The personal data
ResumeAidi Huo is a professor and serves as a PhD supervisor. He is mainly engaged in research on water resources information, soil erosion in arid areas, hydrological ecology, geological disasters, basin hydrological models and extreme hydrological events under climate change. He has presided over more than 30 national and provincial scientific research projects, including the major project of the National Natural Science Foundation of China: the sub-project of major engineering disaster mechanism and prevention and control in the Loess Plateau, the general project of the National Natural Science Foundation of China: the mechanism of loess hydraulic erosion and landslide mutual affection and risk warning, the Sustainable Development International Cooperation Program (referred to as Science Program or SDIC) project and the Shaanxi Provincial Key Research and Development Plan. He has published 2 academic monographs and textbooks and more than 100 academic papers as the first author/corresponding author, including more than 80 SCI-indexed papers, 1 highly cited paper, and 2 hot papers. He has won 4 awards for sharing large scientific instruments and equipment in Shaanxi Province and for agricultural science and technology in Shaanxi Province. He is the first inventor of 15 national inventions and utility patents and has 1 PCT international patent and 2 software copyrights. He is currently a member of the International Society for Hydrological Sciences, one of the directors of the Ecological Society of Shaanxi Province, one of the directors of the Joint Council of the Agricultural Science Commissioner Expert Service Platform of Shaanxi Province (Agricultural Science 114), specially invited reviewer of more than 10 kinds of international journals such as Water Resources Management, and a guest editor of several international SCI journals such as Environmental Technology & Innovation (ETI). Social positionDirector of Shaanxi Ecological Society Special reviewer Water Resources Management Environmental Technology & Innovation ResearchThe research team recruits masters, doctoral, postdoctoral and overseas students in the field of hydraulic engineering and environmental science and engineering all year round. Welcome to join us! Research areas mainly focus on watershed hydrological modelling and hydrological ecology, including: 1. Water conservancy and agricultural informatization. 2. River-groundwater conversion mechanism. 3. Watershed hydrological model. 4. Numerical modeling of groundwater. 5. Application of remote sensing in hydrology and ecology. To address the common questions in the minds of graduate students, the research team meets every two weeks in a relaxed atmosphere, fostering an environment conducive to enhancing academic achievements. The subsidy is paid on time every month according to work; Graduation requirements meet the uniform standards of the school, and graduation pressure is not high. Encourage the development of students' personalities, support students' certificates, grade examination, selection of students, joint training and further study abroad; Support participation in social practice while ensuring successful completion of studies. Currently, the team has project funds superior office conditions, and each student has a station. Support doctoral students in applying for the excellent university and National Natural Science Youth Fund projects. Open Course(1) Watershed Hydrological Model, 32 hours, graduate student. (2) River Basin Water Resources Information system, 32 hours, graduate students. (3) Hydraulics, 32 hours, international students. (4) Water Conservancy Informatization and 3S technology, 32 hours, undergraduate. (5) Water conservancy and energy planning, 32 hours, undergraduate. (6) Flood Disaster and Prevention, 30 hours, undergraduate students. (7) Application of 3S technology in Hydraulic engineering, 30 hours, undergraduate. (8) Introduction to Environmental Science, 36 hours, undergraduate. (9) Environmental Remote Sensing and GIS application, 10 hours, undergraduate. (10) Flood Disaster and Prevention, 30 hours, undergraduate. (11) Environmental Ecology, 30 hours, undergraduate. (12) Water Resources Information System, 32 hours, undergraduate. (13) Introduction to Remote sensing, 32 hours, undergraduate. Research project[1] National Natural Science Foundation international cooperation project, 42261144749, Capacity Cultivation Project + ASRT+ Mechanisms of Climate Change and Human Activities on Runoff and Erosion Based on Artificial Intelligence and Big Data-Taking Egypt and China as Examples, 2023.1-2025.12, presided. [2] General program of National Natural Science Foundation of China, 41877232, Mutual feedback mechanism and risk warning of loess hydraulic erosion and landslide, presided. [3] General program of National Natural Science Foundation of China, 41672255/D0214, Study on the formation mechanism of loess landslide caused by underground coal mining, participated in. [4] Major program of the National Natural Science Foundation of China -catastrophe mechanism and prevention and control of major projects in the Loess Plateau, the fourth program - the mutual feedback effect of the mechanism of loess erosion disaster and gully consolidation and highland plateau protection project(subquestion). 41790444/D0214, 2018/01-2022/12, presided. [5] General program of National Natural Science Foundation of China: Study on the mechanism of siltation-desilting in the hyporheic zone of rivers in arid and semi-arid regions. (41072183/D0213), 2010/01-2013/12, participated in. [6] Open Fund Project of State Key Laboratory of Loess and Quaternary Geology (Institute of Earth Environment, Chinese Academy of Sciences): The formation mechanism and control measures of loess landslide-mud flow disaster chain under the coupling effect of gravity and water erosion; SKLLQG1909; 2020.1.1-2021.12.31, presided over. [7] Key R&D projects in Shaanxi Province: The impact mechanism of the gully consolidation and highland protection project on the water cycle of small watersheds and the response to secondary geological disasters, 2020SF-424, 2020.1.1-2021.12.31, presided over. [8] BFunded projects of basic scientific research business fees of central universities (natural science): The impact mechanism of the gully consolidation and highland protection project on the water cycle of small watersheds and the response to secondary geological disasters; 300102299201, presided over. [9] Shaanxi Provincial Department of Science and Technology: 2017 Shaanxi Province Large Scientific Instrument Sharing Project (2018). presided over. [10] Xinjiang Forestry Department: Monitoring and evaluation of Populus euphratica forest protection benefit in the middle and lower reaches of Tarim River, HY-1, presided over. [11] Xinjiang Forestry Department: Research on the impact of the space-time change of water and soil resources in the middle and lower reaches of the Tarim River on the regeneration of Populus euphratica, HY-4, presided over. [12] Xinjiang Academy of Forestry Sciences: Water Resources Survey of Populus euphratica Forest Nature Reserve of Tarim River in Xinjiang, presided over. [13] Open Research Fund of the Chinese Academy of Water Resources and Hydropower: Study on temperature tracing and simulation of hyporheic zone of inland rivers in northwest China. (IWHR-SKL-201510; 214029150131), 2016/01-2017/12, presided over. [14] Shaanxi Provincial Department of Science and Technology: 2015 Shaanxi Province Large Scientific Instrument Sharing Project. (2015) 2016/06-2017/12, presided over. [15] Shaanxi Social Development Science and Technology Research Project: Study on meteorological monitoring and early warning technology of mountain torrent and debris flow in the loess plateau of northern Shaanxi. (2016SF-411) 2016/01-2017/12, presided over. [16] Shaanxi Provincial Department of Science and Technology: 2013 Shaanxi Province Large Scientific Instrument Sharing Project. (213029140180) 2014/01-2016/12, presided over. [17] National Postdoctoral Research Fund: Multispectral remote sensing monitoring model and application for eutrophication of urban landscape water. (2012m511961), 2011/01-2013/4, presided over. [18] Northwest Forestry Planning, Survey and Design Institute of the Ministry of Forestry: Construction of distributed forest resource management geographic information system based on remote sensing. (CNG-2010-2), 2010/09-2012/09, presided over. [19] China Geological Survey, Ministry of Land and Resources: Detailed Survey of Geological hazards in Loess Plateau Region of Northwest China based on Remote Sensing Huangling County (No. 1212010640403 and 1212011014012), 2010/3~2011/6, Presided over. [20] China Geological Survey, Ministry of Land and Resources: Research on Detailed Survey Methods of Geological hazards in Yaozhou District, Tongchuan City based on Remote Sensing (1212011014012), 2010/3~2011/6, presided over. [21] Central University Fund: Hydrological simulation and prediction of rainstorm type dilute debris flow in the Loess Plateau based on DEM (CHD2011JC028) 2009/06-2012/12, presided over. [22] Lingqian Land consolidation, 210000130023 Horizontal cooperation. [23] The Key Laboratory of Mine Geological Disaster Mechanism and Prevention and Control, Ministry of Natural Resources, is an open project: Monitoring and evaluation of mine ecological restoration effect. 2023.1-2024.12, presided. [24] Ningxia Mine Geological Environment Monitoring and ecological Restoration Innovation Team project (sub-project) : 3D modeling, numerical simulation and stability analysis of mine landslide. 2023.1- 2024.12,presided. ThesisThesis [1] Huo, A., Zhao, Z., Wang, X., et al. Hydrologic response change and optimization of gully consolidation and highland protection in the Malian River based on CMADS+SWAT Model [J/OL]. Advances in Water Science, 1-10. http://kns.cnki.net/kcms/detail/32.1309.p.20231020.143 8.002.html. [2] Wang, X., Huo, A., Lv, J, et al.(2023). Dynamic changes and driving factors of vegetation coverage in the mainstream of Tarim River, China. Transactions of the Chinese Society of Agricultural Engineering, 39(8), 284-292. [3] Lyu, J., Fu, X., Lu, C., Zhang, Y., Luo, P., Guo, P., Huo, A., Zhou, M. Quantitative assessment of spatiotemporal dynamics in vegetation NPP, NEP and carbon sink capacity in the Weihe River Basin from 2001 to 2020[J]. Journal of Cleaner Production, 2023, 428: 139384. [4] Huo, A., Liu, Q., Zhao, Z., Elbeltagi, A., Abuarab, M. E. S., & Ganjidoust, H. (2023). Habitat Quality Assessment and Driving Factor Analysis of Xiangyu in Feng River Basin Based on InVEST Model. Water, 15(23), 4046. https://doi.org/10.3390/w15234046. [5] Wang, X., Huo, A., Lv, J, et al. Variation Characteristics and Source Analysis of Atmospheric Ozone Pollution in Guanzhong Region[J/OL].Environmental Science. https://doi.org/10.13227 /j.hjkx.202305229. [6] Zhao Z, Huo A, Cheng Y, Luo P, Peng J, Elbeltagi A, Mohamed EL, Mokhtar A. Experimental study on slope morphological characteristics and stability analysis of GCHP engineering in the loess plateau. Advances in Space Research. 2023 Nov 15;72(10):4324-35. [7] Luo, Y.; Huo, A.; Yang, L.;Zhao, Z.; Ahmed, A.; Elbeltagi, A.;Abuarab, M.E.-S.; Ganjidoust, H. Assessment of the Implementation Effect of a Gully Consolidation and Highland Protection (GCHP) Project Based on the GeoWEPP Model. Water 2023, 15, 2971. https://doi.org/10.3390/w15162971. [8] Zhao, Z.; Huo, A.; Liu, Q.;Peng, J.; Elbeltagi, A.; Abuarab,M.E.-S.; Abu-Hashim, M.S.D. Spatiotemporal Variation in the Coupling Relationship between Human Activities and Soil Erosion- A Case Study in the Weihe River Basin. Sustainability 2023, 15,10785. https://doi.org/10.3390/su151410785. [9] Zhong, F.; Huo, A.; Zhao, Z. et al. Effect of Basin Urbanization on Flood Regime in the LoessPlateau Gully Region Based on HEC-HMS [J]. Yellow River, 2032, 45. [10] Lyu J, Fu X, Lu C, Zhang Y, Luo P, Guo P, Huo A, Zhou M. Quantitative assessment of spatiotemporal dynamics in vegetation NPP, NEP and carbon sink capacity in the Weihe River Basin from 2001 to 2020. Journal of Cleaner Production. 2023 Nov 20;428:139384. [11] Zhai, H.; Wang, J.; Lu, Y.; Rao, Z.; He, K.; Hao, S.; Huo, A.; Adnan, A. Prediction of the Mine Water Inflow of Coal-Bearing Rock Series Based onWell Group Pumping. Water 2023, 15, 3680. https://doi.org/10.3390/w15203680. [12] Yang, Y.; Cui, Q.; Cheng, R.; Huo, A.; Wang, Y. Retrieval of Soil Heavy Metal Content for Environment Monitoring in Mining Area via Transfer Learning. Sustainability 2023, 15, 11765. https://doi.org/10.3390/su151511765. [13] Zhang, J.; Gong, Y.; Huang, W.; Wang, X.; Ke, Z.; Liu, Y.; Huo, A.; Adnan, A.; Abuarab, M.E.-S. Identification of Potential Landslide Hazards Using Time-Series InSAR in Xiji County, Ningxia. Water 2023, 15,300. https://doi.org/10.3390/w15020300. [14] Zhang, Jia, Yongfeng Gong, Wei Huang, Xing Wang, Zhongyan Ke, Yanran Liu, Aidi Huo, Ahmed Adnan, and Mohamed EL-Sayed Abuarab. Identification of Potential Landslide Hazards Using Time-Series InSAR in Xiji County, Ningxia. Water 15, no. 2 (2023): 300. [15] Zhao, Zhixin, Qi Liu, Aidi Huo, Yuxiang Cheng, Wenke Guan, E. L. Mohamed, Ali Mokhtar, and Ahmed Elbeltagi. A novel integrated approach for monitoring drought stress in an aeolian desertification area using Vegetation Drought Status Index. Water Supply 23, no. 2 (2023): 738-748. 2022 [16] Huo, A.; Wang, X.; Zhao, Z.; Yang, L.; Zhong, F.; Zheng, C.; Gao, N. Risk Assessment of Heavy Metal Pollution in Farmland Soils at the Northern Foot of the Qinling Mountains, China. Int. J. Environ. Res. Public Health 2022, 19, 14962. https://doi.org/10.3390/ijerph192214962 [17] Huo, A.; Zhao, Z.; Luo, P.; Zheng, C.; Peng, J.; Abuarab, M.E.-S. Assessment of Spatial Heterogeneity of Soil Moisture in the Critical Zone of Gully Consolidation and Highland Protection. Water 2022, 14, 3674. https://doi.org/10.3390/w14223674 [18] Huo A, Peng J, Cheng Y, et al. Key Issues in the Research on Loess Flow Slides Under Hydraulic and Gravitational Soil Erosion[C]//Conference of the Arabian Journal of Geosciences. Springer, Cham, 2022: 295-297. [19] Huo, A., Zhao Z, Luying Y, et al. Apparatus and method for real-time monitoring of groundwater level and soil moisture of gully head landfill area: U.S. Patent Application 17/527,199[P]. 2022-3-10. [20] Aidi H, Jianbing P, Yuxiang C, Pingping L, Zhixin Z, Chunli Z (2021a) Hydrological Analysis of Loess Plateau Highland Control Schemes in Dongzhi Plateau. Front Earth Sci 8:528632. [21] Aidi H, Lei Y, Pingping L, Yuxiang C, Jianbing P, Daniel N (2021b) Influence of landfill and land use scenario on runoff, evapotranspiration, and sediment yield over the Chinese Loess Plateau.Ecological Indicators 121:107208. 2021 [22] Huo A, Chen S, J Peng, et al. UAV-based gully retrogressive erosion status dynamic variability investigations in Chinese Loess Plateau[J]. Arabian Journal of Geosciences, 2021, 14(4):1-10. 2020 [23] Huo, A., Z. Huang, Y. Cheng, and M.W. Van Liew, Comparison of two different approaches for sensitivity analysis in Heihe River basin (China). Water Supply, 2020. 20(1): p. 319-327. [24] Huo, A., L. Yang, J. Peng, Y. Cheng, and C. Jiang, Spatial characteristics of the rainfall induced landslides in the Chinese Loess Plateau. Human and Ecological Risk Assessment: An International Journal, 2020: p. 1-16. DOI: 10.1080/10807039.2020.1728517 2019 [25] Huo AD, Wang X, Liang Y, Jiang C, Zheng X (2019b) Integrated numerical model for irrigated area water resources management. Journal of Water and Climate Change. [26] Huo, A., Wang, X., Lyu, Y., Cheng, Y., Zheng, C., & Song, J. (2019). Simulation research on the reinjection temperature fields of deep geothermal wells based on real-scale experiment. Energy Exploration & Exploitation, 37(2), 646–662. [27] Huo, A., J. Peng, Y. Cheng, X. Zheng, and Y. Wen, Temporal Characteristics of the Rainfall Induced Landslides in the Chinese Loess Plateau (China), in Recent Advances in Geo-Environmental Engineering, Geomechanics and Geotechnics, and Geohazards. 2019, Springer. p. 425-427. [28] Huo, A., X. Wang, Y. Cheng, C. Zheng, and C. JIANG, IMPACT OF FUTURE CLIMATE CHANGE (2020–2059) ON THE HYDROLOGICAL REGIME IN THE HEIHE RIVER BASIN IN SHAANXI PROVINCE, CHINA. International Journal of Big Data Mining for Global Warming, 2019: p. 1950003. [29] Huo, A., Wang, X., Liang, Y., Jiang, C., Zheng, X., 2019b. Integrated numerical model for irrigated area water resources management. Journal of Water and Climate Change. https://doi.org/10.2166/wcc.2019.042 2018 [30] Huo A, Wei H, Guan W, Du W, Zhong J, Yi X Hydrochemical characteristics and effects on growth of Populus euphratica in desertification areas: A case study in Tarim National Nature Reserve of China. In: BASIC & CLINICAL PHARMACOLOGY & TOXICOLOGY, 2018. WILEY 111 RIVER ST, HOBOKEN 07030-5774, NJ USA, pp 36-36 [31] Huo A, Zheng X, Peng J, Cheng Y, Jiang C, Wen Y Gully retrogressive erosion status dynamic variability investigations based on remote sensing big data. In: BASIC & CLINICAL PHARMACOLOGY & TOXICOLOGY, 2018. WILEY 111 RIVER ST, HOBOKEN 07030-5774, NJ USA, pp 52-52 2016 [32] Huo, Aidi,Zhang, Jia,Cheng, Yuxiang,Yi, Xiu,Qiao, Liang,Su, Fengmei,Du, Yalei,Mao, Hairu. Assessing the effect of scaling methods on retrieval of soil moisture based on MODIS images in arid regions. Toxicological and Environmental Chemistry, 2016, 98(3-4):410-418. http://dx.doi.org/10.1080/02772248.2015.1123484. [33] Huo A, Peng J, Chen X, Deng L, Wang G, Cheng Y (2016) Groundwater storage and depletion trends in the Loess areas of China. Environmental Earth Sciences 75 (16):1-11. doi:10.1007/s12665-016-5951-4. [34] Huo A-D, Guan W-K, Dang J, Wu T-Z, Shantai H, Wang W, Liew MWV (2016) Submerged area of typical torrential flood and debris-flow disasters in Mengzong Gully, China. Geomatics, Natural Hazards and Risk:1-7. [35] Huo A-D, Dang J, Song J-X, Chen XH, Mao H-R (2016) Simulation modeling for water governance in basins based on surface water and groundwater. Agricultural Water Management, Volume 174, August 2016, Pages 22-29. [36] Huo, A., Chen, X. *, Li, H., Hou, M. and Hou, X. Development and testing of a remote sensing-based model for estimating groundwater levels in aeolian desert areas of China. 2015 [37] Huo, A., Z. Ma, S. Guo, Y. Du, F. Su, Groundwater Flow Transfixion of Deep Heat Reservoir and Its Influence on Temperature Field. International Journal of Mathematics and Computational Science. Vol. 1, No. 5, 2015, pp. 295-302. 2014 [38] Huo, Aidi (#) (*),Zhang, Jia,Qiao, Changlu ,Li, Chenlong,Xie,Juan,Wang, Jucui,Zhang, Xu,Multispectral remote sensing inversion for city landscape water eutrophication based on Genetic Algorithm-Support Vector Machine,Water Quality Research Journal of Canada,2014,49(3):285-293.http://dx.doi.org/10.2166/wqrjc.2014.040. 2013 [39] Huo, A. Hua Li. Assessment of climate change impact on the streamflow in a typical debris flow watershed of Jianzhuangcuan catchment in Shaanxi Province, China. Environmental Earth Sciences,2013. [40] Huo A-D, Li J-G, Jiang G-Z, Yang Y (2013) Temporal and Spatial Variation of Surface Evapotranspiration Based on Remote Sensing in Golmud Region, China. Appl. Math. Inf. Sci. 7, No. 2L, 519-524 (2013) [41] Huo, Aidi(#)(*) ,Li, Hua,Assessment of climate change impact on the stream-flow in a typical debris flow watershed of Jianzhuangcuan catchment in Shaanxi Province, China,Environmental Earth Sciences,2013,69(6):1931-1938. 2012 [42] Ai-di H, Hui-xia Z, Li Z, Hua L, Ming H (2012) A Sampled Method of Classification of Susceptibility Evaluation Unit for Geological Hazards based on GIS. Appl Math 6 (1S):19S-23S. 2011 [43] Huo, A., Chen, X. *, Li, H., Hou, M. and Hou, X. Development and testing of a remote sensing-based model for estimating groundwater levels in aeolian desert areas of China. Can. J. Soil Sci., 91: 29-37, 2011. [44] Huo, A., Li, H., Hou, M., Qiao, C.. Relations between surface evapotranspiration and water table: A case study base on remote sensing. African Journal of Agricultural Research[J], 6(32):6653-6660, 2011. [45] Huo A, Chen X, Li H, Hou M, Hou X (2011) Development and testing of a remote sensing-based model for estimating groundwater levels in aeolian desert areas of China. Canadian Journal of Soil Science 91 (1):29-37. [46] Huo, A. , et al. Methodology of land surface broadband albedo retrieval in the desertification area based on MODIS image data. International Symposium on Water Resource & Environmental Protection IEEE, 2011. [47] Huo, A. D., et al. Method of Classification for Susceptibility Evaluation Unit for Geological Hazards: A Case Study of Huangling County, Shaanxi, China. Journal of Jilin University(Earth Science Edition) (2011). [48] Huo, A., et al. Study on the monitoring model of soil moisture for Aeolian desertification using MODIS image data. Proc Spie 7840(2009):78400D-78400D-7. [49] Huo, A., et al. Dynamic Characteristics of Vertical Hyporheic Flux in the Downstream of Weihe River, China [J]. Journal of Changjiang River Scientific Research Institute, 2018, 35(09):17-22. [50] Huo, A., Lu, Y., Hu, A., Lv, J., et al. The construction of water conservancy professional curriculum system based on cloud computing technology and big data platform [J].Education Modernization, 2018,5(51):355-357.DOI:10.16541/j.cnki.2095-8420.2018.51.169. [51] Huo, A., Zhang, J., Lu, Y.,et al. Method of Classification for Susceptibility Evaluation Unit for Geological Hazards: A Case Study of Huangling County, Shaanxi, China.[J].Journal of Jilin University (Earth Science Edition), 2011, 41(02):523-528+535.DOI:10.13278/j.cnki.jjuese. [52] Huo, A., Zhang, G., Zhao, J., et al. Study on remote sensing monitoring model of groundwater level in Aeolian desertification areas A case study of Mu Us Aeolian desertification areas, China[J].Agricultural Research in the Arid Areas, 2010, 28(06):196-200. [53] Huo, A.,Kang, X., Zhang, G., et al. Study on soil moisture model in Mu Us desert using MODIS image[J].Agricultural Research in the Arid Areas, 2010, 28(04): 19-23. [54] Huo, A., Zhang, G., Wang, G., et al. Methodology of the Land Surface Wide Band Albedo Retrieving in Desertification Area with MODIS Data-A Case Study in Xinjiang Aeolian Desertification Regions[J]. Journal of Northwest Forestry University, 2010, 25(01):212-215. [55] Huo, A., Kang, X., Liu, Z., et al. Simplified Split-window Algorithm Model to Retrieve Land Surface Temperature in Aeolian Desertification Area with MODIS image Data Taking North Shaanxi Province as an Example, 2009. 31(003): p. 306-311. [56] Huo, A., Liu, Z., Kang, X., et al. (2008) Method of retrieving land surface temperature from MODIS image in desertified area [J]. Chinese High Technology Letters. 18 (5):511-518. [57] Huo, A., Kang, X., Wang, G., et al. Model establishment of vegetation coverage extraction in sandy desertification Area based on MODIS image data [J].Agricultural Research in the Arid Areas, 2008(06):217-223. [58] Huo, A., Zhang, G., Wu, S., et al. The application of remote sensing technique to sandy desertification assessment based on MODIS data-Taking North Shaanxi as an example[J].Agricultural Research in the Arid Areas, 2008(02):154-158. [59] Huo, A., Zhang, G., Wu, S., et al. Progressing and problems of domestic and international desertification dynamic monitoring and evaluation. Agricultural Research in the Arid Areas, 2007. 25(2): p. 206-211. [60] Huo, A., Zhang, G., Wu, S., et al. Design and application of the information system of soil recommendation fertilization[J].Agricultural Research in the Arid Areas, 2006(06):90-93+102. Writings Aidi Huo, Jiqiang Lv, Pingping Luo, Yan Liang, Chunli Zheng. Watershed hydrological model and practical textbook. [M] Xi'an: Xi'an Jiaotong University Press, 2022. Technological AchievementsPatent [1] ZL 2016 2 0626776.9. A data acquisition device for measuring hyporheic flux. Huo Aidi, Deng Lin, Dang Jian, Sai Jiamei, Mao Hairu, Li Yinghao, Wei Hong. [2] ZL 2016 2 0959616.6. A monitoring, forecasting and early warning device for stormy and watery debris flow. Huo Aidi, Dang Jian, Wang Jucui, Wang Jie, Li Zecheng, Wang Lei, Cao Zhe, Yuan Jing. [3] ZL 2017 2 1806415.3. A simulation device for checking the effect of gully consolidation and highland protection projcetion. Huo Aidi, Jiang Cheng, Zhu Xinghua, Li Lan, Wang Xiaofan, Wei Hong, Zheng Xiaolu, Du Weihong. [4] 201610398015.7. A monitoring, forecasting and early warning method for stormy and watery debris flow. Huo Aidi, Dang Jian, Wang Jucui, Wang Jie, Li Zecheng, Xu Xueqiao, Ge Song, Min Sixian, Li Tao. [5] ZL 2017 2 1770922.6, Sensor bracket. Huo Aidi, Jiang Cheng, Wang Xiaofan, Guan Wenke, Cheng Jinze, Li Lan, Wei Hong, Zheng Xiaolu. [6] ZL201610459828.2. A measuring device and method of hyporheic flux based on temperature tracing. Huo Aidi, Dang Jian, Deng Lin, Sai Jiamei, Zhang Jia, Mao Hairu, Li Yinghao, Wei Hong. [7] ZL201820982386.4. A radiation well drainage device based on gully consolidation and highland protection. Huo Aidi, Wang Xiaofan, Zhu Xinghua, Li Congyi, Jiang Cheng, Zheng Xiaolu, Du Weihong, Wei Hong. [8] ZL 2018 2 2105549.3. A groundwater level monitoring device. Huo Aidi, Du Weihong, Yang Lei, Huang Zhikai, Guan Wenke, Wei Hong. [9] ZL 201711397806.9. A simulation device and simulation method and application of engineering measures for gully consolidation and highland protection. Huo Aidi, Li Lan, Zhu Xinghua, Jiang Cheng, Wang Xiaofan, Wei Hong, Zheng Xiaolu, Du Weihong. [10] ZL 2019207926318. A groundwater level monitoring device for forecasting and early warning of the new water demand of Populus euphratica forest after root pruning. Guan Wenke, Du Weihong, Huo Aidi, Huang Zhikai, Yang Lei, Wei Hong. [11] ZL201920985547.X. A real-time monitoring device for groundwater level and soil moisture in the gully head landfill area. Huo Aidi, Yang Lei, Huang Zhikai, Chen Siming, Chen Sibin, Li Congyi, Wen Yiran [12] Software copyright 1: The secondary survey and statistical analysis system of forest resources based on remote sensing. V1.0 (2010SR054240), the first signatory. Huo Aidi. National Copyright Administration of the People's Republic of China. May 6, 2011. [13] Software copyright 2: Geological hazard information management system based on remote sensing GHIS.VER1.0 (2011SR026346), the first signatory. Huo Aidi, Wang Jinglei. National Copyright Administration of the People's Republic of China. May 6, 2011. Honor Reward2009.10, excellent instructor of summer social practice of Chang'an University 2010.07, excellent instructor of the undergraduate thesis of Chang'an University 2010.12, excellent teacher of Chang'an University 2011.07, excellent instructor of the undergraduate thesis of Chang'an University 2013.10, exemplary individual of Shaanxi Provincial Large Scientific Instrument Cooperation Office 2013 Advanced Manager of Shaanxi Provincial Large Scientific Instrument and Equipment Sharing 2015.10, exemplary individual of Shaanxi Provincial Large Scientific Instrument Cooperation Office 2015 Advanced Manager of Shaanxi Provincial Large Scientific Instrument and Equipment Sharing 2017.06,the first prize of instructor in the 11th Little Doctor of the Earth National Geographic Popular Science Knowledge Competition and was awarded the title of National Excellent Science and Technology Instructor. 2019, advanced scientific research workers of Chang'an University from 2015 to 2018 2019, Outstanding exemplary individual of Chang'an University 2021, the second prize of the Higher Education Teaching Achievement Award of Chang'an University: research on the educational model of using cloud computing technology to build hydrological data platform, Aidi Huo, Yudong Lu, Pingping Luo, Yinke Yang, Hongbo Zhang Work experience2008.06-2011.11: Lecturer, School of Water Resources and Environment, Chang'an University 2014.08-2015.08: Visiting scholar, Department of Natural Resources, University of Nebraska and Lincoln, USA 2011.11-2014.04: Post-doctor, School of Water Resources and Environment, Chang'an University 2011.11-2018.11: Associate Professor, School of Water Resources and Environment, Chang'an University 2018.11-Till now: Professor, School of Water Resources and Environment, Chang'an University |