[1] 国家自然科学基金重点项目 “多年冻土变化与水文过程的耦联机制研究” (42330512),2024.1-2028.12,骨干
[2] 国家自然科学基金面上项目:“疏勒河上游山区积雪风吹雪过程观测与模拟试验研究”(42171124), 2022-2025 主持
[3] 国家重点研发计划课题:“温升背景下雨雪冰混合洪水形成过程模拟技术研发”(2019YFC1510503),2020.1-2023.11 主持
[4] 航天宏图信息技术有限责任公司委托项目:《地球系统数值模拟装置-区域高精度长期气候变化风险模拟分系统》项目的“冰冻圈灾害模拟分析子系统”,2020.7-2023.6,主持
[5] 国家自然科学基金重点项目课题“西北内陆河山区流域水文内循环过程及机理研究” (41730751-1),2018.1-2022.12,主持
[6] 国家自然科学基金面上项目:“疏勒河上游山区冰川储量变化及其对水资源的影响”(41671056),2017.1-2020.12,主持
[7] 国家自然科学基金面上项目:”长江源区冰川面积-表面形态变化及其对水资源的影响研究”(41271090),2013.1-2016.12, 主持
[8]国家自然科学基金项目重点项目 “干旱区典型山区流域水量平衡观测试验与模拟研究”(41130638),2012.1-2016.12, 骨干
主要成果
2023
[1] Li, C.,Zhang, S*., Synergistic changes in precipitation and soil water use efficiency and their driving mechanisms of terrestrial ecosystems in China. Journal of Cleaner Production, 2023,426:139159. DOI: 10.1016/j.jclepro.2023.139159
[2] Wu, Y.; Zhang, W.; Zhang, S.; Mao, Z.; Chen, A.; Li, Z.; Zhang, Q.; Guo, Z.; Jiang, X.; Long, Y. Emerging Signal of Englacial Debris on One Clean Surface Glacier Based on High Spatial Resolution Remote Sensing Data in Northeastern Tibetan Plateau. Remote Sens. 2023, 15, 3899. DOI:10.3390/rs15153899
[3] Li, C.; Zhang, S*.,Chen, R.;Zhang, D.; Zhou, G.; Li,W.; Rao, T. The Spatio-Temporal Changes of Small Lakes of the Qilian Mountains from 1987 to 2020 and Their Driving Mechanisms. Remote Sens. 2023, 15, 3604. DOI:10.3390/rs15143604
[4] Hua, T., Wang, N*., Liu, J., Zhang, S. and Tan, Q., 2023. The role of external and local atmospheric moisture fluxes in the interannual variability of peak summer precipitation over the northern fringe of the East Asian summer monsoon. Journal of Hydrology,625:129912. DOI:10.1016/j.jhydrol.2023.129912
[5] Li C, Zhang S*, Zhang D, Zhou G,2023, An intra-annual 30-m dataset of small lakes of the Qilian Mountains for the period 1987–2020, Scientific Data, 10(1):365. DOI: 10.1038/s41597-023-02285-x
[6] 李雯,侯丽陶,张世强*,1980―2019年西北地区海拔依赖性变暖(EDW)与雪雨比的关系研究,地理研究,2023, 42(7):1957-1970
[7] Chang, Y., Ding, Y*., Zhang, S., Qin, J. and Zhao, Q*., 2023. Variations and drivers of evapotranspiration in the Tibetan Plateau during 1982–2015. Journal of Hydrology: Regional Studies, 47: 101366. DOI:10.1016/j.ejrh.2023.101366
[8] Chang Y, Ding Y, Zhao Q, Zhang S*, Attributing evapotranspiration changes with an extended Budyko framework considering glacier changes in a cryospheric-dominated watershed, Remote Sensing, 2023, 15, 558. DOI: 10.3390/rs15030558
[9] Zhou G, Zhang D, Wan J, Cui M, Zhang S* ,Mapping reveals contrasting change patterns of rain-on-snow events in China during 2001 to 2018, Journal of Hydrology,2023, 617,129089 DOI:10.1016/j.jhydrol.2023.129089
[10] Chang Y, Ding Y*, Zhao Q, Qin J, Zhang S*,Elevation-dependent changes in the trend of reference evapotranspiration in the Tibetan Plateau during 1960–2017,International Journal of Climatlogy,2023, 43(5), 2077-2095. DOI:10.1002/joc.7964
[11] Zhang D, Zhou G, Li W, Han L, Zhang S*, Yao X, Duan H. 2023. A robust glacial lake outburst susceptibility assessment approach validated by GLOF event in 2020 in the Nidu Zangbo Basin, Tibetan Plateau. CATENA, 220: 106734. DOI: 10.1016/j.catena.2022.106734
2022
[1] Li, C.; Zhang, S*.; Cui, M.; Wan, J.; Rao, T.; Li, W.; Wang, X. Improved Vegetation Ecological Quality of the Three-North Shelterbelt Project Region of China during 2000–2020 as Evidenced from Multiple Remotely Sensed Indicators. Remote Sens. 2022, 14, 5708. DOI:10.3390/rs14225708
[2] Zhang D, Zhou G, Li W, Zhang S*, Yao X, Wei S. 2022. A new global dataset of mountain glacier centerlines and lengths, Earth System Science Data, 14: 3889-3913. DOI: 10.5194/essd-14-3889-2022.
[3] Chang Y, Ding Y*, Zhang S, Qin J, Zhao Q*. 2022. Dynamics and environmental controls of evapotranspiration for typical alpine meadow in the northeastern Tibetan Plateau. Journal of Hydrology, 612: 128282. DOI: 10.1016/j.jhydrol.2022.128282.
[4] Liu Q, Zhang S, Wang N, Ming Y, Huang C*, Fusing Landsat-8, Sentinel-1, and Sentinel-2 Data for River Water Mapping Using Multi-dimensional Weighted Fusion Method, IEEE Transactions on Geoscience and Remote Sensing, 2022,60:1-12. DOI: 10.1109/TGRS.2022.3187154.
[5] 崔曼仪,周刚,张大弘,*张世强,2022,1900-2020年全球融雪洪水灾害及其影响变化研究,冰川冻土,44(6):1898-1911
[6] Chang Y, *Ding Y, Zhao Q, Qin J, *Zhang S. 2022. Optimization of canopy resistance models for alpine meadow in the northeastern Tibetan Plateau. Journal of Hydrology, 610: 128007. DOI: 10.1016/j.jhydrol.2022.128007
[7] 侯丽陶,蒲旭凡,李哲,张小文*,张世强,1980-2019年中国西北地区降雪和融雪时空变化特征. 地理研究,2022,41(3):880-902
[8] Li X, Wang N, Ding Y, Hawkings JR, Yde JC, Raiswell R, Liu J, Zhang S, Kang S, Wang R. Globally elevated chemical weathering rates beneath glaciers. Nature Communications, 2022,13: 1-13.
2021
[1] 李飞,郭佳锴,张世强*.VIC-CAS导热率和未冻水算法改进及其对多年冻土水热过程模拟的实验研究,冰川冻土, 2021, 43(6):1888-1903.
[2] Zhang Z, Zhao Q, Zhang S*, Abundant Precipitation in Qilian Mountains Generated from the Recycled Moisture over the Adjacent Arid Hexi Corridor, Northwest China. Water,2021, 13,3354. DOI:10.3390/w13233354
[3] Zhou G, Cui M, Wang J, Zhang S*, A review on snowmelt models: progress and prospect. Sustainability, 2021,13,11485. DOI: 10.3390/su132011485
[4] 王雷,龙永清,庞国伟,王春梅,刘建红,杨勤科,张世强.在GIS实验教学中引入思政教学元素的实践——黄土高原水土保持GIS思政实验案例库建设.南京师大学报(自然科学版),2021,44(S1):77-81.
[5] Zhang Y, Wang N, Tang C*, Zhang S*, Song Y, Liao K, Nie X, A new indicator to better represent the impact of landscape patterns change on basin soil erosion and sediment yield in upper reach of Ganjiang, China. Land, 2021,10(9), 990. DOI: 10.3390/land10090990
[6] 周刚,崔曼仪,李哲,张世强*. 新疆春季融雪洪水危险性动态评价研究,干旱区研究。2021, 38(4): 950-960. DOI:10.13866/j.azr.2021.04.06
[7] 陈仁升,沈永平,毛炜峄,张世强,吕海深,刘永强,刘章文,房世峰,张伟,陈春艳,韩春坛,刘俊峰,赵求东,郝晓华,李如琦,秦艳,黄维东,赵成先,王世峰. 西北干旱区融雪洪水灾害预报预警技术:进展与展望. 地球科学进展,2021,36(3):233-244.DOI:10.11867/j. issn. 1001-8166.2021.025.
[8] 郭佳锴,李哲,李飞,张世强*. 基于多源遥感数据的疏勒河上游山区流域VIC-CAS模型积雪模拟效果评估研究,冰川冻土,2021, 43(2): 650-661. DOI: 10.7522/j.issn.1000-0240.2021.0049
[9] Wu Q, Ma S, Zhang Z, Wang G, Zhang S*, Evaluation of nine precipitation products with ground-based measurements during 2001 to 2013 in alpine Upper Reach of Shule River Basin, Northeastern edge of Tibetan Plateau, Theoretical and Applied Climatology,2021, 144(3): 1101-1117. DOI: 10.1007/s00704-021-03585-1
[10] Chen A, Zhang S*, Li Z. Impact of ASD and Delta downscaling methods on projecting future climate change in northeast Tibetan Plateau, Climate Research, 2021, 83:91-110. DOI: 10.3354/cr01634
[11] Huang C, Zhang S, Dong L, Wang Z, Li L, Cui L. 2021. Spatial and temporal variabilities of rainstorms over China under climate change. J. Geogr. Sci, 31(4):479-496
[12] 蒲旭凡,丁永建,侯丽陶,张小文,张世强,基于GF-1的青藏高原东南部积雪分布及MODIS积雪产品适用性研究,地理科学进展, 2021 ,40(3): 477-486
2020
[1] Ding Y*, Zhang S*, Chen R, Han T, Han H, Wu J, Li X, Zhao Q, Shangguan D, Yang Y, Liu J, Wang S, Qin J, Chang Y. Hydrological Basis and Discipline System of Cryohydrology: From a Perspective of Cryospheric Science. Frontiers in Earth Science-Cryospheric Sciences, 2020,8:574707. DOI: 10.3389/feart.2020.574707
[2] 邓诗凡,张智华,马思煜,*张世强.老旧小区近距离铸铁管线探测实验与应用,地球物理学进展.2020, 35(5): 1945-1952
[3] 李哲,丁永建*,陈艾姣,张智华,张世强.1960—2019年西北地区气候变化中的Hiatus现象及特征.地理学报, 2020,75(9):1845-1859.
[4] Zhang Y, Tang C*, Ye A. Zheng T, Nie X, Tu A. Zhu H, Zhang, S*. Impacts of Climate and Land-Use Change on Blue and Green Water: A Case Study of the Upper Ganjiang River Basin, China. Water, 2020, 12, 2661. DOI: 10.3390/w12102661
[5] 丁永建,张世强*,吴锦奎,赵求东,李向应,秦甲.中国冰冻圈水文过程变化研究新进展.水科学进展,2020, 31(5):690-702. DOI: 10.14042/j.cnki.32.1309.2020.05.006
[6] 丁永建,赵求东,吴锦奎,张世强,王生霞,苌亚平,李向应,上官冬辉,韩海东,秦甲,韩添丁.中国冰冻圈水文未来变化及其对干旱区水安全的影响.冰川冻土,2020,42(1):23-32.
[7] Ma, S., Zhang S*, Wu Q, Wang J. Long-term Changes in Surface Soil Moisture Based on CCI SM in Yunnan Province, Southwestern China. Journal of hydrology. 2020, 588: 125083 DOI: 10.1016/j.jhydrol.2020.125083
[8] Liu, Q.; Huang, C.; Shi, Z.; Zhang, S. Probabilistic River Water Mapping from Landsat-8 Using the Support Vector Machine Method. Remote Sens. 2020 12, 1374.
[9] 丁永建,张世强,陈仁升. 冰冻圈水文学:解密地球最大淡水库. 中国科学院院刊,2020, 35(4):393-403. DOI: 10.16418/j.issn.1000-3045. 20200302002
[10] Deng, S., Ma, S., Zhang, X, Zhang, S*. 2020. Integrated Detection of a Complex Underground Water Supply Pipeline System in an Old Urban Community in China. Sustainability 12, 1670. DOI: 10.3390/su1204167
[11] Chang Y, Ding Y, Zhao Q, Zhang S*. 2020. A Comprehensive Evaluation of 4-Parameter Diurnal Temperature Cycle Models with In Situ and MODIS LST over Alpine Meadows in the Tibetan Plateau. Remote Sensing, 12:103. DOI: 10.3390/rs12010103
[12] 李想,张世强*,梁倩. 小型四旋翼无人机序列影像三维重建实验研究. 遥感信息, 2020, 35(1): 135-141
[13] 丁永建,张世强,陈仁升,2020.冰冻圈水文学. 北京:科学出版社(国家科学技术学术著作出版基金资助)
2019
[1] Huang C, Chen Y, Zhang S, Li L, Shui J, Liu Q. Integrating Water Observation from Space Product and Time-Series Flow Data for Modeling Spatio-Temporal Flood Inundation Dynamics. Remote Sensing, 2019. 11: 2535. DOI: 10.3390/rs11212535
[2] 邓诗凡,张智华,李想,吴倩鑫,张世强*. 城市老旧小区内外业一体化给水管线探测.地球物理学进展, 2019, 34(5): 1996–2001. DOI:10.6038/pg2019CC0346
[3] 吴倩鑫,马思煜,张智华,郭佳锴,张世强.五种降水产品在疏勒河上游山区和中下游月尺度降水的适用性对比研究,.冰川冻土, 2019, 41(2):470-482.
[4] Zhao Qiudong, Ding Yongjian*, Wang Jian, Gao Hongkai, Zhang Shiqiang*, Zhao Chuancheng, Xu Junli, Han Haidong, Shuangguan Donghui. Projecting climate change impacts on hydrological processes on the Tibetan Plateau with model calibration against the Glacier Inventory Data and observed streamflow, Journal of Hydrology, 2019, 573: 60-81. DOI: 10.1016/j.jhydrol.2019.03.043
[5] Zhang Zhihua, Deng Shifan, Zhao Qiudong*, Zhang Shiqiang*, Zhang Xiaowen. Projected glacier meltwater and river runoff changes in the upper reach of the Shule River Basin, northeastern edge of the Tibetan Plateau, Hydrological Processes, 2019, 33(7): 1059-1074. DOI: 10.1002/hyp.13384
[6] Ding Y, *Zhang S, Zhao L, Li Z, Kang S. Global warming weakening the inherent stability of glaciers and permafrost, Science Bulletin., 2019, 64 :245-253. DOI: 10.1016/j.scib.2018.12.028
[7] Wang G, Zhang X, *Zhang S. Performance of Three Reanalysis Precipitation Datasets over the Qinling-Daba Mountains, Eastern Fringe of Tibetan Plateau, China. Advance in Meteorology, 2019, Article ID:7698171, 16pages. DOI: 10.1155/2019/7698171
[8] He, Y., Jiang, X., Wang, N., Zhang, S., Ning, T., Zhao, Y., Hu, Y. Changes in mountainous runoff in three inland river basins in the arid Hexi Corridor, China, and its influencing factors. Sustainable Cities and Society, 2019,50:101703.
[9] 陈仁升,张世强,阳勇,刘俊峰,赵求东. 冰冻圈变化对中国西部寒区径流的影响,2019.. 北京:科学出版社
2018以前的代表论文:
[1] Chang Y, Qin D, Ding Y*, Zhao Q, Zhang S*. A modified MOD16 algorithm to estimate evapotranspiration over alpine meadow on the Tibetan Plateau, China. Journal of Hydrology, 2018, 561: 16-30. DOI: 10.1016/j.jhydrol.2018.03.054
[2] Qin, D., Ding, Y., Xiao, C., Kang, S., Ren, J., Yang, J., Zhang, S. Cryospheric Science: research framework and disciplinary system. National Science Review, 2018, 5(2), 255-268.
[3] Ma, S., Wu, Q., Wang, J., *Zhang, S. Temporal Evolution of Regional Drought Detected from GRACE TWSA and CCI SM in Yunnan Province, China. Remote Sensing, 2017, 9(11), 1124. https://doi.org/10.3390/rs9111124
[4] Wang, G., Zhang, P., Liang, L., *Zhang, S.. Evaluation of precipitation from CMORPH, GPCP-2, TRMM 3B43, GPCC, and ITPCAS with ground-based measurements in the Qinling-Daba Mountains, China. PLOS ONE, 2017, 12(10), e0185147. DOI: 10.1371/journal.pone.018514
[5] 种丹,李浩杰,范硕,李娇娇,王杰,张世强*.基于MODIS数据的云南九大高原湖泊叶绿素a浓度反演,生态学杂志,2017, 36(1):277-286
[6] 王戈飞,张佩云,梁枥文,王杰,*张世强. 地理信息系统与大数据的耦合应用.遥感信息, 2017, 32(4):146-151
[7] 张佩云,王凯,王戈飞,梁枥文,*张世强.毛乌素沙地中部地表水体1999-2015时空动态变化特征及驱动分析.干旱区地理, 2017, 40(3):633-639
[8] Chang Y, Ding Y, Zhao Q, Zhang S*. Remote estimation of terrestrial evapotranspiration by Landsat 5 TM and the SEBAL model in cold and high-altitude regions: A case study of the upper reach of the Shule River Basin, China. Hydrological Processes, 2017, 31(3): 514-524. DOI: 10.1002/hyp.10854.
[9] 丁永建,张世强,李新荣,赵文智. 西北地区生态变化评估报告。2017, 北京:科学出版社
[10] 丁永建,张世强,陈仁升. 寒区水文导论. 2017,北京:科学出版社
[11] 王杰,张世强,诸云强,彭建,曹言. 基于多源数据的云南土壤墒情监测技术研究。2017, 北京:中国水利水电出版社
[12] 苌亚平,张世强*,赵求东.高寒山区地表温度反演算法对比 —以疏勒河上游流域为例,遥感信息, 2016,31(4):122-128
[13] 李浩杰,种丹,范硕,张世强*,王杰, 近三十年云南九大高原湖泊水面面积遥感变化监测,长江流域资源与环境,2016,25(Z1):32-37
[14] Zhang SQ, Gao X, Zhang XW. Glacial runoff likely reached peak in the mountainous areas of the Shiyang River Basin, China. Journal of Mountain Science, 2015 12(2): 382-395. DOI: 10.1007/s11629-014-3077-2
[15] 丁永建,张世强,冰冻圈水循环在全球尺度的水文效应. 科学通报, 2015, 60(7): 593-602. DOI: 10.1360/N972014-00899
[16] 苌亚平,种丹,李浩杰,秦甲,张世强*. 基于 HJ-1B卫星数据的疏勒河上游流域地表温度反演.冰川冻土,2015,37(4):954-962
[17] 苌亚平,种丹,李浩杰,秦甲,张世强*. 基于 HJ-1B卫星数据的疏勒河上游流域地表温度反演.冰川冻土,2015, 37(4):954-962
[18] Xu Min, Ye baisheng, Zhao qiudong, Wang jian, Zhang Shiqiang*. ,Estimation of water balance in the source region of Yellow River based on GRACE satellite data, Journal of Arid land, 2013,5(3):384-395
[19] Zhang Shiqiang, Xu min, Xu junli, Zhao qiudong, Stefan Hagemann. Estimating the characteristics of runoff inflow into Lake Gojal in ungauged, highly glacierized upper Hunza River Basin, Pakistan. Journal of Earth Science,2013,24(2):234-243. DOI: 10.1007/s12583-013-0324-3
[20] Zhang Shiqiang , Gao,Xin Zhang Xiaowen, Stefan Hagemann. Projection of glacier runoff in Yarkant River basin and Beida River basin, western China. Hydrological Processes, 2012,26 (18):2773-2781. DOI: 10.1002/hyp.8373
[21] Zhang Shiqiang , Ye Baisheng, Liu Shiyin, Zhang Xiaowen, Stefan Hagemann,. A modified monthly degree-day model for evaluating glacier runoff changes in China. Part I: model development. Hydrological Processes, 2012,26(11): 1686-1696. DOI:10.1002/hyp.8286
[21]Zhang Shiqiang ,Xin Gao, Baisheng Ye, Xiaowen Zhang, Stefan Hagemann. A modified monthly degree-day model for evaluating glacier runoff changes in China. Part II: application Hydrological Processes, 2012, 26 (11) : 1697-1706. DOI:10.1002/hyp.8291
主要获奖
[1] 2016年 甘肃自然科学一等奖 寒区水文过程与机理研究,丁永建,叶柏生,张世强,陈仁升,上官冬辉
