姓名:吴雪娇
学历:博士
职称:教授
邮箱:xjwu@nwu.edu.cn
个人简介
黑龙江人,英国beat365官方网站入口教授,硕士生导师。2015年获中科院理学博士学位,2015.7-2023.2在中国科学院西北生态环境资源研究院工作,2023年3月调入beat365官方最新版工作。主要从事雪冰遥感与寒区水文过程模拟研究。近年来主持国家自然科学基金面上项目1项,国家自然科学基金青年基金1项,中国科学院西部之光青年学者B类项目1项,甘肃省自然科学基金自然基金1项,参加国家973项目、科技部重点研发计划、中科院A类先导专项、国家自然科学基金等项目十余项,公开发表论文30余篇,参编专著1部。任中国冰冻圈科学学会(筹)积雪专业委员会委员(2018-);中国冰冻圈科学学会(筹)女科学家委员会委员(2021-);担任《Geophysical Research Letters》、《Hydrological Processes》、《地理科学》、《冰川冻土》、《遥感技术与应用》等期刊审稿人学术职务。
欢迎具有遥感、测绘、地理信息科学、地理学等相关专业背景的同学报考。
主要课题
1.国家自然科学面上基金:温升背景下山区积雪加速消融机理及其融雪洪水效应(42071091),2021/1-2024/12,主持;
2.科技部青藏高原二次科考子专题:高原气候资料稀缺地区气候变化及其影响与应对(2019QZKK1001),2019/11-2022/10,主持;
3.甘肃省自然科学基金自然基金:祁连山雨雪混合型洪水灾害评估(20JR10RA029),2021/2-2023/3,主持;
4.冰冻圈科学国家重点实验室自主研究课题:干旱区积雪水文模拟研究(SKLCS-ZZ-2021),2021/1-2021/12,主持;
5.冰冻圈科学国家重点实验室自主研究课题:我国西北干旱区积雪水资源价值评估研究(SKLCS-ZZ-2019),2019/1-2019/12,主持;
6.国家自然科学青年基金:新疆阿尔泰山典型山区流域融雪径流模拟与预测研究(41701065),2018/1-2020/12,主持;
7.中科院西部之光-西部青年学者B类:阿尔泰山中段典型积雪流域融雪径流模拟与预测,2017/8-2019/12,主持。
8.科技部重点研发计划:融雪洪水灾害监测预警装置及立体检测技术研发(2019YFC1510502),2021/01-2024/11,参与;
9.中国科学院战略性先导科技专项(A类)联合攻关项目:气候变化影响下亚洲水塔变化及其影响与绿色发展方案(XDA20100305),2018/03-2023/2,参与;
10.中科院A类先导专项-地球大数据科学工程子课题-三极大数据共享与集成:三极环境大数据分析与发现(XDA19070100),2018/03-2023/2,参与;
11.国家自然科学基金委重大项目:中国冰冻圈服务功能形成过程及其综合区划研究:冻土和积雪的工程服役功能(41690144),2017/01-2021/12,参与;
12.科技部973项目: 2010CB951404,“北半球冰冻圈变化及其对气候环境的影响与适应对策”第四课题“冰冻圈变化的综合气候环境效应及我国的应对策略”,2010/01-2014/12,参与;
13.国家自然科学面上基金:新疆阿尔泰山两河源区冰冻圈资源价值核算及服务功能研究(41971083),2020/01-2023/12,参与;
14.国家自然科学面上基金:结合遥感数据的青藏高原典型流域季节性河冰春季径流贡献研究(41971399),2020/01-2023/12,参与。
主要成果
第一作者/通讯作者:
1.Wu X, ZhuR, Long Y, Zhang W*. (2022). Spatial trend and impact of snowmelt rate in spring across China’s three main stable snow cover regions over the past 40 years based on remote sensing. Remote Sensing, 14, 4176.https://doi.org/10.3390/rs14174176. (IF=5.349)(JCRQ1)
2.Wu X*, Zhang W, Li H, Long Y, Pan X, Shen Y. (2021). Analysis of seasonal snowmelt contribution using a distributed energy balance model for a river basin in the Altay Mountains of north-west China. Hydrological Processes, 35(3): 14046.https://doi.org/10.1002/hyp.14046. (IF=3.784)(JCRQ1)
3.Wu X*, Wang X, Liu S, Yang Y, Xu G, Xu Y, Jiang T, Xiao C. (2021). Snow cover loss compounding the future economic vulnerability of western China. Science of the Total Environment, 755(2021): 143025.https://doi.org/10.1016/j.scitotenv.2020.143025. (IF=10.753)(JCRQ1)
4.Wu X*, Shen Y, Zhang W, Long Y. (2020). Fast Warming Has Accelerated Snow Cover Loss during Spring and Summer across the Northern Hemisphere over the Past 52 Years (1967–2018). Atmosphere, 11(7): 728.https://doi.org/10.3390/atmos11070728. (IF=3.110)(JCRQ3)
5.Wu X, Che T*, Li X, Wang N, Yang X. (2018). Slower snowmelt in spring along with climate warming across the Northern Hemisphere. Geophysical Research Letters. 45(22): 12331-12339.https://doi.org/10.1029/2018GL079511. (IF=5.576)(JCRQ1 Top)(nature index)
6.Wu X*, Wang N, Shen Y, Pan X, Zhang W, He J, Wang G. (2016). Coupling the WRF model with a temperature index model based on remote sensing for snowmelt simulations in a river basin in the Altay Mountains, north-west China. Hydrological Processes. 30(21): 3967-3977.https://doi.org/10.3390/atmos11070728. (IF=3.784)(JCR Q1)
7.Wu X*, He J, JiangX, Wang N. (2016). Analysis of surface energy and mass balance in the accumulation zone of Qiyi Glacier, Tibetan Plateau in an ablation season. Environmental Earth Science. 75(9): 785.https://doi.org/10.1007/s12665-016-5591-8.(IF=3.119)(JCRQ3)
8.Wu X, Zhou Z*, Wang H, Li Y, Zhong B. (2015). Evaluation of irrigation water use efficiency using remote sensing in the middle reach of the Heihe river, in the semi-arid Northwestern China. Hydrological Processes. 29(9): 2243-2257.https://doi.org/10.1002/hyp.10365. (IF=3.784) (JCRQ1)
9.Wu X, Wang N*, Lu A, Pu J, Guo Z, Zhang H. (2015). Variations in albedo on Dongkemadi Glacier in Tanggula Range on the Tibetan Plateau during 2002-2012 and its linkage with mass balance. Arctic, Antarctic, and Alpine Research. 47(2): 71-82. DOI:http://dx.doi.org/10.1657/AAAR00C-13-307. (IF=1.880)(JCRQ4)
10.Wu X*, Wang N, Shen Y, He J, Zhang W. (2014). In-situ observations and modeling of spring snowmelt processes in an Altay Mountains river basin. Journal of Applied Remote Sensing. 8(1): 084697.https://doi.org/10.1117/1.JRS.8.084697. (IF=1.568)(JCRQ4)
11.Wu X*, Lu A, Wang L, Zhang H. (2011). Glacier change along wusong roadGlacier Change along WuSun Road in Chinese TienShan during 1973-2007 Monitored by Remote Sensing. IEEE. International Conference on Remote Sensing, Environment and Transportation Engineering.https://doi.org/10.1109/RSETE.2011.5964507. (EI)
12.吴雪娇,潘小多,沈永平*,张伟,贺建桥,贺斌(2016). WRF模式模拟的高空间分辨率空间气象数据的验证.冰川冻土. 38(2):332-340. (CSCD)
13.吴雪娇*,周剑,李妍,潘晓多,周彦召(2014).基于涡动验证的SEBS模型对黑河中游地表蒸散发的估算研究.冰川冻土. 36(6):1538-1547. (CSCD)
14.吴雪娇*,杨梅学,吴洪波,吴玉伟,王学佳(2013). TRMM多卫星降水数据在黑河流域的验证与应用.冰川冻土, 35(2):310-319.(CSCD)
15.吴雪娇,鲁安新*,王丽红,张华伟(2013).基于MODIS的长江源近10年积雪反照率时空分布及动态变化.地理科学, 33(3):371-377.(CSCD)
16.吴雪娇,鲁安新*,王丽红,张华伟(2011). 2001-2010年松木希错流域植被动态变化遥感研究.遥感技术与应用, 26(6):782-790.(CSCD)
其他作者:
1.Liu S, Qi J*, Liang S, Wang X,Wu X, Xiao C. (2022). Cascading costs of snow cover reduction trend in northern hemisphere. Science of the Total Environment. 806(2022): 150970.https://doi.org/10.1016/j.scitotenv.2021.150970.(IF=10.753)(JCRQ1)
2.Zhang W*, Wang X, Shen Y, Yang X, Wu Y, Chen A,Wu X, Liu S, Yang Y, Zhang J. (2021). Cryospheric water regime by its functions and services in China. Advances in Climate Change Research. 12(3): 430-443.https://doi.org/10.1016/j.accre.2021.05.008. (IF=4.746)(JCRQ2)
3.Yang Y,Wu X, Liu S, Xiao C, Wang X*. (2019). Valuating service loss of snow cover in Irtysh River Basin. Advances in Climate Change Research. 10(2019): 109-114.https://doi.org/10.1016/j.accre.2019.06.004.(IF=4.746)(JCRQ2)
4.Dai L, Che T*, Xie H,Wu X.(2018). Estimation of Snow Depth over the Qinghai-Tibetan Plateau Based on AMSR-E and MODIS Data. Remote Sensing. 10(12): 1989.https://doi.org/10.3390/rs10121989.(IF=5.349)(JCRQ2)
5.Guo Z, Wang N*, Wu H, Wu Y,Wu X, Li Q. (2015) Variations in firn line altitude and firn zone area on Qiyi Glacier, Qilian Mountains, over the period of 1990 to 2011. Arctic Antarctic and Alpine Research. 47(2): 293-300.https://doi.org/10.1657/AAAR00C-13-303. (IF=1.880)(JCRQ4)
6.Wang J, Wu X. (2010). An experimental comparison of ETM+ image geometric correction methods in the mountainous areas of Yunnan Province, China. Proc. SPIE 7840. Sixth International Symposium on Digital Earth: Models, Algorithms, and Virtual Reality, 784021.https://doi.org/10.1117/12.872968. (EI)
7.刘世伟,王晓明*,效存德,杨洋,吴雪娇. (2020)中国积雪气候调节服务价值评估.气候变化研究进展. 16(5): 536-544.(CSCD)
8.周剑*,吴雪娇,李红星,李妍,仲波,潘晓多.(2014)改进SEBS模型评价黑河中游灌溉水资源利用效率.水利学报,2014,45(12):1387-1398.
9.张伟,沈永平*,贺建桥,贺斌,吴雪娇,陈安安,李红德.(2014)额尔齐斯河源区森林对春季融雪过程的影响评估.冰川冻土, 36(05):1260-1270.
10.张伟,沈永平*,贺建桥,贺斌,努尔兰·哈再孜,吴雪娇,王国亚.(2014)阿尔泰山融雪期不同下垫面积雪特性观测与分析研究.冰川冻土, 36(03):491-499.
11.毛瑞娟*,吴红波,贺建桥,郭忠明,吴玉伟,吴雪娇.(2013)昆仑山木孜塔格冰川反照率变化特征及其与粉尘的关系.冰川冻土, 35(05):1133-1142.
12.张华伟*,童海刚,鲁安新,王丽红,吴雪娇.(2012)精河到伊宁公路沿线积雪及其影响.山地学报, 30(01):48-56.
13.张华伟*,鲁安新,王丽红,吴雪娇.(2011)祁连山地区气温和降水变化分析.甘肃联合大学学报(自然科学版), 25(05):34-40.
参编专著:
王宁练等.2023.祁连山水塔变化及其影响.科学出版社.