1.学术论文 l 2025年度 [1] Ma Z, He J, Zhang J, Li W, Yin F, Wen Y, Liang Y, Ye H, Liu J* and Wang Z*. 2025. Combination with moderate irrigation water temperature and nitrogen application rate enhances nitrogen utilization and seed cotton yield. European Journal of Agronomy, 162: 127417. (SCI一区, IF=4.5 通讯作者) [2] Zhou Z, Jin J*, Li F and Liu J. 2025. Estimating the temperature sensitivity of rice (Oryza sativa L.) yield and its components in China using the CERES-Rice model. European Journal of Agronomy, 162: 127419. (SCI一区, IF=5.2) [3] Yao N, Wei Y, Jiang K, Liu J, Li Y*, Ran H, Javed T, Feng H, Yu Q and He J*. 2025. Nonlinear water stress response functions can improve the performance of the DSSAT-CERES-Wheat model under water deficit conditions. Agricultural Water Management, 307: 109235. (SCI一区, IF=5.9) [4] Ma J, Wen Y, Ma Z, Liu J, Wei C, Zhang J and Wang Z*. 2025. Effect of fertilizer–air-coupled drip irrigation on soil microbial carbon and nitrogen cycling functions. Soil Science Society of America Journal, 89(1): e70001. (SCI三区, IF=2.4) [5] Liang Y, Wu M, Zhang J, Ma Z, Han Y, Wen Y, Chen R, Liu J, Li H and Wang Z*. 2025. Synergy between aerated drip and biodegradable film enhances sustainable maize production in arid oasis. European Journal of Agronomy, 165: 127535. (SCI一区, IF=4.5) [6] Zhang X, Wang Z, Liu J, Li W, Lin H, Javed T, Gao X, Qin G, Liu H, Wang H, Liu Y and Ye H*. 2025. Spatial–Temporal Dynamics and Drivers of Crop Water Footprint in Xinjiang, China. Agronomy, 15(2): 296. (SCI二区, IF=3.3) l 2024年度 [1] Ma Z, Zhu Y, Liu J, Li Y, Zhang J, Wen Y, Song L, Liang Y and Wang Z*. 2024. Multi-objective optimization of saline water irrigation in arid oasis regions: Integrating water-saving, salinity control, yield enhancement, and CO2 emission reduction for sustainable cotton production. Science of the Total Environment, 912: 169672. (SCI一区, IF=9.8) [2] Javed T, Wang Z*, Liu J, Li W, Lin H and Zhang J. 2024. Unlocking the ecohydrological dynamics of vegetation growth's impact on Terrestrial Water Storage trends across the China-Pakistan Economic Corridor. Science of the Total Environment, 955: 176977. (SCI一区, IF=9.8) [3] Ma Z, Liu J, Wen Y, Zhang J, Yin F, Guo L, Li W, He J, Ma J, Liang Y and Wang Z*. 2024. Optimizing cotton yield through appropriate irrigation water salinity: Coordinating above- and below-ground growth and enhancing photosynthetic capacity. European Journal of Agronomy, 154: 127095. (SCI一区, IF=5.2) [4] Gao X, Liu J, Lin H, Wen Y, Chen R, Javed T, Mu X and Wang Z*. 2024. Temperature increase may not necessarily penalize future yields of three major crops in Xinjiang, Northwest China. Agricultural Water Management, 304: 109085. (SCI一区, IF=5.9) [5] Ma Z, Liu J, Zhang J, Yin F, Guo L, Wen Y, Song L, Zhu Y, Liang Y and Wang Z*. 2024. Ultra-wide film mulching with moderate irrigation water salinity enhances cotton growth under drip irrigation in Xinjiang, China. Field Crops Research, 315: 109485. (SCI一区, IF=5.6) [6] Zhou Z, Liu J, Zhang J, Li W, Wen Y, Chen R, Chen P, Li H, Gao X, Zhu Y and Wang Z*. 2024. Combining magnetized water with biodegradable film mulching reshapes soil water-salt distribution and affects processing tomatoes' yield in the arid drip-irrigated field of Northwest China. Agricultural Water Management, 303: 109021. (SCI一区, IF=5.9) [7] Qin G, Liu J, Lin H, Javed T, Gao X, Tang Y, Mu X, Guo M and Wang Z*. 2024. Assessing the Coordination and Spatial Equilibrium of Water, Energy, and Food Systems for Regional Socio-Economic Growth in the Ili River Valley, China. Agronomy, 14(9): 2037. (SCI二区, IF=3.3) [8] Ma Z, Liu J, Wen Y, Li W, Zhu Y, Song L, Li Y, Liang Y and Wang Z*. 2024. Effects of Different Film Types on Cotton Growth and Yield under Drip Irrigation. Sustainability, 16(10): 4173. (SCI三区, IF=3.3) [9] Han Y, Zhang J, Chen P, Li H, Li W, Liu J, Zong R, Wang D, Liang Y and Wang Z*. 2024. Biochar improves water and nitrogen use efficiency of cotton under mulched drip irrigation in arid regions. Industrial Crops and Products, 222: 119830. (SCI一区, IF=5.6) [10] 何静, 王振华*, 刘健, 马占利, 温越. 2024. 灌溉水温与施氮量对滴灌棉田土壤水热及棉花生长和产量的影响. 中国农业科学, 57(02): 319-335. [11] 赵露, 叶含春*, 王振华, 刘健, 吝海霞, 邹杰, 谭明东. 2024. 基于SHAW模型的北疆地区不同滴灌年限棉田冻融期土壤水热盐动态模拟研究. 土壤, 56(03): 623-638. [12] 张疏影, 张金珠*, 王振华, 温越, 刘健, 朱艳, 唐宇鹏. 2024. 不同水氮配施对北疆膜下滴灌棉花生长发育的影响. 排灌机械工程学报, 42(06): 641-648. [13] 谢忠, 叶含春*, 王振华, 李海强, 刘健, 陈睿, 许宇双. 2024. 浅埋滴灌水氮配施对冬小麦生长发育、产量及水分利用效率的影响. 新疆农业科学, 61(05): 1057-1066. [14] 吴梅, 张金珠*, 王振华, 刘健, 温越, 李宣志. 2024. 水气互作对膜下滴灌玉米生理生长及产量的影响. 中国农业科技导报, 26(08): 189-200. [15] 唐宇鹏, 雷雨*, 王振华, 宋利兵, 刘健, 郝天鹏, 张维克. 2024. 基于农业灌溉模式优化的白杨河流域用水结构预测分析. 水电能源科学, 42(03): 49-53. [16] 张维克, 吕德生*, 王振华, 宋利兵, 刘健, 郝天鹏, 唐宇鹏. 2024. 新疆白杨河流域河道内外生态需水的研究. 石河子大学学报(自然科学版), 42(02): 192-197. [17] 张泽华, 叶含春, 王振华, 李文昊, 李海强, 刘健. 2024. 等氮配施脲酶抑制剂对滴灌棉花生长发育和产量及品质的影响. 新疆农业科学, 61(09): 2103-2111. l 2023年度 [1] Wen Y, Wu X, Liu J*, Zhang J, Song L, Zhu Y, Li W and Wang Z*. 2023. Effects of drip irrigation timing and water temperature on soil conditions, cotton phenological period, and fiber quality under plastic film mulching. Agricultural Water Management, 287: 108435. (SCI一区, IF=6.7 通讯作者) [2] Zhou Z, Jin J*, Liu J and Si Y. 2023. Covering rice demand in Southern China under decreasing cropping intensities and considering multiple climate and population scenarios. Sustainable Production and Consumption, 40: 13-29. (SCI一区, IF=12.1) [3] Wen Y, Liu J, Zhang J, Li W, Ayantobo O O and Wang Z*. 2023. Effects of macro-plastics on soil hydrothermal environment, cotton yield, and fiber quality under mulched drip irrigation in the arid region of Northwest China. Field Crops Research, 302: 109060. (SCI一区, IF=5.8) [4] Zhou Z, Jin J*, Liu J and Si Y. 2023. Optimizing the sowing window for direct-seeded rice (Oryza sativa L.) considering high yield and methane emissions in Central China. Agricultural Systems, 205: 103594. (SCI一区, IF=6.6) [5] Wu X, Wang Z*, Guo L, Liu J, Dhital Y P, Zhu Y, Song L and Wen Y. 2023. Timing and water temperature of drip irrigation regulate cotton growth and yield under film mulching in arid areas of Xinjiang. Journal of the Science of Food and Agriculture, 103(12): 5754-5769. (SCI二区, IF=4.1) [6] 王振华*, 王菲, 吕德生, 刘健, 朱艳, 温越. 2023. 不同土质下灌水盐度对滴灌棉花生理及产量品质的影响. 农业工程学报, 39(24): 69-78. [7] 李宣志, 张金珠*, 王振华, 刘健, 梁洪榜. 2023. 氮盐调控对膜下滴灌加工番茄光合特性及产量的影响. 华中农业大学学报, 42(05): 186-194. [8] 李宣志, 张金珠*, 王振华, 刘健, 谭明东. 2023. 水-肥-盐耦合对滴灌加工番茄生长和产量的影响. 干旱地区农业研究, 41(04): 133-140. [9] 马怡璠, 吕德生*, 王振华, 李燕强, 刘健, 温越, 朱艳. 2023. 磁氮耦合对膜下滴灌加工番茄产量及水肥利用效率的影响. 干旱区研究, 40(11): 1855-1864. [10] 马占利, 王振华*, 刘健, 宋利兵, 温越, 谭明东, 梁永辉, 何静. 2023. 膜下滴灌配置模式对北疆地区棉花生长与产量的影响. 灌溉排水学报, 42(05): 9-15. [11] 李燕强, 王振华, 叶含春*, 宋利兵, 刘健, 温越, 武小荻. 2023. 灌溉水矿化度对棉田土壤呼吸速率的影响. 干旱区研究, 40(03): 392-402. [12] 王菲, 吕德生*, 王振华, 张金珠, 刘健, 温越, 秦程, 胡贵荣. 2023. 水盐耦合对滴灌棉花出苗率及苗期生长的影响. 节水灌溉(03): 91-97+105. l 2022年度前 [1] Wen Y, Liu J, Dhital Y, Wu X, Song L, Zhu Y, Chen P, Li W and Wang Z*. 2022. Integrated effects of plastic film residues on cotton growth and field carbon sequestration under drip irrigation in arid oasis regions. Agriculture, Ecosystems & Environment, 339: 108131. (SCI一区, IF=6.6) [2] Jian Liu, Jiming Jin*, and Guo-Yue Niu. 2021. Effects of Irrigation on Seasonal and Annual Temperature and Precipitation over China Simulated by the WRF Model. Journal of Geophysical Research: Atmospheres, 126: e2020JD034222. (SCI二区, IF=4.4 第一作者) [3] Tengcong Jiang #, Jian Liu#, Yujing Gao#, Zhe Sun, Shang Chen, Ning Yao, Haijiao Ma, Hao Feng, Qiang Yu, and Jianqiang He*. 2020. Simulation of plant height of winter wheat under soil Water stress using modified growth functions. Agricultural Water Management, 232: 106066. (SCI一区, IF=6.7, #contribute equally) [4] Tengcong Jiang #, Zihe Dou#, Jian Liu#, Yujing Gao, Robert W. Malone, Shang Chen, Hao Feng, Qiang Yu, Guining Xue, and Jianqiang He*. 2020. Simulating the Influences of Soil Water Stress on Leaf Expansion and Senescence of Winter Wheat. Agricultural and Forest Meteorology, 291: 108061. (SCI一区, IF=6.2, #contribute equally) [5] 刘健, 姚宁, 吝海霞, 周元刚, 吴淑芳, 冯浩, 张体彬, 白江平和何建强*. 2016. 冬小麦物候期对土壤水分胁迫的响应机制与模拟. 农业工程学报, 32(21): 115-124. [6] Ma, Xiaogang, Jiming Jin*, Jian Liu, and Guo-Yue Niu. 2019. An improved vegetation emissivity scheme for land surface modeling and its impact on snow cover simulations. Climate Dynamics, 53: 6215-26. (SCI二区, IF=4.6) [7] Yao, Ning, Yi Li, Fang Xu, Jian Liu, Shang Chen, Haijiao Ma, Henry Wai Chau, De Li Liu, Meng Li, Hao Feng, Qiang Yu, and Jianqiang He*. 2020. Permanent wilting point plays an important role in simulating winter wheat growth under water deficit conditions. Agricultural Water Management, 229. (SCI一区, IF=6.7) [8] Lin, H., Li, N., Li, Y*., Liu, H., Liu, J., Li, L., et al. 2021. Quantitative Analysis of Winter Wheat Growth and Yields Responding to Climate Change in Xinjiang, China. Water, 13(24), 3624. (SCI三区, IF=3.4) [9] Ma, Xiaogang, Jiming Jin*, Lingjing Zhu, and Jian Liu. 2021. Evaluating and improving simulations of diurnal variation in land surface temperature with the Community Land Model for the Tibetan Plateau. PeerJ, 9: e11040. (SCI三区, IF=2.7) [10] 杨涛, 刘健, 金继明*. 2020. 塔里木盆地灌溉对局地干旱气候影响的数值模拟研究. 节水灌溉(05): 83-87+92. [11] 王灵猛, 周泽羽, 刘健, 金继明*.2021. 气候变化下新疆棉花调亏灌溉的节水效果评估. 节水灌溉(06), 17-23+30. [12] 周元刚, 李华龙, 蒋腾聪, 窦子荷, 刘健, 吴淑芳, 冯浩, 张体彬, 何建强*. 2016. 夏玉米叶片形状系数的时间和空间变异. 中国农业科学, 49(23): 4520-4530. [13] 姚宁, 周元刚, 宋利兵, 刘健, 李毅, 吴淑芳, 冯浩, 何建强*. 2015. 不同水分胁迫条件下DSSAT-CERES-Wheat模型的调参与验证. 农业工程学报, 31(12): 138-150. [14] 姚宁, 宋利兵, 刘健, 冯浩, 吴淑芳, 何建强*. 2015. 不同生长阶段水分胁迫对旱区冬小麦生长发育和产量的影响. 中国农业科学, 48(12): 2379-2389. 2.获奖情况 |