大气科学
大氣科學
대기과학
Chinese Journal of Atmospheric Sciences
2015年
6期
1059-1072
,共14页
春季青藏高原感热%年际变化%印度夏季风爆发
春季青藏高原感熱%年際變化%印度夏季風爆髮
춘계청장고원감열%년제변화%인도하계풍폭발
Spring sensible heat over the Tibetan Plateau%Interannual variability%Indian summer monsoon onset
本文基于日本气象厅(JMA)的 JRA-25再分析资料,分析了春季青藏高原表面感热加热年际变化的时空特征,及其对印度夏季风爆发过程的影响。EOF分析结果表明,春季高原感热加热的年际变化在高原中西部最为明显,这主要与局地地—气温差的年际变率有关。统计分析表明,当春季高原中西部表面感热偏强(弱)时,印度夏季风爆发偏早(晚),且高原中西部表面感热与ENSO事件无显著相关。春季高原中西部感热能够通过改变印度季风区对流层高层和低层的经向热力结构来影响印度夏季风的爆发时间。当春季高原中西部感热偏强时,造成的上升气流在高原以西的印度季风区北部下沉,通过绝热增暖引起局地对流层中上部的异常暖中心,令印度季风区对流层中上部平均温度经向梯度由冬至夏的季节性反转提早。同时,印度季风区北部的下沉运动能够抑制当地降水,令陆面温度升高,并通过非绝热过程造成对流层低层的异常暖中心,进一步增强了印度季风区的海陆热力对比。在印度季风区以北地区对流层高、低层异常增暖的共同作用下,印度夏季风提前爆发。
本文基于日本氣象廳(JMA)的 JRA-25再分析資料,分析瞭春季青藏高原錶麵感熱加熱年際變化的時空特徵,及其對印度夏季風爆髮過程的影響。EOF分析結果錶明,春季高原感熱加熱的年際變化在高原中西部最為明顯,這主要與跼地地—氣溫差的年際變率有關。統計分析錶明,噹春季高原中西部錶麵感熱偏彊(弱)時,印度夏季風爆髮偏早(晚),且高原中西部錶麵感熱與ENSO事件無顯著相關。春季高原中西部感熱能夠通過改變印度季風區對流層高層和低層的經嚮熱力結構來影響印度夏季風的爆髮時間。噹春季高原中西部感熱偏彊時,造成的上升氣流在高原以西的印度季風區北部下沉,通過絕熱增暖引起跼地對流層中上部的異常暖中心,令印度季風區對流層中上部平均溫度經嚮梯度由鼕至夏的季節性反轉提早。同時,印度季風區北部的下沉運動能夠抑製噹地降水,令陸麵溫度升高,併通過非絕熱過程造成對流層低層的異常暖中心,進一步增彊瞭印度季風區的海陸熱力對比。在印度季風區以北地區對流層高、低層異常增暖的共同作用下,印度夏季風提前爆髮。
본문기우일본기상청(JMA)적 JRA-25재분석자료,분석료춘계청장고원표면감열가열년제변화적시공특정,급기대인도하계풍폭발과정적영향。EOF분석결과표명,춘계고원감열가열적년제변화재고원중서부최위명현,저주요여국지지—기온차적년제변솔유관。통계분석표명,당춘계고원중서부표면감열편강(약)시,인도하계풍폭발편조(만),차고원중서부표면감열여ENSO사건무현저상관。춘계고원중서부감열능구통과개변인도계풍구대류층고층화저층적경향열력결구래영향인도하계풍적폭발시간。당춘계고원중서부감열편강시,조성적상승기류재고원이서적인도계풍구북부하침,통과절열증난인기국지대류층중상부적이상난중심,령인도계풍구대류층중상부평균온도경향제도유동지하적계절성반전제조。동시,인도계풍구북부적하침운동능구억제당지강수,령륙면온도승고,병통과비절열과정조성대류층저층적이상난중심,진일보증강료인도계풍구적해륙열력대비。재인도계풍구이북지구대류층고、저층이상증난적공동작용하,인도하계풍제전폭발。
The JRA-25 reanalysis dataset provided by the Japan Meteorological Agency (JMA) was utilized to investigate the spatiotemporal characteristics of surface sensible heating over the Tibetan Plateau (TP) in boreal spring, as well as their effect on the onset of the Indian summer monsoon (ISM). The EOF results show that the most evident interannual variability of sensible heat occurs over the central-western TP in spring; this is primarily attributed to the interannual variability of the land–air temperature difference in situ. This is demonstrated by statistical analysis, which shows that the ISM builds up early (late) with strong (weak) spring sensible heat over the central-western TP, which is not significantly correlated with ENSO events. In fact, the spring sensible heat over the central-western TP could alter the ISM onset time by changing the meridional thermal structure in both the upper and lower troposphere over the ISM region. When the spring sensible heat over the central-western TP is stronger, local ascent is enhanced followed by descent to the west of the TP, which is to the north of the ISM region. Thus, the anomalous warming induced by the adiabatic process could accelerate the seasonal transition of the meridional mean temperature gradient in the middle and upper troposphere from winter to summer. Meanwhile, the subsidence anomaly to the north of the ISM region could prevent rainfall development in situ causing the land surface temperature to increase. Thereafter, the strengthened diabatic heating of the land leads to the warm center in the lower troposphere, increasing the land-sea thermal contrast in the ISM region. As a result, the anomalous warming in both the upper and lower troposphere contributes to the early onset of the ISM under the influence of the stronger spring sensible heat over the central-western TP.
