., Webb, N. P., Huggins, D. R., Sharratt, B., & Li, S. 2022a. Performance of the SWEEP model in assessing the impact of crop rotation, green manure, fertilizer, and tillage on wind erosion. Land Degradation & Development. (accepted) (Web of Science-JCR1区(WOS-JCR),中科院1区TOP, 影响因子4.977).
(8)Pi, H., Webb, N. P., Lei, J., & Li, S. 2022b. Soil loss and PM10 emissions from agricultural fields in the Junggar Basin over the past six decades. Journal of Soil and Water Conservation, 77(2), 113-125 (WOS- JCR2区,中科院2区,影响因子3.18).
(9)Li, S., Liu, M., Adam, J. C.†, Pi, H.†, Su, F., Li, D., ... & Yao, Z. 2021. Contribution of Snow-Melt Water to the Streamflow over the Three-River Headwater Region, China. Remote Sensing, 13(8), 1585.
(10)Pi, H.*, Huggins, D., Sharratt, B., 2021a. Soil wind erosion influenced by clay amendment in the inland Pacific Northwest, USA. Land degradation and development, 32.1: 241-255. (Web of Science-JCR1区(WOS-JCR),中科院1区TOP, 影响因子4.275).
(11)Pi, H.*, Webb N. P., Lei J., Huggins, D., Sharratt, B. S., 2021b. Influence of physical crust cover on the wind erodibility of soils in the inland Pacific Northwest, USA. Earth Surface Processes and Landforms, 46(8), 1445-1457. (WOS- JCR1区,中科院2区,影响因子3.598).
(12)Pi, H.*, Huggins, D., Sharratt, B., 2020a. Influence of clay amendment on soil physical properties and threshold friction velocity within a disturbed crust cover in the inland Pacific Northwest. Soil and Tillage Research, 202: 104659. (WOS-JCR1区,中科院1区TOP, 影响因子4.675).
(13) Pi, H.*, Nicholas P. Webb, David R. Huggins, and Brenton Sharratt. 2020b. Critical standing crop residue amounts for wind erosion control in the inland Pacific Northwest, USA. Catena 195: 104742. (WOS- JCR1,中科院1区TOP, 影响因子3.851).
(14)Pi, H.*, Huggins, D., Sharratt, B., 2020c. Threshold friction velocities influenced by standing crop residue in the inland Pacific Northwest, USA. Land degradation and development, 31(16), 2356-2368. (WOS-JCR1区,中科院1区TOP, 影响因子4.275).
(15)Pi H, Huggins D R.*, Abatzoglou J T, et al. 2020d. Modeling soil wind erosion from agro-ecological classes of the Pacific Northwest in response to current climate. Journal of Geophysical Research: Atmospheres, 125(2), e2019JD031104. (WOS-JCR1区,中科院2区TOP,影响因子3.633).
(16)Pi H.*, Huggins D R, Webb N P, et al. 2020e. Comparison of soil-aggregate crushing-energy meters. Aeolian Research, 42: 100559 (WOS-JCR2区,中科院3区,影响因子2.864).
(17)Pi, H.*, Huggins, D., Sharratt, B., 2019a. Dry aggregate stability influenced by soil type, crop rotation, soil amendment, and tillage in the Columbia Plateau. Aeolian Research 40, 65-73. https://doi.org/10.1016/j.aeolia.2019.07.001 (WOS-JCR2区,中科院3区,影响因子2.864).
(18)Pi H., Sharratt B*, Lei J. 2019b.Wind erosion and dust emissions in central Asia: Spatiotemporal simulations in a typical dust year. Earth Surface Processes and Landforms, 44(2): 521-534. (WOS- JCR1区,中科院2区,影响因子3.598).
(19)Pi, H.*, & Sharratt, B. 2019. Threshold Friction Velocity Influenced by the Crust Cover of Soils in the Columbia Plateau. Soil Science Society of America Journal, 83(1), 232-241. doi:10.2136/sssaj2018.06.0230. (WOS-JCR2区,中科院2区TOP,影响因子1.997).
(20)Pi, H., Sharratt, B.*, Schillinger, W. F., Bary, A. I., & Cogger, C. G. 2018a. Wind erosion potential of a winter wheat–summer fallow rotation after land application of biosolids. Aeolian Research, 32, 53-59(WOS-JCR2区,中科院3区,影响因子2.864).
(21)Pi, H., Sharratt, B.*, Schillinger, W. F., Bary, A. I., & Cogger, C. G. 2018b. Chemical composition of windblown dust emitted from agricultural soils amended with biosolids. Aeolian Research, 32: 102-115 (WOS-JCR2区,中科院3区,影响因子2.864).
(22)Sharratt B*, Pi H. 2018. Field and laboratory comparison of PM10 instruments in high winds. Aeolian Research, 32: 42-52 (WOS-JCR2区,中科院3区,影响因子2.864).
(23)Pi H, Sharratt B, Lei J*. 2017a. Windblown sediment transport and loss in a desert–oasis ecotone in the Tarim Basin. Scientific Reports, 2017,7:7723 (WOS-JCR1区,中科院3区,影响因子4.011).
(24)Pi H, Sharratt B*. 2017. Evaluation of the RWEQ and SWEEP in simulating soil and PM10 loss from a portable wind tunnel. Soil and Tillage Research, 170: 94-103 (WOS-JCR1区,中科院1区TOP, 影响因子4.675).
(25)Pi, H., Sharratt B.*, and Lei J., 2017b. Atmospheric dust events in central Asia: Relationship to wind, soil type, and land use, J. Geophys. Res. Atmos.,122, doi:10. 1002/2016JD026 314. 2017 (WOS-JCR1区,中科院2区TOP,影响因子3.633).
(26)Pi H, Sharratt B.*, Feng G, et al. 2017c. Evaluation of two empirical wind erosion models in arid and semi-arid regions of China and the USA. Environmental Modelling & Software, 91: 28-46 (WOS-JCR1区,中科院1区TOP,影响因子4.552).
(27)Pi, H., Sharratt, B.*, Feng, G., Lei, J., Li, X., & Zheng, Z., 2016. Validation of SWEEP for creep, saltation, and suspension in a desert–oasis ecotone. Aeolian Research 2016, 20, 157-168 (WOS-JCR2区,中科院3区,影响因子2.864).
(28)Pi, H., Feng, G., Sharratt, B.*, Li, X., Zheng, Z., 2014a. Validation of SWEEP for contrasting agricultural land use types in the Tarim Basin. Soil Science 179, 433-445 (WOS-JCR3区,中科院3区,影响因子1.042).
(29)Pi, H., Sharratt, B.*, Feng, G., 2014b. Comparison of measured and simulated friction velocity and threshold friction velocity using SWEEP. Soil Science 179, 393-402 (WOS-JCR3区,中科院3区,影响因子1.042).
(30)Pi, H., Feng G., Sharratt, B.*, 2014c. Performance of the SWEEP model affected by estimates of threshold friction velocity. 57, 1675-1685 (WOS-JCR3区,中科院3区,影响因子1.153).
3. 出版著作
●代表性奖励或荣誉称号
(1)Frontiers in Environmental Science (IF:4.581, Q2, 中科院3区) 副主编(Guest Associate Editor)