水利与土木工程学院

多孔介质流动和溶质迁移理论

农业水文与水资源高效利用

农田水土环境及其调控机理

[1]2022–2025 国家自然科学基金面上项目“水盐胁迫对农田土壤微生物和碳氮循环关键过程影响机制研究”（项目号：52179050）

[2]2019基本科研业务费专项资金项目“盐渍化农田土壤温室气体排放机理研究”（项目号：2019TC039）

[3]2019–2022国家自然科学基金面上项目“强蒸发条件下农田土壤–水–盐相互作用机理研究”（项目号：51879264）

[4]2017–2020国家重点研发计划项目子课题“节水减排控盐技术集成与效果评价”（项目号：2017YFC0403305-2）

[5]2014–2016基本科研业务费专项资金项目（教师科研启动基金）“长期封育草地生态–水文过程研究”（项目号：2014XJ024）

[6]2013–2015国家自然科学基金青年科学基金项目“黄土高原半干旱区草地土壤水分动态变化过程及其植被承载力”（项目号：41201037）

[1]2022–2025 “科技兴蒙”行动重点专项巴彦淖尔国家农业高新技术产业示范区重点项目“智慧农业灌溉关键技术集成应用与农业面源污染研究示范”

[2]2021–2025国家重点研发计划课题“黄河上游河套平原作物根区水盐响应机理及品种筛选与节水抑盐调控技术”（项目号：2021YFD1900603）

[3]2018–2022国家自然科学基金重大项目课题“土壤水盐动力学过程与量化表征”（项目号：51790535）

[4]2017–2021国家自然科学基金重点项目“灌区节水的生态环境效应及高效用水调控”（项目号：51639009）

[5]2016–2020国家重点研发计划项目子课题“灌排调控农田次生盐碱地生态治理技术”（项目号：2016YFC0501304）

[1] 2019 水利部国际经济技术合作交流中心项目 “以色列节水政策与制度资料汇编和研究分析”

[1]Chen Z., Y. Li, M. Hu, Y. Xiong*, Q. Huang, S. Jin, G. Huang*. 2023. Lignite bioorganic fertilizer enhanced microbial co-occurrence network stability and plant–microbe interactions in saline-sodic soil, Sci. Total Environ., 879, 163113.

[2]Li, Y., X. Xu, M. Hu, Z. Chen, J. Tan, L. Liu, Y. Xiong, Q. Huang, G. Huang*. 2023. Modeling water-salt-nitrogen dynamics and crop growth of saline maize farmland in Northwest China: Searching for appropriate irrigation and N fertilization strategies. Agr. Water Manage., 282, 108271.

[3]Wu Z., Y. Li., R. Wang, X. Xu, D. Ren, Q. Huang, Y. Xiong, G. Huang*. 2023. Evaluation of irrigation water saving and salinity control practices of maize and sunflower in the upper Yellow River basin with an agro-hydrological model based method. Agr. Water Manage., 278: 108157. DOI: 10.1016/j.agwat.2023.108157

[4]Li Y., X. Xu, Z. Chen, Y. Xiong, Q. Huang, G. Huang*. 2023. A process simulation-based framework for resource, food, and ecology trade-off by optimizing irrigation and N management. J. Hydrol., 617: 129035. DOI: 10.1016/j.jhydrol.2022.129035

[5]Liu S., Q. Huang, W. Zhang, D. Ren, X. Xu, Y. Xiong, G. Huang*. 2023. An improved estimation of soil water and salt dynamics by considering soil bulk density changes under freeze/thaw conditions in arid areas with shallow groundwater tables. Sci. Total Environ., 859: 160342. DOI: 10.1016/j.scitotenv.2022.160342

[6]Chen Z., Y. Li, X. Zhang, Y. Xiong, Q. Huang, S Jin, G. Huang*. 2022. Effects of lignite bioorganic product on sunflower growth, water and nitrogen productivity in saline-sodic farmlands at Northwest China. Agr. Water Manage., 271: 107806. DOI: 10.1016/j.agwat.2022.107806.

[7]Dong L., W. Zhang, Y. Xiong*, J. Zou, Q. Huang, X. Xu, P. Ren, G. Huang. 2022. Impact of short-term organic amendments incorporation on soil structure and hydrology in semiarid agricultural lands. Int. Soil Water Conserv. Res., 10 (3): 457-469, DOI: 10.1016/j.iswcr.2021.10.003.

[8]Zhang W., Y. Xiong*, Y. Li, Y. Qiu, G. Huang. 2022. Effects of organic amendment incorporation on maize (Zea mays L.) growth, yield and water-fertilizer productivity under arid conditions, Agr. Water Manage., 269, 107663.

[9]Chen Z., Y. Li, X. Zhang, Y. Xiong, Q. Huang, S. Jin, G. Huang. 2022. Effects of the lignite bioorganic fertilizer on greenhouse gas emissions and pathways of nitrogen and carbon cycling in saline-sodic farmlands at Northwest China. J. Clean. Prod., 334. DOI: 10.1016/j.jclepro.2021.130080.

[10]Xiong Y.*, L. Dong, X. Long, M. Chen, G. Huang. 2022. Pore-network model to quantify pore structure and hydraulic characteristics of randomly packed grains with different morphologies. Granul. Matter, 24:10. DOI:10.1007/s10035-021-01174-7.

[11]Li Y., G. Huang*, Z. Chen, Y. Xiong, Q. Huang, X. Xu, Z. Huo. 2022. Effects of irrigation and fertilization on grain yield, water and nitrogen dynamics and their use efficiency of spring wheat farmland in an arid agricultural watershed of Northwest China. Agr. Water Manage., 260, 107277. DOI: 10.1016/j.agwat.2021.107277.

[12]Xiong L., X. Xu, B. Engel, Q. Huang, Z. Huo, Y. Xiong, W. Han, G. Huang*. 2021. Modeling agro-hydrological processes and analyzing water use in Hetao of arid upper Yellow River basin, Northwest China. J. Hydrol., 603, 127014. DOI: 10.1016/j.jhydrol.2021.127014.

[13]Dong L., Y. Xiong*, Q. Huang, X. Xu, Z. Huo, G. Huang. 2021. Evaporation-induced salt crystallization and feedback on hydrological functions in porous media with different grain morphologies. J. Hydrol., 598, 126427. DOI: 10.1016/j.jhydrol.2021.126427.

[14]Li C., Y. Xiong*, J. Zou, L. Dong, P. Ren, G. Huang. 2021. Impact of biochar and lignite-based amendment on microbial communities and greenhouse gas emissions from agricultural soil. Vadose Zone J., e20105. DOI: 10.1002/vzj2.20105.

[15]Liu, K., G. Huang, J. Simunek, X. Xu, Y. Xiong, Q. Huang. 2021. Comparison of ensemble data assimilation methods for the estimation of time-varying soil hydraulic parameters. J. Hydrol., 594, 125729. DOI: 10.1016/j.jhydrol.2020.125729.

[16]Xu X., H. Li, C. Sun, T. B. Ramos, H. Darouich, Y. Xiong, Z. Qu, G. Huang*. 2021. Pedotransfer functions for estimating soil water retention properties of northern China agricultural soils: development and needs. Irrig. and Drain., 1-16. DOI: 10.1002/ird.2584.

[17]Liu S., Q. Huang*, D. Ren, X. Xu, Y. Xiong, G. Huang*. 2021. Soil evaporation and its impact on salt accumulation in different landscapes under freeze/thaw condition in the upper reaches of the Yellow River basin. Vadose Zone J., e20098. DOI: 10.1002/vzj2.20098.

[18]Xiong L., X. Xu*. C. Sun, B. Engel, Y. Xiong, Q. Huang, G. Huang. 2021. Predicting agro-ecohydrological responses to identify appropriate water-saving management in arid irrigated regions with shallow groundwater: Realization on a regional scale. Agr. Water Manage., 247, 106713. DOI: 10.1016/j.agwat.2020.106713.

[19]Liu K., J. Simunek, X. Xu, Y. Xiong, Q. Huang, G. Huang*. 2021. Comparison of ensemble data assimilation methods for the estimation of time-varying soil hydraulic parameters. J. Hydrol., 125729. DOI: 10.1016/j.jhydrol.2020.125729.

[20]Du J., Z. Huo*, X. Wang, H. Guan, Y. Xiong, G. 2021. Huang. Response of shelterbelt transpiration to shallow groundwater in arid areas. J. Hydrol., 592, 125611. DOI: 10.1016/j.jhydrol.2020.125611.

[21]Ren D., X. Xu, B. Engel, Q. Huang, Y. Xiong, Z. Huo, G. Huang*. 2021. A comprehensive analysis of water productivity in natural vegetation and various crops coexistent agro-ecosystems. Agr. Water Manage., 243: 106481. DOI: 10.1016/j.agwat.2020.106481.

[22]Liu K., G. Huang*, Z. Jiang, X. Xu, Y. Xiong, Q. Huang. 2020. A gaussian process-based iterative Ensemble Kalman Filter for parameter estimation of unsaturated flow. J. Hydrol., 589 125210, DOI: 10.1016/j.jhydrol.2020.125210.

[23]Li C., Y. Xiong*, Q. Huang, X. Xu, G. Huang. 2020. Impact of irrigation and fertilization regimes on greenhouse gas emissions from soil of mulching cultivated maize (Zea mays L.) field in the upper reaches of the Yellow River, China. J. Clean. Prod., 259, 120873. DOI: 10.1016/j.jclepro.2020.120873.

[24]Liu K., Y. Xiong, X. Xu, Q. Huang, Z Huo, G. Huang*. 2020. Modified model for simulating water flow of furrow irrigation. J. Irrig. Drain. Eng., 146(6): 06020002.

[25]Li C., Y. Xiong*, Z. Cui, Q. Huang, X. Xu, W. Han, G. Huang. 2020. Effect of irrigation and fertilization regimes on grain yield, water and nitrogen productivity of mulching cultivated maize (Zea mays L.) in the Hetao Irrigation District of China. Agr. Water Manage., 232, 106065. DOI: 10.1016/j.agwat.2020.106065.

[26]Xiong Y.*, X. Long, G. Huang. 2019. Pore structure and morphology impact on flow and transport characteristics in randomly packed grains with different angularities. Soils Found., 59, 1992-2006. DOI: 10.1016/j.sandf.2019.10.002.

[27]Ren D., B. Wei, X. Xu*, B. Engel, G. Li, Q. Huang, Y. Xiong, G. Huang. 2019. Analyzing spatiotemporal characteristics of soil salinity in arid irrigated agro-ecosystems using integrated approaches. Geoderma, 356. DOI: 10.1016/j.geoderma.2019.113935.

[28]Pan, M., Q. Huang*, R. Feng, X. Xu, Y. Xiong, G. Huang. 2019. Improving the estimation of hydraulic and thermal properties of heterogeneous media via the addition of heat loss. Vadose Zone J., 18:180149. DOI:10.2136/vzj2018.08.0149.

[29]Ren D., X. Xu*, B. Engel, Q. Huang, Y. Xiong, Z. Huo, G. Huang. 2019. Hydrological complexities in irrigated agro-ecosystems with fragmented land cover types: Insights from a distributed hydrological modeling method. Agr. Water Manage., 213, 868-881.

[30]Liu K., G. Huang*, X. Xu, Y. Xiong, Q Huang, J. Simunek. 2019. A coupled model for simulating water flow and solute transport in furrow irrigation. Agr. Water Manage., 213, 792–802.

[31]Xiong Y*, B. Yu, M. Bai, X. Zhang, G. Huang. A Furman. 2019. Soil properties and plant growth response to litter in a prolonged enclosed grassland of Loess Plateau, China. J. Earth Sci., 30(5): 1041-1048. DOI:10.1007/s12583-019-1017-3.

[32]Zhang H., G. Huang*, X. Xu, Y. Xiong, Q. Huang. 2018. Estimating evapotranspiration of processing tomato under plastic mulched irrigation in the upper reaches of the Yellow River using the dual Kc model. Water, 10, 1088. DOI:10.3390/w10081088.

[33]Li C., Y. Xiong*, Z. Qu, X. Xu, G. Huang. 2018. Impact of biochar addition on soil properties and water-fertilizer productivity of tomato in semi-arid region of Inner Mongolia, China. Geoderma, 331, 100-108.

[34]Ren D., X. Xu*, Q. Huang, Z. Huo, Y. Xiong, G. Huang. 2018. Analyzing the role of shallow groundwater system in affecting water use of different land-use types in arid irrigated regions. Water, 10, 634. DOI:10.3390/w10050634.

[35]Xiong Y., J Dai, X. Zhang, G. Huang*, A. Furman. 2017. Quantitative assessment of the heterogeneity and reproducibility of repacked silica sand columns. Vadose Zone J., 16(13). DOI:10.2136/vzj2017.06.0120.

[36]Pan W., Y. Xiong, Q. Huang*, G. Huang. 2017. Removal of nitrogen and COD from reclaimed water during long-term simulated soil aquifer treatment system under different hydraulic conditions. Water, 9, 786. DOI: 10.3390/w9100786.

[37]Zhang H., Y. Xiong, G. Huang, X. Xu, Q. Huang*. 2017. Effects of water stress on processing tomatoes yield, quality and water use efficiency with plastic mulched drip irrigation in sandy soil of the Hetao Irrigation District. Agr. Water Manage., 179, 205-214.

[38]Xiong Y.* 2014. Flow of water in porous media with saturation overshoot: A review. J. Hydrol., 10, 353-362.

[39]Xiong Y., A. Furman, R. Wallach*. 2012. Moment analysis description of wetting and redistribution plumes in wettable and water-repellent soils. J. Hydrol., 422-423, 30-42.

[40]Xiong Y., R. Wallach, A. Furman*. 2011. Modeling multidimensional water flow in wettable and repellent soils using artificial neural networks. J. Hydrol., 410, 92-104.

[41]Xiong Y., G. Huang*, Q. Huang. 2006. Modeling solute transport in one-dimensional homogeneous and heterogeneous soil columns with continuous time random walk. J. Contam. Hydrol., 86, 163-175.

[42]Huang G.*, Q. Huang, H. Zhan, J. Chen, Y. Xiong, S. Feng. 2005. Modeling contaminant transport in homogeneous porous media with fractional advection-dispersion equation. Sci. China Ser. D, 48, 295-302.

[1] 黄权中，徐旭，吕玲娇，任东阳，柯隽迪，熊云武，霍再林，黄冠华. 2018. 基于遥感反演河套灌区土壤盐分分布及对作物生长的影响. 农业工程学报，34 (1): 102-109.

[2] 王秋玲，施凡欣，刘志鹏，熊云武. 2017. 土壤斥水性影响土壤水分运动研究进展. 农业工程学报，33(24): 96-103.

[3] 熊云武，黄冠华，黄权中. 2006. 非均质土柱中溶质迁移的连续时间随机游走模拟. 水科学进展，17(6): 797-802.

[1] Xiong Y., G. Huang*, Q. Huang. K. Wang. 2006. Continuous time random walk for analyzing solute transport in one-dimensional heterogeneous soil column. Proceedings of the 34th Congress of International Association of Hydrogeologists. Beijing, China.

[2] Huang G., Y. Xiong, Q. Huang, K. Wang. 2006. Non-Fickian transport in one-dimensional homogeneous and heterogeneous soil columns. CIGR Congress, Bonn, Germany.

[1] 熊云武，董理，黄冠华. 多孔介质水分蒸发与盐分结晶过程微观尺度模拟软件(PoreEvap–v1.0)，登记号：2023SR0098615.

PoreEvap: A package to simulate evaporation-induced salt precipitation in porous media through a pore-network approach.

[2] 熊云武，邱怡超，黄冠华. 土壤孔隙结构分析软件(SoilPore–v1.0)，登记号：2021SRBJ1137.

SoilPore: A package to analyze soil porous architecture

[3] 黄冠华，冯子怡，黄权中，徐旭，熊云武. 基于SD-ELM组合分类器的遥感种植结构识别软件，登记号：2020SRBJ0196.

[1] 黄权中、刘胜、黄冠华、徐旭、熊云武、肖学、江政、张通. 2021. 一种地下水水位监测及自动取样保存装置及方法，专利号：ZL202110498001.3. 发明专利

[2] 黄权中，黄冠华，张奥，徐旭，熊云武，刘冰倩，李维垚，于兵. 2015. 一种点阵式土壤负压/含水量测量装置，专利号：CN201410120463.1. 发明专利.

[3] 黄冠华，孙宇瑞，黄权中，马道坤，熊云武，王开丽.  2010. 一种测量饱和土壤溶液中盐分浓度的装置，专利号：ZL200710099014.3. 发明专利.

团队拥有激光粒度仪、流动分析仪、元素分析仪、气相色谱仪、紫外分光光度计、电位滴定仪、恒温恒湿培养箱、无人机、多光谱和热红外相机等仪器设备，建有农田水转化、农业水文过程及生态环境、农田水土环境野外监测站点和平台。

《溶质运移理论》研究生

《Subsurface Hydrology》本科生

《专业认识实习》本科生

《水文水资源研究进展》研究生

《土壤学基础》本科生