学术论文 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, IF=9.8) [2] 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, IF=5.2) [3] 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, IF=3.9) [4]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. [5]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. [6]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. 亚洲bet356体育学报(自然科学版), 42(02): 192-197. 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, IF=6.7) [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, 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, 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, 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. J Sci Food Agric. (SCI, 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 and 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. 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, 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, IF=4.4) [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, 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, 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, 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, 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, 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, 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. 获奖情况 |