利用中国科学院珠穆朗玛大气与环境综合观测站(下称珠峰站)的观测资料, 初步分析了2008-2011年珠穆朗玛峰北坡气温、 降水、 水面蒸发和土壤温湿度等水文和气象要素的变化特征, 并以2010年绒布河实测流量为例, 分析了气温和降水变化对径流的影响。结果表明, 2008-2011年珠峰站的年平均气温为4.3 ℃, 冬半年气温日较差大于夏半年; 年降水量为203.4 m且集中在7、 8月, 年际变化较大; 水面蒸发为2 459 mm, 夏季高于冬季, 6月最大; 绒布河流量在整个消融期(4-10月)受气温影响显著, 无降水日气温与流量之间有较好的正相关关系, 反映了气温对冰川消融的影响; 降水事件当日对应的径流减少, 特别是10 mm以下的降水量与当日流量呈负相关关系, 这与冰川区降水常伴随降温, 又主要为固态, 进而对冰川消融和径流有抑制作用有关。
The characteristics of air temperature, precipitation, water surface evaporation, soil temperature and soil moisture have been analyzed using the observational data from 2008 to 2011 at Qomolangma station for Atmospheric and Environmental Observation and Research, Chinese Academy of Sciences. A brief results of the influence of the air temperature and precipitation on runoff have been analyzed using the measured data at gauging station in Rongbuk River during ablation period in 2010. Annual mean air temperature at Qomolangma station is 4.3 ℃, the daily temperature range of air temperatures in winter half year is greater than that in summer half year. Average annual precipitation is 213.4 mm, which concentrates in July and August, its interannual variation is large. Annual water surface evaporation is 2 104 mm, and it is larger in summer than in winter, the largest water surface evaporation happen in June. During ablation period of Rongbuk River runoff, the air temperature dominates runoff and they have a good positive correlation. Precipitation can reduce runoff on the same day, especially the precipitation smaller than 10 mm has apparent negative impact on runoff on the same day.
[1]杨继超, 张镱锂, 张玮, 等. 珠穆朗玛峰地区近34年来气候变化[J]. 地理学报, 2006, 61(7): 688-695.
[2]张东启, 效存德, 刘伟刚. 喜马拉雅山区1951-2010年气候变化事实分析[J]. 气候变化研究进展, 2012, 8(2): 110-117.
[3]Ren Jiawen, Qin Dahe, Kang Shichang, et al. Glacier variations and climatic warming and drying in the central Himalayas[J]. Chinese Sci Bull, 2004, 49(1): 65-69.
[4]Hou Shugui,Qin Dahe,Wake C P, et al. Climatological significance of an ice core net-accumulation record at Mt. Qomolangma (Everest)[J]. Chinese Sci Bull, 2000, 45(3):259-263.
[5]刘辉志, 冯健武, 邹捍, 等. 青藏高原珠峰绒布河谷地区近地层湍流输送特征[J]. 高原气象, 2007, 26(6): 1151-1161.
[6]孙方林, 马耀明. 珠穆朗玛峰北坡地区河谷局地环流特征观测分析[J]. 高原气象, 2007, 26(6): 1187-1190.
[7]邹捍, 周立波, 马舒坡, 等. 珠穆朗玛峰北坡局地环流日变化的观测研究[J]. 高原气象, 2007, 26(6): 1123-1140.
[8]马伟强, 戴有学, 马耀明, 等. 珠峰北坡地区地表辐射和能量季节变化的初步分析[J]. 高原气象, 2007, 26(6): 1237-1243.
[9]张美根, 马舒坡, 许丽人, 等. 珠峰北坡绒布河谷局地环流的模拟分析[J]. 高原气象, 2007, 26(6): 1146-1150.
[10]李茂善, 戴有学, 马耀明, 等. 珠峰地区大气边界层结构及近地层能量交换研究[J]. 高原气象, 2006, 25(5): 807-813.
[11]李茂善, 马耀明, 仲雷, 等. 珠峰和曲宗站2005年4, 5月近地辐射能收支初步分析[J]. 高原气象, 2006, 25(6): 1008-1013.
[12]孙方林, 马耀明, 马伟强, 等. 珠峰地区大气边界层结构的一次观测研究[J]. 高原气象, 2006, 25(6): 1014-1019.
[13]仲雷, 马耀明, 苏中波, 等. 雨季前后珠峰地区近地层气象要素、 辐射及能量平衡分量变化特征[J]. 高原气象, 2007, 26(6): 1269-1275.
[14]刘伟刚, 任贾文, 秦翔, 等.珠穆朗玛峰绒布冰川消融与产汇流水文特征分析[J]. 冰川冻土, 2010, 32(2): 367-372.
[15]张东启, 效存德, 秦大河. 近几十年来喜马拉雅山冰川变化及其对水资源的影响[J]. 冰川冻土, 2009, 31(5): 885-895.
[16]施雅风, 刘时银. 中国冰川对21世纪全球变暖响应的预估[J]. 科学通报, 2000, 45(2): 434-438.
[17]Hu H, Wang G, Liu G, et al. Influence of alpine Ecosystem degradation on soil temperature in the freezing-thawing process on Qinghai-Tibet Plateau[J]. Environmental Geology, 2009, 57(6): 1391-1397.
[18]杨梅学, 姚檀栋, 田立德, 等. 青藏高原唐古拉山南北坡夏季风降水特征的对比分析[J]. 应用气象学报, 2000, 11(2): 199-204.
[19]Renoj J, Thayyen J T, Gergan D P, et al. Monsoonal control on glacier discharge and hydrograph characteristics, a case study of Dokriani Glacier, Garhwal Himalaya, India[J]. J Hydrol,2005, 306: 37-49.
[20]Ageta Y, Higuchi K. Estimation of mass balance components of a summer accumulation type glacier in the Nepal Himalaya[J]. Geografiska Annaler, 1984, 66(3): 249-255.
