澳门金莎网址

澳门金莎网址

张世强

个人信息

姓名:张世强

学历:博士

职称:教授

邮箱:zhangsq@lzb.ac.cn

                           
个人简介

    张世强,教授,博士生导师,陕西省遥感与地理信息工程中心主任2003 年于武汉大学获得学博士学位2003-2013年在中国科学院寒区旱区环境与工程研究所工作,200611-2007.10 在英国帝国理工学院学术访问, 2010.10 - 2013.10德国马普气象研究所从事博士后项目研究2014年调入澳门大金沙乐娱场app工作,201412月入选陕西省“百人计划”全职项目。主要开展寒区流域系统中各要素及水循环的观测、遥感反演与模拟工作兼任冰冻圈学会冰冻圈水文专业委员会主任委员(2015- );中国地理学会干旱区委员会主任委员(2019- );CNC-IAHS 冰雪水文分委会(2019- ;《冰川冻土》编委(2020- )。

主要成果

(一)代表性科研项目

1.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

2.国家自然科学基金重点项目 “西北内陆河山区流域水文内循环过程及机理研究” 课题 (41730751-1),2018.1-2022.12,主持

3.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

4.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

5.国家自然科学基金面上项目:“长江源区季节雪盖对多年冻土活动层水热输运过程的影响研究”(40671041),2007.1-2009.12, 主持

6.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,排名第2。

7.科技部超级973项目“冰冻圈变化及其影响研究”课题6“寒区流域水文过程综合模拟与预估研究”(2013CBA01806),2013.1-2017.8,第2负责人    

8.陕西省留学归国择优项目“气候变化和人类活动对渭河流域水文过程和水资源的影响与适应”,2016.1-2017.10,主持

9.中国科学院STS计划项目“西北地区过去六十年生态变化评估”(KFJ-EW-STS-004-2)课题,2014.5-2016.12,主持

10.全球变化研究国家重大科学研究计划项目课题4:“冰冻圈变化的综合气候环境效应及我国的应对策略”(2010CB951404)专题: “冰冻圈水文过程模拟”, 2010-2014,

11. 973项目课题2 “干旱区典型流域冰冻圈水文过程模拟及水资源变化预测”(2007CB411502)专题“干旱区典型流域冰冻圈水文过程模拟”,2007-2011,主持

12.水利部行业专项项目“云南高原湖泊水资源地面-遥感监测技术研究”(201401026)课题,2014-2016, 主持

13.云南省科技厅社会事业项目“基于多源数据的土壤墒情监测关键技术在抗旱测报中的应用研究”(2012CA021)课题, 2013-2015, 主持

14.冰冻圈国家重点实验室自主课题“疏勒河山区流域水量平衡观测试验与模拟研究”(SKLCS-ZZ-2010-02),2011-2012,主持

15.公益性行业(水利)科研专项项目“西部冰川水资源及其变化评估的关键技术研究”(2007SHZ1046),2008 - 2011, 执行负责

16.中国科学院重要方向项目“西部冰川变化监测及其影响评估方法研究”第2课题“冰川储量估算与冰川参数遥感提取精度评估”(kzcx2-yw-301-2),2007-2010, 主持

17.公益性行业(气象)科研专项项目“中国冰冻圈卫星监测关键技术研究及系统开发” (GYHY200706018)课题“冰川参数提取关键技术研究” 2008-2011, 主持

18.黄河勘查设计公司“南水北调西线第一期工程雅砻江干流调水河段产汇流特性与变化规律研究”项目, 2006.1-10 ,主持

19.三峡梯调中心委托项目“135水位梯级水库调度中长期水文气象预报业务系统建设” 课题“长江上游流域数值化降水预报制作系统”,2004-2005,主持

20.黄河勘查设计公司“南水北调西线第一期工程各调水河段产汇流特性与变化规律研究”项目,2003-2004,  执行负责

(二)代表性论著

2020年

[1]Ma, S., Zhang S*, Wu Q, Wang J. 2020. Long-term Changes in Surface Soil Moisture Based on CCI SM in Yunnan Province, Southwestern China. Journal of hydrology. DOI: 10.1016/j.jhydrol.2020.125083

[2]李哲,丁永建,陈艾娇,张智华,张世强,2020. 西北地区1960-2019年气候变化中的Hiatus现象及其特征研究, 地理学报(待刊)

[3]Liu, Q.; Huang, C.; Shi, Z.; Zhang, S, 2020. Probabilistic River Water Mapping from Landsat-8 Using the Support Vector Machine Method. Remote Sens.  12, 1374.

[4]丁永建,张世强,陈仁升,2020. 冰冻圈水文学:解密地球最大淡水库. 中国科学院院刊,35(4):393-403. DOI: 10.16418/j.issn.1000-3045. 20200302002

[5]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

[6]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.

2019年

[1]Huang C, Chen Y, Zhang S, Li L, Shui J, Liu Q. 2019. Integrating Water Observation from Space Product and Time-Series Flow Data for Modeling Spatio-Temporal Flood Inundation Dynamics. Remote Sensing, 11: 2535. DOI: 10.3390/rs11212535

[2]邓诗凡,张智华,李想,吴倩鑫,张世强*, 2019. 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, 34(5): 1996–2001 , DOI:10.6038/pg2019CC0346

[3]吴倩鑫,马思煜,张智华,郭佳锴,张世强, 2019. .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41(2):470-482.

[4]Zhao Qiudong, Ding Yongjian*, Wang Jian, Gao Hongkai, Zhang Shiqiang*, Zhao Chuancheng, Xu Junli, Han Haidong, Shuangguan Donghui, 2019.  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, 573: 60-81. DOI: 10.1016/j.jhydrol.2019.03.043

[5]Zhang Zhihua, Deng Shifan, Zhao Qiudong*, Zhang Shiqiang*, Zhang Xiaowen, 2019. Projected glacier meltwater and river runoff changes in the upper reach of the Shule River Basin, northeastern edge of the Tibetan Plateau, Hydrological Processes,33(7):  1059-1074.  DOI: 10.1002/hyp.13384

[6]李想,张世强*,梁倩,2019. 小型四旋翼无人机序列影像三维重建实验研究. 遥感信息

[7]Ding Y, *Zhang S, Zhao L, Li Z, Kang S, 2019. Global warming weakening the inherent stability of glaciers and permafrost, Science Bulletin. 64(2019):245-253. DOI: 10.1016/j.scib.2018.12.028

[8]Wang G, Zhang X, *Zhang S. 2019. 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

2018年

[1]丁永建,张世强, 2018.西北内陆河山区流域内循环过程与机理研究: 现状与挑战.地球科学进展, 33( 7) : 719-727.DOI: 10.11867 /j.issn.1001- 8166.2018.07.0719

[2]Zhang, X., Li, H., Zhang, Z., Wu, Q., Zhang, S*. 2018. Recent Glacier Mass Balance and Area Changes from DEMs and Landsat Images in Upper Reach of Shule River Basin, Northeastern Edge of Tibetan Plateau during 2000 to 2015. Water, 10(6), 796; doi:10.3390/w10060796

[3]Huang C, Chen Y, Zhang S, Wu J., 2018. Detecting, Extracting, and Monitoring Surface Water from Space Using Optical Sensors: A Review. Reviews of Geophysics, 56,333-360. DOI: 10.1029/2018RG000598

[4]Chang Y, Qin D, Ding Y*, Zhao Q, Zhang S*. 2018. A modified MOD16 algorithm to estimate evapotranspiration over alpine meadow on the Tibetan Plateau, China. Journal of Hydrology, 561: 16-30.  DOI: 10.1016/j.jhydrol.2018.03.054    

[5]Qin, D., Ding, Y., Xiao, C., Kang, S., Ren, J., Yang, J., Zhang, S. 2018. Cryospheric Science: research framework and disciplinary system. National Science Review, 5(2), 255-268.

[6]种丹,张世强,李浩杰,李姣姣, 2018. 基于光学遥感的湖泊水体信息提取研究进展.人民黄河, 40(3):49-53+75.

2017年

[1]Ma, S., Wu, Q., Wang, J., *Zhang, S. 2017. Temporal Evolution of Regional Drought Detected from GRACE TWSA and CCI SM in Yunnan Province, China. Remote Sensing, 9(11), 1124. https://doi.org/10.3390/rs9111124

[2]Chang, Y., Wang, J., Qin, D., Ding, Y., Zhao, Q., Liu, F., *Zhang, S., 2017. Methodological comparison of alpine meadow evapotranspiration on the Tibetan Plateau, China. PLOS one, 12(12), e0189059. DOI:10.1371/journal.pone.0189059

[3]Wang, G., Zhang, P., Liang, L., *Zhang, S., 2017. Evaluation of precipitation from CMORPH, GPCP-2, TRMM 3B43, GPCC, and ITPCAS with ground-based measurements in the Qinling-Daba Mountains, China. PloS one, 12(10), e0185147. DOI: 10.1371/journal.pone.0185147

[4]Huang, C., Chen, Y., Zhang, S., Li, L., Shi, K., Liu, R., 2017. Spatial Downscaling of Suomi NPP–VIIRS Image for Lake Mapping. Water, 9(11), 834.

[5]Huang C, Nguyen BD, Zhang S, Cao S, Wagner W. 2017. A Comparison of Terrain Indices toward Their Ability in Assisting Surface Water Mapping from Sentinel-1 Data. International Journal of Geo-Information, 6: 140. doi:10.3390/ijgi6050140

[6]种丹,李浩杰,范硕,李娇娇,王杰,张世强*,2017.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,36(1):277-286

[7]王戈飞,张佩云,梁枥文,王杰,*张世强, 2017. 地理信息系统与大数据的耦合应用[J].遥感信息, 32(4):146-151

[8]张佩云,王凯,王戈飞,梁枥文,*张世强, 2017..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, 40(3):633-639

[9]李姣姣,种丹,李浩杰,范硕,*张世强, 2017. 云南省渔洞水库山区流域降雨径流过程模拟.山东农业大学学报(自然科学版), ,48(1):56-63.

[10]Chang Y, Ding Y, Zhao Q, Zhang S*, 2017. 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, 31(3): 514-524. DOI: 10.1002/hyp.10854.

2016年

[1]Huang Chang, Chen Yun, Zhang Shiqiang, Li Linyi,Shi Kaifang, Liu Rui.2016. Surface water mapping from Suomi NPP-VIIRS imagery at 30m resolution via blending with Landsat data. Remote Sensing, 8,631. DOI: 10.3390/rs8080631

[2]Muhammad Naveed Anjum, Yongjian Ding, Donghui Shangguan, Muhammad Wajid Ijaz, and Shiqiang Zhang, 2016. Evaluation of High-Resolution Satellite-Based Real-Time and Post-Real-Time Precipitation Estimates during 2010 Extreme Flood Event in Swat River Basin, Hindukush Region, Advances in Meteorology, vol. 2016, Article ID 2604980, 8 pages, doi:10.1155/2016/2604980

[3]Wang W, Rinke A, Moore JC, Cui X, Ji D, Li Q, Zhang N, Wang C, Zhang S, Lawrence DM, McGuire AD, Zhang W, Delire C, Koven C, Saito K, MacDougall A, Burke E, Decharme B. 2016. Diagnostic and model dependent uncertainty of simulated Tibetan permafrost area. The Cryosphere, 10: 287-306. DOI: 10.5194/tc-10-287-2016.

[4]Zhang Xiaowen, Zhang Shiqiang, Xu Junli, 2016. Glacier stagnant in central Karakorum during 2003 to 2008 derived from DEOS Mass Transport Model GRACE data and one monthly degree-day model, Proc. SPIE 9998, Remote Sensing for Agriculture, Ecosystems, and Hydrology XVIII, 999806 (October 25, 2016); doi:10.1117/12.2235582

[5]Zhao, L., Wang, L., Cernusak, L. A., Liu, X., Xiao, H., Zhou, M., Zhang, S., 2016. Significant difference in hydrogen isotope composition between xylem and tissue water in Populus euphratica. Plant, cell & environment, 39(8), 1848-1857.

[6]Peng J, Loew A, Zhang S, Wang J., 2016. Spatial Downscaling of Satellite Soil Moisture Data Using a Vegetation Temperature Condition Index. IEEE Transactions on Geoscience and Remote Sensing, 54(1):558-566. DOI: 10.1109/TGRS.2015.2462074

[7]Yongjian Ding, Shiqiang Zhang, Fengjing Liu, Daqing Yang, Chansheng He, Svetlana Stuefer, 2016, Hydrometeorological Observation and Study in High Altitude Area,”Advances in Meteorology, Article ID 1372464, 2 pages, 2016. doi:10.1155/2016/1372464

[8]苌亚平,张世强*,赵求东.2016,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,31(4):122-128

[9]李浩杰,种丹,范硕,张世强*,王杰,2016, 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,25(Z1):32-37

2015年

[1]Zhang SQ, Gao X, Zhang XW , 2015. Glacial runoff likely reached peak in the mountainous areas of the Shiyang River Basin, China. Journal of Mountain Science 12(2), 382-395  DOI: 10.1007/s11629-014-3077-2  

[2]丁永建,张世强,2015. 冰冻圈水循环在全球尺度的水文效应. 科学通报, 60(7): 593-602. DOI: 10.1360/N972014-00899

[3]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

[4]Qiudong Zhao, Shiqiang Zhang, Yong jian Ding,Jian Wang,  Haidong Han, Junli Xu, 2015.  Modeling hydrologic response to climate change and shrinking glaciers in the highly glacierized Kunma Like River catchment, Central Tian Shan Mountains, Journal of Hydrometeorology, 16: 2383-2402  DOI: 10.1175/JHM-D-14-0231.1

[5]Peng jian, Jonathan Niesel, Lowe Alexander, Zhang Shiqiang, Wang Jie, 2015.  Evaluation of Satellite and Reanalysis Soil Moisture Products over Southwest China Using Ground-Based Measurements ,  Remote Sens.  7, 15729-15747. DOIi:10.3390/rs71115729

[6]Chuancheng Zhao, Shuxia Yao, Shiqiang Zhang, Haidong Han, Qiudong Zhao, and Shuhua Yi, 2015. Validation of the Accuracy of Different Precipitation Datasets over Tianshan Mountainous Area, Advances in Meteorology, vol. 2015, Article ID 617382, 10 pages, 2015. DOI::10.1155/2015/617382

[7]Jin-kui Wu, Shiqiang Zhang, Hao Wu, Shi-wei Liu, Yu Qin, and Jia Qin, 2015. Actual Evapotranspiration in Suli Alpine Meadow in Northeastern Edge of Qinghai-Tibet Plateau, China, Advances in Meteorology, Article ID 593649, 10 pages, 2015. doi:10.1155/2015/593649

[8]苌亚平,种丹,李浩杰,秦甲,张世强*,2015. 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,37(4):954-962

2014年

[1]苌亚平,*张世强,2014. 2001—2010年河南省县域农业生产效率动态分析,中国农学通报,30(29): 87-94

[2]Wang J, Han H, Zhang S, 2014. Carbon dioxide flux in the ablation area of Koxkar glacier, western Tien Shan, China. Annals of Glaciology 55(66): 231-238.

[3]许民,张世强,王建,赵求东,赵传成,2014. 利用GRACE重力卫星监测祁连山水储量时空变化,干旱区地理, 37(3):458-467

[4]丁永建, 张世强, 韩添丁, 南卓铜. 2014. 由地表过程向地表系统科学研究跨越的机遇与挑战. 地球科学进展,29(4): 443-455.

2013年

[1]Xu junli, Liu shiyin, Zhang shiqiang*, Guo wanqin, Wang jian, Recent changes in glacial area and volume on Tuanjiefeng Peak region of Qilian Mountains, China, PLOS ONE,2013, 8(8): e70574. DOI:10.1371/journal.pone.0070574

[2]Xu Min, Ye baisheng, Zhao qiudong, Wang jian, Zhang Shiqiang*, 2013. ,Estimation of water balance in the source region of Yellow River based on GRACE satellite data, Journal of Arid land, 5(3):384-395  

[3]Wu zhen, Zhang shiqiang*, Liu shiyin, 2013. Optimal antenna of ground penetrating radar for depicting the debris thickness and structure of the Koxkar Glacier, Tian shan, China, Journal of Earth Science, 24(5):830-842

[4]Zhang Shiqiang, Xu min, Xu junli, Zhao qiudong, Stefan Hagemann, 2013. Estimating the characteristics of runoff inflow into Lake Gojal in ungauged, highly glacierized upper Hunza River Basin, Pakistan. Journal of Earth Science, 24(2):234-243. DOI: 10.1007/s12583-013-0324-3

[5]Wu Z, Liu S, Zhang S, Shangguan D. 2013. Accelerated thinning of Hei Valley No. 8 Glacier in the Tianshan Mountains, China. Journal of Earth Science, 24: 1044-1055.

[6]Wu Z, Liu S, Zhang S, Xiao H, 2013. Internal structure and trend of glacier change assessed by geophysical investigations. Environmental Earth Sciences, 68, 1513-1525. DOI:10.1007/s12665-01201845-2

[7]Zhao Q.D,, B. S. Ye, Y. J. Ding, S. Q. Zhang, S. H, Yi,  J. Wang, D. H, Shangguan, H. D. Han, 2013. Coupling a glacier melt model to the Variable Infiltration Capacity (VIC) model for hydrological modeling, Environmental Earth Sciences, 68(1):87-101 DOI: 10.1007/s12665-01201718-8.

[8]Xie Zunyi, Shangguan Donghui, Zhang Shiqiang, Ding Yongjian, Liu Shiyin, 2013. Index for hazard of glacier lake outburst flood of lake Merzbacher by satellite-based monitoring of lake area and ice cover, Global and Planetary Change, 107: 229-237. DOI:10.1016/j.gloplacha.2012.05.025  

[9]丁永建, 周成虎, 邵明安, 陈亚宁, 张甘霖, 张世强, 韩添丁, 南卓铜. 2013. 地表过程研究进展与趋势. 地球科学进展, 28: 407-419.

[10]吴锦奎, 陈军武, 吴灏, 张世强, 高明杰, 秦彧,. 2013. 疏勒河上游高寒草甸蒸散对比研究. 地理科学, 33: 97-103.

2012年

[1]Zhang Shiqiang , Gao,Xin Zhang Xiaowen, Stefan Hagemann., 2012. Projection of glacier runoff in Yarkant River basin and Beida River basin, western China. Hydrological Processes, 26 (18), 2773-2781. DOI: 10.1002/hyp.8373

[2]Zhang Shiqiang , Ye Baisheng, Liu Shiyin, Zhang Xiaowen, Stefan Hagemann,. 2012. A modified monthly degree-day model for evaluating glacier runoff changes in China. Part I: model development. Hydrological Processes, 26(11), 1686-1696. doi :10.1002/hyp.8286

[3]Zhang Shiqiang ,Xin Gao, Baisheng Ye, Xiaowen Zhang, Stefan Hagemann, 2012. A modified monthly degree-day model for evaluating glacier runoff changes in China. Part II: application Hydrological Processes, 26 (11) ,1697-1706.  doi:10.1002/hyp.8291

[4]Zhang Xiaowen, Zhang shiqiang*, 2012. Exploring effects of rainfall intensity on soil erosion at the catmint scale using modified SEMMED model at the Zuli River Basin, western Loess Plateau, China, 2012 IEEE International Geoscience and Remote Sensing Symposium Proceedings,690-694

[5]曹飞凤,严齐斌,张世强*,2012. 改进的SCEM-UA算法在概念性降雨-径流模型参数中的应用,系统工程理论与实践, 32(6): 1362-1368

[6]张小文,晏玲,张世强,2012. 长江源区未来气候变化情景降尺度,兰州大学学报(自然科学版),48(2),29-35

2011年

[1]高鑫,张世强*,叶柏生,高红凯,2011.河西内陆河流域冰川融水近期变化,水科学进展, 22(3):50-56

[2]曹飞凤,张世强*,许月萍,楼章华,2011.基于SCEM-UA算法和全局敏感性分析的水文模型参数优选不确定性研究,中山大学学报(自然科学版),50(2):48-54

[3]谢遵义,张世强*,张小文,谯程俊,杨晓红,2011. 基于GIS的冰川动力学模型部分参数自动提取研究,冰川冻土,33(3):519-523

[4]张世强,晏玲,谢遵义,杨晓红,2011.长江源区全球气候模式评估与未来气候情景预估,戴长雷,吴敏,李治军,杜绍敏主编,2010年中国水论坛No.8, ,哈尔滨,水利水电出版社,237-240

[5]Zhao Q.D,, B. S. Ye, Y. J. Ding, S. Q. Zhang, C. C, Zhao, . J. Wang, Z. R. Wang, 2011. Simulation and analysis of river runoff in typical cold regions, Sciences in Cold and Arid Regions, 3(6):498-508. DOI: 10.3724/SP.J.1226.2011.00498.

[6]Xie zunyi,Donghui ShangGuan,Shiqiang Zhang,Qi Zhang,Jia Qin,Yongquan Zhang, 2011, Method for quickly delineating Merzbacher Lake extent based on Environment and Disaster Monitoring Small Satellite images, 2011 International Conference on Remote Sensing, Environment and Transportation Engineering (RSETE), 2011.6.24-26,Nanjing, 2258-2262 DOI 10.1109/RSETE.2011.5964760

[7]武震,张世强,刘时银,杜文涛,2011. 祁连山老虎沟12号冰川冰内结构特征分析,地球科学进展,26(6):631-641

[8]许君利,张世强,韩海东,刘时银,张盈松,2011. 天山托木尔峰科其喀尔巴西冰川表面运动速度特征分析,冰川冻土,33(2):268-275

[9]张小文,张世强,陈良华,冯敏,2011. 长江三峡库区以上地区数值化降水预报系统的设计及实现,遥感技术与应用,26(5):632-639

[10]王杰,叶柏生,张世强,李静,吴锦奎,周兆叶, 2011. 祁连山疏勒河上游高寒草甸CO2通量变化特征. 冰川冻土,33(3):646-653

[11]赵求东,叶柏生,丁永建,张世强,上官冬辉,赵传成,王建,王增如, 2011. 典型寒区流域水文过程模拟及分析. 冰川冻土, 33(3):595-605

2010年及以前

[1]Gao xin, Ye baisheng, Zhang shiqiang, Qiao chengjun, Zhang xiaowen, 2010. Glacier melt water change and impact on Tarim River during 1961-2000, Science in China Series D: Earth Science, 53(6), 880-891[高鑫,叶柏生,张世强,谯程俊,张小文,2010, 1961-2006年塔里木河流域冰川融水变化及其对径流的影响,中国科学(D),40(5),654-665]

[2]Feng Min, Zhang shiqiang, Gaoxin, 2010. Glacier Runoff Models sharing Service and Online Simulation, Second International Conference on Advanced Geographic Information Systems, Applications, and Services (GEOPROCESSING),123-126  DOI: 10.1109/GEOProcessing.2010.26  

[3]高鑫,张世强,叶柏生,谯程俊,2010,1961-2006年叶尔羌河上游流域冰川融水变化及其对径流的影响,冰川冻土,32(3),446-453

[4]王建,许君利,张世强,刘时银,韩海东,2010,天山南坡科其喀尔冰川流域水化学侵蚀及大气CO2沉降量分析,环境科学,31(4),903-910

[5]余蓬春,刘时银,杨萍,张世强,吴立宗,郭万钦,2010,基于可变窗分析的中国云贵高原地区SRTM DEM数据填补方法研究,云南大学学报(自然科学版),3,273-279

[6]Zhang xiaowen,, Zhangshiqiang, 2009. An improved method for mapping debris-covered glaciers with satellite multispectral image data and digital elevation model, 2009 IEEE International Geoscience and Remote Sensing Symposium Proceedings, III, 635-638

[7]Zhang shiqiang, Zhang xiaowen, 2009, Evaluation of glacier runoff in Tailan basin by monthly degree-day model, 2009 IEEE International Geoscience and Remote Sensing Symposium Proceedings, II, 582-585

[8]晏玲, 张世强, 张小文. 2009, 气象水文耦合的三峡水库入库水量预报研究, 人民长江, 40(24) :29-33.

[9]武震,刘时银,张世强,2009,祁连山老虎沟12号冰川冰下形态特征分析, 地球科学进展,24(10):1149-1158

[10]武震,张世强,张小文,2008,流域水文模型参数识别的现代优化方法研究进展,冰川冻土,30(1):64-71

[11]张小文,张世强,蔡迪花,张延平,孙雪英,2008,黄土高原西部不同土地利用与土壤侵蚀的相互作用,兰州大学学报(自然科学版),2,9-14

[12]上官东辉,刘时银,丁良福,张世强,李刚,张勇,李晶,2008,1970-2000年念青唐古拉山脉西段冰川变化,冰川冻土,30(2)204-210

[13]焦明,张世强,刘勇,张培栋,张小文,2007,基于“3S”技术的甘肃子午岭自然保护区土地利用变化研究,草业科学,24(11)14-17

[14]武震,张世强,丁永建,2007,水文系统模拟不确定性研究进展,中国沙漠,27(5),890-896

[15] 贾志裕,鲁安新, 焦明,张小文,张世强,王丽红,赵永国;,喻林青,2008,川藏公路灾害信息系统特征与实现,遥感技术与应用,6,705-711

[16]蓝永超,沈永平,林纾,张世强,畅俊杰,2007, 黄河上游径流丰枯变化特征及其环流背景,冰川冻土, 28(6),950-955

[17]Shangguan donghui, Liu shiyin, Ding yongjian, Ding liangfu, Xiong libing, Cai dihua, Li gang, Lu anxin, Zhang shiqiang, Zhang yong, 2006, Monitoring the glacier changes in the Muztag Ata and Konggur mountains, east Pamirs, based on Chinese Glacier Inventory and recent satellite imagery, Annuals of Glaciology, 43(1): 79-85

[18]Zhang shiqiang, Ding yongjian, Ye baisheng, 2006, The monthly discharge simulation/construction on upper Yangtze River with absent or poor data Coverage, Liu Zhiyu & Yang Dawen edit, Proceedings of the international symposium on flood forecasting and water resources assessment for IAHS-PUB, 324-333

[19]陈书林,马金辉,张世强,鲁安新,赵永国,2006,基于组件GIS的川藏公路西藏境灾害信息系统设计与开发,遥感技术与应用,21(4):359-362

[20]喻林青; 鲁安新; 冉德甫; 王丽红; 张世强,2006,国道214线西藏境滑塌灾害遥感调查研究,遥感技术与应用,6,517-520

[21]冉德甫 ,鲁安新 ,张世强 ,王丽红, 2006, 国道214 线西藏段地质灾害遥感调查与评价, 水文地质工程地质, 1,88-91

[22]许君丽,刘时银,张世强,上官东辉,2006,塔里木盆地南缘喀拉米兰河-克里雅河流内流区近30a来的冰川变化研究,冰川冻土,28(3):1-7

[23]雷鸣,宋伟华,张世强,2006,缺资料地区设计径流插补方法对比分析研究,甘肃科技,22(4):115-116

[24]Zhang shiqiang, Ding yongjian, Liu shiyin, Zhang xiaowen, Comparing hydrological characters of ungauged area via RS, GIS and observation,2005 IEEE International Geoscience and Remote Sensing Symposium Proceedings,4461-4464

[25]上官冬辉 ,刘时银, 丁永建 ,丁良福, 沈永平, 张世强 ,鲁安新, 李刚 ,蔡迪花 ,张勇,2005,利用ASTER影像对慕士塔格-公格尔山冰川解译与目录编制,冰川冻土,27(3):344-351

[26]张世强,丁永建,卢健,刘时银,2005,青藏高原土壤水热过程模拟(Ⅲ):蒸发量、短波辐射与净辐射通量,冰川冻土,27(5):645-648

[27]张世强,丁永建,卢健,刘时银,2005,青藏高原土壤水热过程模拟(II):土壤温度,冰川冻土,27(1):95-99

[28]Zhang shiqiang, Ding yongjian, Liu shiyin, Zhang xiaowen, Cai dihua, Estimation potential consequences of climate change for water resource via RS, GIS and hydrology model,2004, 2004 IEEE International Geoscience and Remote Sensing Symposium Proceedings: Science for Society: Exploring and Managing a Changing Planet. IGARSS 2004, 4877-4880

[29]王丽红,张世强,鲁安新,2004,基于RS与GIS技术的川西高原土地利用/覆盖现状调查研究,遥感技术与应用,19(5):328-333

[30]张世强,丁永建,卢健,刘时银,2004,青藏高原土壤水热过程模拟(I):土壤湿度,冰川冻土,26(4):384-388

[31]丁永建,杨建平,刘时银,陈仁升,王根绪,沈永平,王建,谢昌卫,张世强,2003,长江黄河源区生态环境范围的探讨,地理学报, 58(4):519-526

[32]Zhang shiqiang, Lu jian, Liu shiyin, Zeng yongnian, Evaluation of the utility of  sub-pixel analysis of thematic mapper imagery of serious soil degradation in the Yellow  River source regions, Ecosystems dynamics,Ecosystem-society interactions, and Remote Sensing applications for semi-arid and arid land, 2003, Proceedings of SPIE, 4890: 634 -643

[33]Zhou Shangzhe, Jiao Keqin, Zhao Jingdong, Zhang Shiqiang, Cui Jianxin, Xu Liubing, 2002 , Geomorphology of the Urümqi River Valley and the uplift of the Tianshan Mountains in Quaternary,Science In China(Series D),  45(11) : 961-968 [周尚哲,焦克勤, 赵井东,张世强,崔建新, 许刘兵, 2002,乌鲁木齐河河谷地貌与天山第四纪抬升研究,中国科学(D辑), 32 (2) :157-162]

[34]Zhou Shangzhe,Li Jijun ,Zhang Shiqiang, 2002 , Quaternary glaciation of the bailing river valley, Qilian Shan. Quaternary International, 97-98, 103-110

[35]张小文,刘勇,潘小多,张世强, 2002,交通地理信息系统的类型、方法及应用初探,遥感技术与应用, 17(6):244-251

[36]张世强,卢建,刘时银, 2001,利用TM高光谱图像提取青藏高原喀喇昆仑山区现代冰川边界,武汉大学学报(信息版), 26(5): 435-440

[37]张世强,卢建,刘时银, 2001,陆地冰川的遥感研究,中国遥感奋进创新二十年学术论文集,北京,气象出版社,329-333

[38]张世强,邹松兵,刘勇,2000 , 基于MapObjects 的GIS 应用开发浅析,遥感技术与应用, 15(3),194-198

参编专著:
[1]丁永建,张世强,陈仁升,2020.冰冻圈水文学. 北京:科学出版社

[2]陈仁升,张世强,阳勇,刘俊峰,赵求东,2019. 冰冻圈变化对中国西部寒区径流的影响。北京:科学出版社

[3]丁永建,张世强,李新荣,赵文智,2017. 西北地区生态变化评估报告。北京:科学出版社

[4]丁永建,张世强,陈仁升,2017. 寒区水文导论。北京:科学出版社

[5]王杰,张世强,诸云强,彭建,曹言,2017. 基于多源数据的云南土壤墒情监测技术研究。 北京:中国水利水电出版社

[6]Yongjian Ding, Mu Mu, Jianyun Zhang, Tong Jiang, Tingjun Zhang, Chunyi Wang, Lixin Wu, Baisheng Ye, Manzhu Bao, Shiqiang Zhang, Impacts of Climate Change on the Environment, Economy, and Society of China, In: Qin Dahe, Ding Yongjian, Mu Mu eds, Climate and Environmental, Change in China: 1951–2012, Springer, 2016

软件著作权:
      2010中国西部冰川融水评估平台1.0, 软件著作权登记证书(No.2010SR002605)。

获奖情况:

    甘肃省2015年自然科学一等奖,寒区水文过程与机理研究. 排名第三