序号 |
文章信息(2015-2020) |
1 |
Wu, ZN., Lv H, Meng Y, Guan XJ*, Zang YW, The determination of flood damage curve in areas lacking disaster data based on the optimization principle of variation coefficient and beta distribution[J], Science of The Total Environment, 2020, 750, 142277. |
2 |
Guan XJ, Jiang PK, Meng Y*, Qin HD, Lv H, Study on Production, Domestic and Ecological Benefits of Reservoir Water Supply Based on Emergy Analysis[J]. Processes. 2020, 8(11). |
3 |
Meng, Y., Liu, M., Guan, XJ*, Liu, W. Comprehensive evaluation of ecological compensation effect in the Xiaohong River Basin, China[J]. Environmental Science and Pollution Research. 2019. 26(8): 7793-7803. |
4 |
Guan XJ, Hou SL, Meng, Y*, Liu, WK. Study on the quantification of ecological compensation in a river basin considering different industries based on water pollution loss value[J]. Environmental Science and Pollution. 2019. 26(20): 30954-30966. |
5 |
Guan XJ, Qin HD, Meng Y*, Wu ZN. Comprehensive evaluation of water-use efficiency in China’s Huai river basin using a cloud–compound fuzzy matter element–entropy combined model[J]. Journal of Earth System Science, 2019, 128(7):179. |
6 |
Guan XJ, Liu WK, Wang HL, Study on the ecological compensation standard for river basin based on a coupling model of TPC-WRV[J]. Water Science & Technology Water Supply, 2018(4), 1196–1205. |
7 |
Guan XJ, Liu W, Chen M. Study on the ecological compensation standard for river basin water environment based on total pollutants control [J]. Ecological Indicators, 2016, 69: 446~452. |
8 |
Guan XJ, Liang S X, Meng Y, Evaluation of water resources comprehensive utilization efficiency in Yellow River Basin [J]. Water Science & Technology Water Supply, 2016, 16(6). |
9 |
Guan XJ, Chen M, Hu C, An ecological compensation standard based on emergy theory for the Xiao Honghe River Basin.[J]. Water Science & Technology A Journal of the International Association on Water Pollution Research, 2015, 71(10): 1463~70. |
10 |
Guan XJ, Wang H L, Li X Y, The effect of DEM and land use spatial resolution on simulated streamflow and sediment[J]. Global NEST Journal, 2015, 17(3): 525~535. |
11 |
Lv H. , Wu ZN, Guan XJ, Meng Y*. The construction of flood loss ratio function in cities lacking loss data based on dynamic proportional substitution and hierarchical Bayesian model[J]. Journal of Hydrology. 2021, 592, 125797. doi.org/10.1016/j.jhydrol.2020.125797. |
12 |
Lv H., Guan XJ, Meng Y*. Study on economic value of urban land resources based on emergy and econometric theories. Environment[J], Development and Sustainability. 2020. doi:10.1007/s10668-019-00573-4. |
13 |
Lv H., Guan XJ, Meng Y*. Comprehensive evaluation of urban flood-bearing risks based on combined compound fuzzy matter-element and entropy weight model[J]. Natural Hazards.2020. 103(2). |
14 |
Meng Y, Zhang X*, She D, Wang J, Wu B, The spatial and temporal variation of water use efficiency in the Huai River Basin using a comprehensive indicator, Water Science and Technology: Water Supply, 2017.1, 17(1): 229~237(博士成果) |
15 |
Zhang X*, Meng Y, Xia J, Wu B, She D., A combined model for river health evaluation based upon the physical, chemical, and biological elements, Ecological Indicators, 2018.1, 84: 416~424(博士成果,郑大第二单位) |
16 |
Cuimei Lv(#); Wuyue Zhang; Minhua Ling(*); Huiqin Li; Guangjun Zhang. Quantitative analysis of eco-economic benefits of reclaimed water for controlling urban dust. Environmental geochemistry and health,2020,42:2961-2973.(期刊论文) |
17 |
Xi Guo, Zening Wu, Xinling Wang, Cuimei Lv*, Changkuan Gu , Yang Li and Meiyan Gao. The Joint Optimal Allocation Study of Regional Total Water Consumption and Pollutant Carrying Capacity of Water Function Areas Based on Emergy Theory. WATER, doi:10.3390/w12041101 |
18 |
Lv, Cuimei(#); Ling, Minhua(*); Wu, Zening; Gu, Pan; Guo, Xi; Di, Danyang, Analysis of groundwater variation in the Jinci Spring area, Shanxi Province (China), under the influence of human activity, Environmental geochemistry and health,2019,41:921-928 |
19 |
Lv, Cuimei(#); Ling, Minhua(*); Wu, Zening; Guo, Xi; Cao, Qianqian, Quantitative assessment of ecological compensation for groundwater overexploitation based on emergy theory. Environmental geochemistry and health,2020,42:733-744. |
20 |
Zening Wu, Danyang Di, Cuimei Lv*, Xi Guo and Huiliang Wang. Defining and evaluating the social value of regional water resources in terms of emergy [J]. Water Policy, 2019, 21:73–90. |
21 |
Minhua Ling(#); Cuimei Lv(*); Xi Guo, Quantification method of water environmental value loss caused by water pollution based on emergy theory[J]. Desalination and Water Treatment, 2018,129: 299~303. |
22 |
Wu, Zening(#); Guo, Xi; Lv, Cuimei(*); Wang, Huiliang; Di, Danyang, Study on the quantification method of water pollution ecological compensation standard based on emergy theory, Ecological Indicators, 2018,92: 189~194. |
23 |
Zening Wu, Qianqian Cao, Cuimei Lv*. Using a three-tier model to optimize the allocation of river water resources to meet eco-environmental water requirement targets[J]. Water science and technology: water supply, 2018,18(4):1222-1233. |
24 |
lv cuimei, wu zening. Emergy Analysis of Regional Water Ecological Economic System[J]. Ecological Engineering, 2009,35:703-710. |
25 |
Wu, Z, Zhou, Y, Wang, H, Jiang Z. Depth prediction of urban flood under different rainfall return periods based on deep learning and data warehouse. Science of The TotalEnvironment. 2020,716:137077. |
26 |
Wu, Z, Shen, Y, Wang, H, Wu M. Urban Flood Disaster Risk Evaluation Based on Ontology and Bayesian Network. Journal of Hydrology. 2020, 583:124596. |
27 |
Wu, Z, Shen, Y, Wang, H, Wu M. An ontology-based framework for heterogeneous data management and its application for urban flood disasters. Earth Science Informatics. 2020, online. |
28 |
Wu Z, Shen Y, Wang H. Assessing Urban Areas Vulnerability to Flood Disaster Based on Text Data: A Case Study in Zhengzhou City. Sustainability, 2019,11(17):4548. |
29 |
Wu Z, Shen Y, Wang H, Wu M. Assessing urban flood disaster risk using Bayesian network model and GIS applications. Geomatics, Natural Hazards and Risk, 2019, 10(1): 2163-2184. |
30 |
Wu Z, Shen Y, Wang H, Wu M. Quantitative assessment of urban flood disaster vulnerability based on text data: case study in Zhengzhou. Water Science and Technology:Water Supply. 2019,online. https://doi.org/10.2166/ws.2019.171 |
31 |
Zening Wu, Danyang Di, Huiliang Wang, Meimei Wu,Chentao .He.Study on the quantification method of water pollution ecological compensation standard based on emergy theory, Ecological Indicators,2018,92:189-194. |
32 |
Zening Wu, Qianqian Cao, Cuimei Lv,Huiliang Wang, Zihao Jiang. Using a three-tier model to optimize the allocation of river water resources to meet eco-environmentalwater requirement targets. Water Science & Technology: Water Supply,2018,18(04):1222-1233. |
33 |
Wang H, He P, Shen C, Wu Z(通讯作者). Effect of irrigation amount and fertilization on agriculture non-point source pollution in the paddy field. Environmental Science and Pollution Research, 2019, 26(10): 10363-10373. |
34 |
Danyang Di, Zening Wu, Xi Guo*, Cuimei Lv, Huiliang Wang. Value Stream Analysis and Emergy Evaluation of the Water Resource Eco-Economic System in the Yellow River Basin. Water. 2019,11(4),710. |
35 |
Zening Wu, Xi Guo, Cuimei Lv, et.al. Study on the quantification method of water pollution ecological compensation standard based on emergy theory, Ecological Indicators. 2018, 92(9), 189-194. |
36 |
Zening Wu, Xi Guo, Xinjian Guan, Cuimei Lv and Huiliang Wang. Water efficiency evaluation of a regional water scheme - Zhengzhou, China, using a water ecological-economic system (WEES) and based on emergy theory, Water Science & Technology: Water Supply, 2017, 05 (17):674-687. |
37 |
Guan Xinjian, Guo Xi, Wu Zening. Emergy Analysis for the Positive and Negative Benefits of Regional Agricultural Water, International conference on water resource and environmental protection. |
38 |
Hu Caihong* et al,Response of LUCC on Runoff Generation Process in Middle Yellow River Basin: The Gushanchuan Basin,water,2020,doi:10.3390/w12051237 |
39 |
Wang Jingyi,Hu Caihong* et al,Rapid Urbanization Impact on the Hydrological Processes in Zhengzhou, China,water,doi:10.3390/w12071870 |
40 |
Caihong Hu, Qiang Wu, Hui Li, Shenqi Jian, Nan Li, Zhengzheng Lou2, Deep Learning with Long Short-term Memory Networks Approach for Rainfall-Runoff Simulation Based on Event Floods, water,2018.(10)11(SCI源刊) |
41 |
Wen Yuexiu, Hu Caihong, Zhang Guodong, Jian Shengqi *. Response of the parameters of excess infiltration and excess storage model to land use cover change. Journal of Hydrology and Hydromechnaics, 68, 2020, 2, 99–110. (通讯作者) |
42 |
Hu Caihong, Zhang Li, Wu Qiang, Shan-e-hyder Soomro, Shengqi Jian*. Response of LUCC on Runoff Generation Process in Middle Yellow River Basin: The Gushanchuan Basin. Water, 2020, 12, 1237. (通讯作者) |
43 |
Zhang Xueli, Zhang Guodong, Hu Caihong, Jian Shengqi *. Response of soil moisture to landscape restoration in the hilly and gully region of the Loess Plateau, China. Biologia, 2020, 75:827–839. (通讯作者) |
44 |
Hu Caihong, Zhang Li, Wu Qiang, Ran Guang, Jian Shengqi*. Discrimination and Analysis of runoff Generation Pattern in Gushanchuan Basin Under the Condition of Underlying Surface Change. Journal of Basic Science and Engineering, 2020, 28(3): 620-630. (通讯作者) |
45 |
Hu Caihong, Liu Chengshuai, Yao Yichen, Wu Qiang, Ma Bingyan, Jian Shengqi*, Evaluation of the Impact of Rainfall Inputs on Urban Rainfall Models: A Systematic Review, Water, 2020, 12, 2484. (通讯作者) |
46 |
Wang Jiayi, Li Yitian, Pan Li, Lai Zhiqiang, Jian Shengqi*, Study of the Sediment Transport Law in a Reverse-Slope Section of a Pressurized Pipeline, Water, 2020, 12, 3042. (通讯作者) |
47 |
Hu CaiHong, Ran Guang, Li Gang, Yu Yun, Wu Qiang, Yan Denghua, Jian Shengqi*,The effects of rainfall characteristics and land use and cover change on runoff in the Yellow River basin, China. Journal of Hydrology and Hydromechnaics, 2021, 69(1): 12-19. (通讯作者) |
48 |
Jian Shengqi, Hu Caihong, Zhang Guodong, Zhang Jinping, Study on the throughfall, stemflow, and interception of two shrubs in the semiarid Loess region of China, Agricultural and Forest Meteorology, 2019, 279, 107713. |
49 |
Jian Shengqi, Wu Zening, Hu Caihong, Estimation of water use of Pinus tabulaeformis Carr. in Loess Plateau of Northwest China, Journal of Hydrology and Hydromechnaics, 2019, 67(3): 271–279. |
50 |
Jian Shengqi, Zhang Xueli, Li Dong, Wang Deng, Wu Zening, Hu Caihong(*), The effects of stemflow on redistributing precipitation and infiltration around shrubs. Journal of Hydrology and Hydromechnaics, 2018, 66(1): 79–86. |
51 |
Jian Shengqi, Wu Zening, Hu Caihong, Zhang Xueli, Sap flow in response to rainfall pulses for two shrub species in the semiarid Chinese Loess Plateau, Journal of Hydrology and Hydromechnaics, 2016, 64(2): 121–132. |
52 |
Jian Shengqi, Zhang Xueli, Wu Zening, Hu Caihong, Water use pattern of Pinus tabulaeformis in the semiarid region of Loess Plateau, China, Forest Systems, 2016, 25(3): e077. |
53 |
Jian Shengqi, Zhao Chuanyan, Fang Shumin, Yu Kai. Evaluation of water use of Caragana korshinskii Kom. and Hippophae rhamnoides Linns. in the Chinese Loess Plateau, Canadian Journal of Forest Research, 2015, 44, 15–25. |
54 |
Jian Shengqi, Zhao chuanyan, Fang shumin, Yu kai, Effect of different vegetation restoration on soil water storage and water balance in the Chinese Loess Plateau, Agricultural and Forest Meteorology, 2015, 206, 85–96. |
55 |
Jian Shengqi, Zhao Chuanyan, Fang Shumin, Yu Kai, The distribution of fine root length density for six artificial afforestation tree species in Loess Plateau of Northwest China, Forest Systems, 2015, 24(1): e003. |
56 |
Wu, Z, He C, Wang, H*, Zhang Q. Reservoir Inflow Synchronization Analysis for Four Reservoirs on a Mainstream and its Tributaries in Flood Season Based on a Multivariate Copula Model.Water Resources Management, 34(9): 2753-2770. (通讯作者) |
57 |
Di D, Wu Z, Wang H*, Huang S. Optimal water distribution system based on water rights transaction with administrative management, marketization, and quanti fication of sediment transport value: A case study of the Yellow River Basin, China. Science of the Total Environment. 2020, 722: 137801. (通讯作者) |
58 |
Wang H, Shen C, Kang Y, Deng Q, Lin X*.Spatial distribution of pollution characteristics and human health risk assessment of exposure to heavy elements in road dust from different functional areas of Zhengzhou, China. Environmental Science and Pollution Research, 2020, 27(21): 26650-26667. (第一作者) |
59 |
Zhang, W, Zhang, L, Hua, T, Li, Y, Zhou, X, Wang, W, You, Z, Wang H*, Li, M. The mechanism for adsorption of Cr (VI) ions by PE microplastics in ternary system of natural water environment. Environmental Pollution, 2020, 257: 113440. (通讯作者) |
60 |
Di D, Wu Z, Wang H*, Lv C. A Double-Layer Dynamic Differential Game Model for the Optimal Trading Quantity of Water and Price Setting in Water Rights Transactions. Water Resources Management, 2020,34:245-262. (通讯作者) |
61 |
Zhang, W, Tang, G, Yan, J, Zhao, L, Zhou, X, Wang, H*, Feng Y, Guo Y, Wu J, Chen W, Yuan N, Li, M. The decolorization of methyl orange by persulfate activated with natural vanadium-titanium magnetite. Applied Surface Science, 2020, 509: 144886. (通讯作者) |
62 |
Zhang Y, Guo J, Sun B, Fang H, Zhu D, Wang H*. Modeling and Dynamic-Simulating the Water Distribution of a Fixed Spray-Plate Sprinkler on a Lateral-Move Sprinkler Irrigation System. Water, 2019, 11(11): 2296. (通讯作者) |
63 |
Wang H, He P, Shen C, Wu Z*. Effect of irrigation amount and fertilization on agriculture non-point source pollution in the paddy field. Environmental Science and Pollution Research, 2019, 26(10): 10363-10373. (第一作者) |
64 |
Di, D, Wu, Z, Guo, X, Lv, C, Wang, H*. Value stream analysis and emergy evaluation of the water resource eco-economic system in the Yellow River Basin. Water, 2019,11(4):710. (通讯作者) |
65 |
Wang H, Liu C, Wu Z, Yang W, Chen C. Improved dewaterability of sewage sludge by Fe (II)-activated persulfate oxidation combined with polymers. Water and Environment Journal, 2017, 31(4): 603-608. (第一作者) |
66 |
Wang, Zongmin Wang, Haibo Yang*, Danyang Di, Yong Zhao*, Qiuhua Liang. Utilizing GRACE-based groundwater drought index for drought characterization and teleconnection factors analysis in the North China Plain. Journal of Hydrology.2020,585. DOI:10.1016/j.jhydrol. 2020.124849. |
67 |
Fei Wang, Zongmin Wang, Haibo Yang*, Danyang Di, Yong Zhao*, Qiuhua Liang. Utilizing GRACE-based groundwater drought index for drought characterization and teleconnection factors analysis in the North China Plain. Journal of Hydrology.2020,585. DOI:10.1016/j.jhydrol. 2020.124849. |
68 |
Fei Wang, Zongmin Wang*, Haibo Yang*, Danyang Di, YongZhao, QiuhuaLiang. A new copula-based standardized precipitation evapotranspiration streamflow index for drought monitoring. Journal of Hydrology. 2020.585. DOI:10.1016/j.jhydrol.2020.124793. |
69 |
Fei Wang, Zongmin Wang, Haibo Yang*, Danyang Di, Yong Zhao*, Qiuhua Liang, Zafar Hussain. Comprehensive evaluation of hydrological drought and its relationships with meteorological drought in the Yellow River basin, China. Journal of Hydrology. 2020.584. DOI:10.1016/j.jhydrol. 2020.124751. |
70 |
Haibo Yang, Chaofan Xi, Xincan Zhao*, Penglei Mao, Zongmin Wang, Yong Shi, Tian He, Zhenhong Li. Measuring the Urban Land Surface Temperature Variations Under Zhengzhou City Expansion Using Landsat-Like Data. Remote Sensing. 12(5).801. DOI:10.3390/rs12050801. |
71 |
Fei Wang, Haibo Yang*, Zongmin Wang, Zezhong Zhang, Zhenhong Li. Drought Evaluation with CMORPH Satellite Precipitation Data in the Yellow River Basin by Using Gridded Standardized Precipitation Evapotranspiration Index. Remote Sensing.DOI:11(5).485. 10.3390/rs11050485. |
72 |
Fei Wang, Zongmin Wang, Haibo Yang*, Yong Zhao*, Zhenhong Li, Jiapeng Wu. Capability of Remotely Sensed Drought Indices for Representing the Spatio-Temporal Variations of the Meteorological Droughts in the Yellow River Basin. Remote Sensing. 2019,10(11).1834. DOI:10.3390/rs10111834. |
73 |
Fei Wang, Zongmin Wang, Haibo Yang*, Yong Zhao*. Study of the temporal and spatial patterns of drought in the Yellow River basin based on SPEI. Science China Earth Science.2018,61(8):1098–1111. DOI:10.1007/s11430-017-9198-2. |
74 |
Fei Wang, Zongmin Wang, Haibo Yang*, Yong Zhao*, Zezhong Zhang, Zhenhong Li, Zafar Hussain. Copula-Based Drought Analysis Using Standardized Precipitation Evapotranspiration Index: A Case Study in the Yellow River Basin, China. Water. 2019, 11(6).1298. DOI:10.3390/w11061298 |
75 |
Yuan W L, Gao QY, Wan F, et al. A Morris-Sobol Two-Layer Progressive Model for Sensitivity Analysis of Parameters in Rainfall Threshold Calculation Of Flash Flood [J]. Revista Internacional de Contaminación Ambiental, 2019,35: 133-147. |
76 |
Yuan W L, Liu MQ, Wan F, et al. The Application of Improved Cuckoo Search In Cascade Reservoir Power Generation Optimized Operation [J]. Revista Internacional de Contaminación Ambiental,2019,35: 123-131. |
77 |
Yuan W L, Liu MQ, Wan F, et al. Calculation of Critical Rainfall for Small-Watershed Flash Floods Based on the HEC-HMS Hydrological Model [J]. Water Resources Management,2019,33(7): 2555-2575. |
78 |
Yuan W L, Liu MQ, Wan F, et al. Study on the impact of rainfall pattern in small watersheds on rainfall warning index of flash flood event [J]. Natural hazard,2019,97(2): 665-682. |
79 |
Yuan W L, Fu L, Gao QY, et al. Comprehensive Assessment and Rechecking of Rainfall Threshold for Flash Floods Based on the Disaster Information [J]. Water Resources Management,2019,33(10): 3547-3562. |
80 |
Wan F, Yuan W L*, Li Q, et al. Research on Risk and Early Warning System of Inter-Basin Multi-Reservoir Water Transfer-Supply Operation with Consideration of Uncertain Factors: Risk and Early Warning System[J]. Irrigation & Drainage, 2018,67(3):461-470. |
81 |
Fang Wan, Wenlin Yuan*, Jin Zhou. Derivation of Tri-level programming model for multi-reservoir optimal operation in inter-basin transfer-diversion-supply project[J]. Water Resour Manage.2017, 31:479–494. |
82 |
Fang Wan, FuqiangWang,WenlinYuan. The reservoir runoff forecast with artificial neural network based on ant colony optimization[J]. Applied Ecology and Environmental Research. 2017,15(4):497-510. |
83 |
LI Qingyun, SUN Yanwei, YUAN Wenlin*, LYU Subing, WAN Fang. Streamflow responses to climate change and LUCC in a semi-arid watershed of Chinese Loess Plateau[J]. J Arid Land. 2017, 9(4): 609-621. |
84 |
Chengcai Zhang, He Huang, Ying Li. Analysis of water accumulation in urban street based on DEM generated from LiDAR data[J]. Desalination and Water Treatment, 2018, (119): 253-261.(SCI) |
85 |
CHENGCAI ZHANG. Application of SCS Model to Simulate Rainfall-Runoff Relationship in Lack of Data Area. INTERNATIONAL JOURNAL OF EARTH SCIENCES AND ENGINEERING, 2016,v9,n4,p1805-1808.(EI) |
86 |
管新建, 黄安齐, 张文鸽, 孟钰. 基于基尼系数法的灌区农户间水权分配研究[J].节水灌溉,2020(03): 46-49+56. |
87 |
管新建, 张一鸣, 孟钰, 刘欣. 径流序列突变检验与环境流量组成——以淮河干流王家坝为例[J]. 水土保持研究, 2020, 27(01): 353-359. |
88 |
管新建, 吕鸿, 孟钰. 基于改进灰靶模型的城市洪涝承灾风险评价[J]. 水电能源科学, 2019, 37(11): 79-82. |
89 |
管新建, 谭力, 张文鸽. 基于模糊数学法和生产函数的水权交易价格研究[J]. 水电能源科学, 2019, 37(04): 148-151. |
90 |
管新建, 胡栋, 孟钰. 多风险因素影响下的水库防洪调度风险综合评估研究[J]. 中国农村水利水电, 2019(03): 161-166. |
91 |
管新建, 秦海东, 孟钰. 基于CRITIC-TOPSIS-灰色关联度的淮河流域水资源利用效率评估[J]. 节水灌溉, 2018(11): 73-76+80. |
92 |
管新建, 刘文康, 污染价值损失模型在清潩河流域的应用研究[J]. 水电能源科学, 2018, 36(01): 48~52. |
93 |
管新建, 刘文康, 胡栋, 基于CRITIC权的污染指数法在清潩河水质评价中的应用[J]. 水电能源科学, 2017, 35(08): 49~52. |
94 |
管新建, 梁胜行, 基于熵权模型的黄河流域水资源利用效率综合评价[J].中国农村水利水电, 2016, 11: 82~85. |
95 |
孟钰, 杜琼英, 管新建*, 秦海东. 黄河流域水资源利用效率评估及空间分异研究[J]. 中国农村水利水电, 2020(10): 12-16. |
96 |
孟钰, 张一鸣, 管新建*, 梁胜行.基于生态逐级保证的河口村水库水量分配研究[J].人民黄河,2019,41(05):38-42. |
97 |
孟钰, 张宽, 高富豪, 管新建*. 基于组合赋权模型的小洪河流域生态补偿效果评价[J]. 节水灌溉,2019(10):64-67. |
98 |
孟钰, 张翔*, 夏军, 吴绍飞, 王俊钗, Christopher J. G., 水文变异下淮河长吻鮠生境变化与适宜流量组合推荐, 水利学报, 2016.5, 47(5): 626~634(博士成果) |
99 |
孟钰, 张翔, 夏军, 高仕春, 王俊钗, 吴比. 河道内生态用水保证率的概念、内涵与计算分析[J].应用基础与工程科学学报, 2018, 26(02): 229-238(博士成果,郑大第二单位) |
100 |
吕翠美,刘苗苗,李会勤,顾长宽,李洋.郑州市城区及郊县地下水主要污染组分及成因[J].南水北调与水利科技,2019,17(05):124-130. |
101 |
张倩,吴泽宁,吕翠美,郭溪,高申.基于Copula函数的郑州市外调水供水补偿特性[J].人民黄河,2019,41(04):37-41. |
102 |
吕翠美,周海生,凌敏华,陆涛.基于能值理论的水资源对农业生产贡献量化分析[J].科学技术与工程,2019,19(04):249-253 |
103 |
吕翠美,凌敏华,吴泽宁.基于能值理论的水污染损失量化方法研究[J].人民黄河,2018,40(04):76-78+82. |
104 |
曹欠欠,于鲁冀,吕翠美,范铮,李廷梅.四种沉水植物对城市污染水体的净化效果研究[J].人民黄河,2017,39(05):76-80. |
105 |
郭溪,吴泽宁,王慧亮. 区域农业生产系统用水正负效益分析及能值评估. 水利水电科技进展, 2016,36(04): 1-5 +52. |
106 |
胡彩虹,张力,下垫面变化条件下孤山川流域产流模式辨析研究,应用数学与工程学报,EI检索,2020,IO,16058/j.issn.1005-0930.2020.03.000 |
107 |
胡彩虹,徐源浩,基于长短时记忆(LSTM)神经网络的黄河中游洪水过程模拟及预报,北京师范大学学报自然科学版,2020,DOI:10.12202/j.0476-0301.2020156 |
108 |
胡彩虹,李东,李析男,荐圣淇,低影响开发模式下城市雨洪控制效果模拟研究,水利水电技术,2019,50(6) |
109 |
冉广,胡彩虹,佳芦河流域林草覆被变化对产流机制的影响,水土保持学报,2020,doi:10.13870/j.cnki.stbcxb.2020.02.0006 |
110 |
何福力,胡彩虹,王纪军,基于SPI与SDI指数的黄河流域气象和水文干旱分析,地理与地理信息科学,2015,31(3):69-75 |
111 |
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