2001-2011年青藏高原东北边坡地带云水资源分析

Abstract

Abstract: The northeast of the Qinghai-Tibet Plateau is the intersection transitional zone of the Qinghai-Tibet Plateau and the Loess Plateau, also the transitional zone of agriculture and animal husbandry, the terrain is complex, and it is often affected by various weather systems, so the response of climate change is very sensitive. It is characterized by the fragile ecological environment, soil erosion and water loss, pasture degeneration, land desertification and various environmental problems. Therefore, it is very meaningful for further understanding the climatic characteristics and climate change in the Qinghai-Tibet Plateau by analyzing the climate change and its trends in the northeast of the plateau. However, the recent discussion about cloud cover and its related factors in the northwest or in the whole plateau was insufficient. So it is necessary to study the temporal change of cloud cover and more detailed weather characteristics related to cloud cover over the northeast of the Qinghai-Tibet Plateau. It is of great significance for implementing artificial precipitation and developing air resources.
Based on the daily cloud cover data observed by 22 meteorological stations and the NCAR/NCEP reanalysis data in the northeast of the Qinghai-Tibet Plateau (32°-37° N, 99°-104° E) during the period from 2001 to 2011, the development characteristics of cloud cover and the relationship between cloud cover and vapor flux in the northeast of the Qinghai-Tibet Plateau in recent 10 years were studied in terms of the statistical analysis and the HYSPLIT_4 Model. The results showed that the total cloud cover and the low cloud cover over the study area was decreased from the south to the north. There was an increase trend of total cloud cover and low cloud cover over the study area during the period from 2001 to 2011, especially in spring and summer. When rain or snow occurred, appear probability of cirrus was the highest, then that of altostratus, and that of cumulus was the lowest. Appear probability of convective cloud was higher than that of nonconvective cloud over the northeast of the Qinghai-Tibet Plateau. Water vapor is one of the main factors affecting the distribution of precipitation and the change of convective cloud. Water vapor flux came mainly from 700 hPa layer, and water vapor flux could reflect the low cloud cover well.

Key words: HYSPLIT Mode, cloud cover, cloud form, water vapor, Qinghai-Tibet Plateau

DU Liang-Liang, LI Jiang-Ping, CHEN Xiao-Yan, SHANG Ke-Zheng, YANG De-Bao, WANG Shi-Gong. Analysis on Cloud and Vapor Flux in the Northeast of the Qinghai-Tibet Plateau during the Period from 2001 to 2011[J]., 2012, 29(5): 862-869.

References

王建兵,杨文杰.青藏高原东北部边坡地带气候变化及对牧草生长的影响〔J〕.安徽农业科学,2010,38(26):14 535-14 537.

王根绪,沈永平,程国栋.黄河源区生态环境变化与成因分析〔J〕.冰川冻土,2000,22(3):200-205.

王建兵,汪治桂.青藏高原东北部边坡地带气温变化特征研究〔J〕.干旱地区农业研究,2007,25(1):176-180.

裘国旺,赵艳霞,王石立.气候变化对我国北方农牧交错带及其气候生产力的影响〔J〕.干旱区研究, 2001,18(1):23-28.

谌芸,李强,李泽椿.青藏高原东北部强降水天气过程的气候特征分析〔J〕.应用气象学报,2006,17(1):98-103.

唐小萍,张核真,路红亚,等.西藏地区1971-2008年台站观测总云量的变化特征〔J〕.气候变化研究进展,2009,5(6):343-347.

高蓉,陈少勇,董安祥.青藏高原低云量的年际变化及其稳定性〔J〕.干旱区研究,2007,24(6):760-765.

陈少勇,董安祥.青藏高原总云量的年际变化及其稳定性〔J〕.干旱区研究,2006,23(2):327-333.

陈勇航,陈艳,黄建平,等.中国西北地区云的分布及其变化趋势〔J〕.高原气象,2007,26(4):741-748.

马京津,高晓清.华北地区夏季平均水汽输送通量和轨迹的分析〔J〕.高原气象,2006,25(5):893-899.

黄健,颜鹏,Roland R Draxler.利用HYSPLIT_4模式分析珠海地面SO2浓度的变化规律〔J〕.热带气象学报,2002,18(4):407-414.

杜亮亮,杨德保,王式功,等.玛曲地区5-10月水汽通量及强降水水汽来源分析〔J〕.兰州大学学报:自然科学版,2011,47(5):55-61.

王宝鉴,黄玉霞,王劲松,等.祁连山云和空中水汽资源的季节分布与演变〔J〕.地球科学进展, 2006,21(9):948-955.

闫蓉,安光辉,郭守生.常见相似云对比及其对应降水分析〔J〕.现代农业科技,2010（12）:263-264.

张勇,赵东宁,李德毅.相似云及其度量分析方法〔J〕.信息与控制,2004,33(2):129-132.

雷春丽.相似云的判定〔J〕.陕西气象,2002(1):28-29.

章基嘉,朱抱真,朱福康,等.青藏高原气象学进展：青藏高原气象科学实验（1979）和研究〔M〕.北京：科学出版社,1988:207-216.

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Analysis on Cloud and Vapor Flux in the Northeast of the Qinghai-Tibet Plateau during the Period from 2001 to 2011

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