教育背景:
[1] 2016.09—2020.12河海大学水文学及水资源博士研究生
[2] 2018.12—2020.01普渡大学水文学及水资源访问博士生
[3] 2017.12—2018.02普渡大学水文学及水资源访问博士生
[4] 2013.09—2016.06河海大学农业水土工程硕士
[5] 2009.09—2013.06三峡大学水文与水资源工程学士
工作经历:
[1] 2024.01—至今,宁夏大学,土木与水利工程学院,副教授
[2] 2021.03—2023.12宁夏大学,土木与水利工程学院,讲师
研究方向:
遥感解译;作物模型;智慧灌溉;农业水资源高效利用
科研成果:主持和参与多项国家自然科学基金、重点研发项目,发表学术论文30余篇,授权发明专利14项,入选宁夏青年科技托举人才培养项目(2024),获农业节水科技奖一等奖(2023)。
科研项目:
[1]基于无人机观测信息与SWAP模型同化的作物精准灌溉研究(2023AAC05013),自治区自然科学基金优秀青年基金, 2023.7-2026.6.主持
[2]低空遥感数据驱动的作物水分亏缺识别及灌溉决策(52209059),国家自然科学基金青年基金, 2023.1-2025.12.主持
[3]气候变化对宁夏主要粮食作物水分利用效率的影响及适应性调控(2022YCZX0007),自治区引才专项, 2023.1-2024.12,主持
[4]气候变化对西北地区谷子水分利用效率的影响及适应性调控,清华大学开放基金, 2022.1-2023.12.主持
[5]农田土壤水分蒸发与干缩开裂耦合模拟及模型体系构建(52269015),国家自然科学基金委员会,国家自然科学基金项目, 2023.1-2026.12.参与
[6]旱区农业高效节水智慧管理系统开发与集成示范重点研发项目(2021ZDYF1170), 2021.1 - 2023.12.参与
[7]气候变化-水资源-粮食生产协同作用机理与适应性调控(BK20180021),江苏省杰出青年基金项目, 2018.7 - 2021.6.参与
[8]量化辨识气候变化、品种更新和管理方式对水稻水分利用效率的协同影响及适应性调控(51779073),国家自然科学基金面上项目, 2018.1- 2021.12.参与
论文:
[1]Jia Z,Yimin D, Lei Z, Yukuai W, Mingtang C, Pengpeng D, et al. Estimating and Forecasting Daily Reference Crop Evapotranspiration in China with Temperature-Driven Deep Learning Models[J], Agricultural Water Management, 2025, 307
[2]Yimin D, Weiguang W, Qianlai Z, Yufeng L, et al. Adaptation of Paddy Rice in China to Climate Change: the Effects of Shifting Sowing Date on Yield and Irrigation Water Requirement[J], Agricultural Water Management, 2019, 228: 105890-105890.
[3]Yimin D, Weiguang W, Ruiming S, Quanxi S, Xiyun J, Wanqiu X, et al. Modeling Spatial and Temporal Variability of the Impact of Climate Change on Rice Irrigation Water Requirements in the Middle and Lower Reaches of the Yangtze River, China[J], Agricultural Water Management, 2017, 193: 89-101.
[4]Weiguang W,Yimin D, Quanxi S, Junzeng X, Xiyun J, Yufeng L, Zhongbo Y, et al. Bayesian Multi-Model Projection of Irrigation Requirement and Water Use Efficiency in Three Typical Rice Plantation Region of China Based on CMIP5[J], Agricultural and forest meteorology, 2016, 232: 89-105.
[5]Zhenyuan S, Zhi Y,Yimin D, Boyan S, Saiju L, Zhen G, Lei Z, et al. Adaptive Spatial-Channel Feature Fusion and Self-Calibrated Convolution for Early Maize Seedlings Counting in UAV Images[J], Frontiers in plant science, 2025, 15: 1496801.
[6]Yuanyuan X, Ruiyin C, Mingyu W,Yimin D. Response of Matching Degree Between Precipitation and Maize Water Requirement to Climate Change in China[J], AGRONOMY-BASEL, 2024, 14(1)
[7]Jianxin J,Yimin D, Boyan S, Saiju L, Zheng G, Lei Z, et al. Simulating the Exploration of the Optimal Irrigation of Spring Wheat in Drought Areas Based on SWAP Model[J], IRRIGATION AND DRAINAGE, 2024
[8]Qi Wei, Siying Li, Junzeng Xu, Zihan Yang, Zhenyang Liu, Peng Chen, Yuzhou Liu,Yimin Ding, Junyi Tan, and Jiuying Li. "Evaluation of Surface Water Quality in Heilongjiang Province, China: Based on Different Quantities of Water Quality Indicators", ECOLOGICAL INDICATORS 154 (2023)
[9]Rui N, Yukuai W,Yimin D, Mingtang C, Lei Z, et al. Effects of Root Systems on Crack Formation: Experiments, Modeling, and Analyses[J], Soil and Tillage Research, 2023, 233: 105784-105784.
[10]Weiguang W, Guoshuai L, Jia W, Zefeng C,Yimin D, Jiazhong Z, et al. The Climatic Effects of Irrigation over the Middle and Lower Reaches of the Yangtze River, China[J], Agricultural and forest meteorology, 2021, 308-309: 108550-108550.
[11]Jia W, Wei-guang W, Yin H,Yi-min D, Jian-yu F, Ze-feng C, Wan-qiu X, et al. Drought Variability and Its Connection with Large-Scale Atmospheric Circulations in Haihe River Basin[J], Water science and engineering, 2020, 14(1): 1-16.
[12]Jiazhong Z, Weiguang W, Guoshuai L,Yimin D, Xinchun C, Dan C, B. A E, et al. Towards Quantification of the National Water Footprint in Rice Production of China: A First Assessment from the Perspectives of Single-Double Rice[J], Science of the Total Environment, 2020, 739: 140032.
[13]Qi W, Junzeng X, Linxian L, Yanmei Y, Weixuan L, Jing Z,Yimin D, et al. Indicators for Evaluating Trends of Air Humidification in Arid Regions under Circumstance of Climate Change: Relative Humidity (RH) Vs. Actual Water Vapour Pressure (Ea)[J], Ecological indicators, 2020, 121: 107043-107043.
[14]Jiazhong Z, Weiguang W, Dan C, Xinchun C, Wanqiu X,Yimin D, Qing D, Ting Z, et al. Exploring the Water–energy–food Nexus from a Perspective of Agricultural Production Efficiency Using a Three-Stage Data Envelopment Analysis Modelling Evaluation Method: a Case Study of the Middle and Lower Reaches of the Yangtze River, China[J], Water Policy, 2018
[15]Jiazhong Z, Weiguang W, Xinchun C, Xiaozhou F, Wanqiu X,Yimin D, Qing D, Quanxi S, et al. Responses of Phosphorus Use Efficiency to Human Interference and Climate Change in the Middle and Lower Reaches of the Yangtze River: Historical Simulation and Future Projections[J], Journal of cleaner production, 2018, 201: 403-415.
[16]Wanqiu X, Weiguang W, Quanxi S,Yimin D, et al. Estimating Net Irrigation Requirements of Winter Wheat Across Central-Eastern China under Present and Future Climate Scenarios[J], Journal of Irrigation and Drainage Engineering-asce, 2018, 144(7)
[17]丁一民,王卫光,孙风朝.水稻产量和灌溉需水量的气候敏感性分析及贡献量评估[J].灌溉排水学报, 2016, 35 (04): 39-42.
[18]王卫光,丁一民,徐俊增,缴锡云,杨士红.多模式集合模拟未来气候变化对水稻需水量及水分利用效率的影响[J].水利学报, 2016, 47 (06): 715-723.
[19]朱磊,程瑞英,丁一民*,孙振源,郭政,江伟.基于低成本多视角立体视觉的辣椒苗三维重建与策略优化[J].中国农村水利水电, 1-14.
[20]孙风朝,赵翠平,张杰,丁一民*.基于SWAP模型分析青铜峡灌区春小麦播期优化及其对灌溉需水量的影响[J].中国农业气象, 2024, 45 (06): 594-608.
[21]朱磊,张伟业,潘自林,丁一民*,雷晓萍,张宗和,孙伯颜,柴明堂.基于Sentinel-2的青铜峡灌区春小麦和苜蓿早期识别[J].灌溉排水学报, 2024, 43 (05): 86-94.
[22]朱磊,江伟,孙伯颜,柴明堂,李赛驹,丁一民*.基于神经辐射场的苗期作物三维建模和表型参数获取[J].农业机械学报, 2024, 55 (04): 184-192+230.
[23]朱磊,王科,丁一民*,孙振源,孙伯颜.基于Sentinel-2的青铜峡灌区水稻和玉米种植分布早期识别[J].干旱区地理, 2024, 47 (05): 850-860.
[24]金建新,丁一民,孙振源,朱磊.基于SWAP-IES的旱区春小麦长势和产量模拟[J].农业工程学报, 2023, 39 (11): 66-76.
[25]高爽,丁一民*,朱磊,万愉快,柴明堂,丁朋朋,邹业斌.基于AquaCrop模型的玉米需水和降水匹配度变化特征研究[J].节水灌溉, 2023, (06): 51-59.
[26]陈君洁,丁一民*,高爽,万愉快,朱磊.夏玉米生育期内极端气候事件时空演变特征分析[J].节水灌溉, 2022, (10): 63-71.
[27]李赛驹,金建新,丁一民,孙伯颜,孙振源,朱磊.基于SWAP-IES作物同化模型的宁夏玉米产量模拟[J].节水灌溉, 2024, (12): 47-54.
[28]李南,郭子龙,柴明堂,朱磊,丁一民.基于SEBAL模型的宁夏蒸散发遥感估算[J].节水灌溉, 2024, (05): 115-124.
[29]朱磊,高欣悦,万愉快,丁一民.地震力对边坡可靠度的影响[J].科学技术与工程, 2023, 23 (10): 4324-4330.
[30]朱世峰,王卫光,丁一民,刘国帅,魏佳.基于CMIP6的长江中下游未来水稻高温热害时空变化特征[J].农业工程学报, 2023, 39 (03): 113-122.
[31]陈岗,王卫光,丁一民,童山琳.江苏省ET0和降水预报准确度分析[J].中国农村水利水电, 2022, (05): 70-76.
[32]王晓宇,王卫光,丁一民,刘国帅.生育期模型的不确定性对未来四川水稻灌溉需水量影响[J].中国农村水利水电, 2019, (07): 11-14+21.
[33]陈泽峰,王卫光,李长妮,丁一民,傅健宇.基于概率Budyko方程的流域未来可用水资源比例预估[J].中国农村水利水电, 2019, (06): 10-15+22.
[34]鲍金丽,王卫光,丁一民.控制灌溉条件下水稻灌溉需水量对气候变化的响应[J].中国农村水利水电, 2016, (08): 105-108.
专利:
[1]丁一民,朱磊,张伟业.一种基于拍照的叶片面积测量方法[P].宁夏回族自治区: CN116592796A, 2023-08-15.
[2]柴明堂,李南,罗园,万愉快,丁一民.一种测量水气交界面处温度的装置[P].宁夏回族自治区: CN217687543U, 2022-10-28.
[3]邢万秋,王卫光,董青,丁一民,郑佳重,傅健宇.一种月尺度蒸散发量的定量估算方法[P].江苏省: CN109035105B, 2021-02-02.
[4]王卫光,鲍金丽,丁一民,郑佳重,邢万秋,傅健宇,董青.一种未来气候条件下作物灌溉需水量计算方法[P].江苏省: CN106570627B, 2020-09-29.
[5]王卫光,郑佳重,丁一民,邢万秋,傅健宇,董青.一种“风光互补”的山丘区节水灌溉综合调控系统[P].江苏省: CN106613761B, 2020-08-25.
[6]邢万秋,王卫光,姚冠泽,丁一民,董青,郑佳重.一种确定蒸散发变化主因及判别因素间耦合作用的方法[P].江苏省: CN107818238B, 2019-12-06.
[7]王卫光,丁一民,鲍金丽,邢万秋,董青,傅健宇.一种考虑逐日数据波动特征的GCM校正方法[P].江苏省: CN108009398B, 2019-08-06.
[8]王卫光,郑佳重,丁一民,邢万秋,董青,傅健宇.一种多模式集合多用途的水文缆道测流装置及方法[P].江苏省: CN106483089B, 2019-07-30.
[9]王卫光,邹珊,邢万秋,丁一民,董青,郑佳重.一种多弹性对径流变化驱动因素的定量分割方法[P].江苏省: CN107084709B, 2019-07-30.
[10]王卫光,丁一民,邢万秋,傅健宇,董青,徐俊增.一种农业智能远程管理系统[P].江苏省: CN106054844B, 2019-04-30.
[11]王卫光,王晓宇,丁一民,郑佳重,邢万秋,傅健宇,董青.一种基于耦合作物模型同化光谱反射率的水稻估产方法[P].江苏: CN107941713A, 2018-04-20.
[12]王卫光,郑佳重,丁一民.一种双模式山洪预警控制系统及方法[P].江苏: CN106971510A, 2017-07-21.
[13]王卫光,丁一民,郑佳重,邢万秋,董青,傅健宇.一种基于累积概率曲线的逐日降水多模式集合方法[P].江苏: CN106909798A, 2017-06-30.
[14]王卫光,郑佳重,丁一民,邢万秋,傅健宇,董青.一种采煤沉陷区蓄洪滞洪效果的定量方法[P].江苏: CN106547974A, 2017-03-29.
