利用2015年NCEP/NCAR再分析一日四时次资料和日资料,应用区域平均、热流量方程估算等方法对2015年12月29日北极爆发性增温的原因进行研究。结果表明,2015年12月29日北极出现爆发性增温,日增温幅度最高达到25°C以上。增温期间,受到...利用2015年NCEP/NCAR再分析一日四时次资料和日资料,应用区域平均、热流量方程估算等方法对2015年12月29日北极爆发性增温的原因进行研究。结果表明,2015年12月29日北极出现爆发性增温,日增温幅度最高达到25°C以上。增温期间,受到强盛温带气旋系统和反气旋系统的共同作用,增温区域出现强盛的南风,风速最大值达到20 m s-1以上,位置不断北进达到北极点。强盛的南风为北极地区带来强盛的暖平流,同时暖湿空气进入北极后,增温区上空云量明显增加。12月28日至12月29日温度平流由冷平流转变为暖平流,暖平流的中心区域与温度爆发性增长的区域有很好的对应关系,暖平流是北极爆发性增温的重要原因。对于一直处于极夜的北极地区,由于云量的增加,大气顶向上长波辐射减少,加剧了温度的上升。温度平流增温贡献率为20.4%,垂直项的贡献率为-9.9%,非绝热作用贡献率为89.5%,温度平流和非绝热作用共同导致了本次北极地区的爆发性增温,非绝热作用是本次爆发性增温最重要的增温因素。展开更多
The interaction between the low-frequency atmospheric oscillation(Madden-Julian Oscillation,MJO) and the diabatic heating over the Qinghai-Xizang Plateau(QXP) from March to June is analyzed.The results show that there...The interaction between the low-frequency atmospheric oscillation(Madden-Julian Oscillation,MJO) and the diabatic heating over the Qinghai-Xizang Plateau(QXP) from March to June is analyzed.The results show that there are respectively two and one wave trains around the QXP during the onset of the South China Sea monsoon in strong and weak monsoon years.The locations and strength of the wave train propagation differ between the strong and weak monsoon years.Because diabatic heating of the QXP prevents the low-frequency oscillation,the wave train of interaction between the diabatic heating and the zonal wind MJO propagates along the west and east of the QXP in the strong monsoon years.The distribution of the wave train interaction between the diabatic heating and the zonal wind MJO traverses the QXP and coincides with the location of the southern and northern upper-level jet streams,showing that they are remarkably correlated.An interesting and notable phenomenon is that the interaction between diabatic heating and the zonal wind MJO over the QXP suddenly disappears during the monsoon onset in weak monsoon years.展开更多
文摘利用2015年NCEP/NCAR再分析一日四时次资料和日资料,应用区域平均、热流量方程估算等方法对2015年12月29日北极爆发性增温的原因进行研究。结果表明,2015年12月29日北极出现爆发性增温,日增温幅度最高达到25°C以上。增温期间,受到强盛温带气旋系统和反气旋系统的共同作用,增温区域出现强盛的南风,风速最大值达到20 m s-1以上,位置不断北进达到北极点。强盛的南风为北极地区带来强盛的暖平流,同时暖湿空气进入北极后,增温区上空云量明显增加。12月28日至12月29日温度平流由冷平流转变为暖平流,暖平流的中心区域与温度爆发性增长的区域有很好的对应关系,暖平流是北极爆发性增温的重要原因。对于一直处于极夜的北极地区,由于云量的增加,大气顶向上长波辐射减少,加剧了温度的上升。温度平流增温贡献率为20.4%,垂直项的贡献率为-9.9%,非绝热作用贡献率为89.5%,温度平流和非绝热作用共同导致了本次北极地区的爆发性增温,非绝热作用是本次爆发性增温最重要的增温因素。
基金supported by National Basic Research Program of China (Grant No. 2007CB411506)National Natural Science Foundation of China (Grant No. 40875050)
文摘The interaction between the low-frequency atmospheric oscillation(Madden-Julian Oscillation,MJO) and the diabatic heating over the Qinghai-Xizang Plateau(QXP) from March to June is analyzed.The results show that there are respectively two and one wave trains around the QXP during the onset of the South China Sea monsoon in strong and weak monsoon years.The locations and strength of the wave train propagation differ between the strong and weak monsoon years.Because diabatic heating of the QXP prevents the low-frequency oscillation,the wave train of interaction between the diabatic heating and the zonal wind MJO propagates along the west and east of the QXP in the strong monsoon years.The distribution of the wave train interaction between the diabatic heating and the zonal wind MJO traverses the QXP and coincides with the location of the southern and northern upper-level jet streams,showing that they are remarkably correlated.An interesting and notable phenomenon is that the interaction between diabatic heating and the zonal wind MJO over the QXP suddenly disappears during the monsoon onset in weak monsoon years.