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51.
The low frequency oscillation of latent heat flux over the tropical oceans has been studied. The NCEP reanalyzed fields of
wind and humidity alongwith Reynolds SST are used to compute the instantaneous as well as monthly mean surface latent heat
fluxes (LHF) for the year 1999. The procedure of LHF computation is based on bulk method. Spectral analysis shows that significant
energy is contained in Madden Julian Oscillation band in the winds, SST, moisture and in the latent heat flux. The global
distribution of wind, humidity, SST and LHF oscillation on the time scale of 30–50 days are analyzed. Maximum amplitude of
oscillation on this time scale in all the above mentioned parameters were found over the Indian Ocean. The fluctuation of
surface wind speed and moisture controls the latent heat flux on this time scale. The fluctuation of SST on this time scale
does not seem to be important over most of the oceans. 相似文献
52.
大气模式中季节内振荡特征对不同海温强迫场的响应 总被引:2,自引:0,他引:2
利用美国国家大气研究中心 (NCAR)的全球大气模式 (CCM3) ,分别以月平均和周平均海表温度 (SST)为强迫场进行 2个积分试验 (称为 CCMM和 CCMW试验 )。积分结果与观测资料的对比分析发现 ,CCM3模拟大气季节内振荡 (MJO)信号的强度均较观测资料偏弱 ,而其中以CCMW模拟的强度略大而较接近真实。表明 SST强迫场包含更真实的季节内变化信息对提高模拟 MJO强度有作用。 CCMM与 CCMW模拟 MJO活动的时间位相均与观测差别较大 ,直接原因在于 CCM3中降水季节内振荡与 SST变化的相关关系不正确 ,而更根本的问题在于大气模式无法反映资料分析发现的季节内时间尺度的 SST与大气的相互作用。 相似文献
53.
基于向外长波辐射、降水、大气再分析资料和 HYCOM(HYbridCoordinateOcean Model)盐度等资料,研究了 MJO(Madden-JulianOscillation,热带大气季节内振荡)对南海夏季降水的调制,并初步探讨了其对海洋表层盐度的影响。结果显示:MJO 对南海夏季降水有显著的调制作用,导致南海降水具有强的季节内变化,其最显著周期为45d。降水季节内信号在泰国湾北部、吕宋岛以西和台湾岛西南等迎风坡区域较强,而在越南外海的安南山脉背风区域较弱,且降水信号会随着 MJO 信号向东北方向移动。MJO 对流抑制(活跃)中心所在区域,低层大气辐聚减弱(增强),中层大气对流减弱(增强),导致降水减少(增加);此外,MJO 对流抑制(活跃)中心伴随的反气旋式(气旋式)环流会改变风场,风场减弱(增强)使得迎风区域的降水减少(增加)。MJO 引起的降水异常进一步影
响南海盐度,南海表层盐度也有明显的季节内变化特征,其显著周期和降水基本一致,为47d,且盐度异常信号也随降水异常向东北移动。本研究结果有助于进一步了解南海降水和表层盐度的季节内变化特征。 相似文献
54.
In this study, the impacts of the tropical Pacific–Indian Ocean associated mode (PIOAM) on Madden–Julian Oscillation (MJO) activity were investigated using reanalysis data. In the positive (negative) phase of the PIOAM, the amplitudes of MJO zonal wind and outgoing longwave radiation are significantly weakened (enhanced) over the Indian Ocean, while they are enhanced (weakened) over the central and eastern Pacific. The eastward propagation of the MJO can extend to the central Pacific in the positive phase of the PIOAM, whereas it is mainly confined to west of 160°E in the negative phase. The PIOAM impacts MJO activity by modifying the atmospheric circulation and moisture budget. Anomalous ascending (descending) motion and positive (negative) moisture anomalies occur over the western Indian Ocean and central-eastern Pacific (Maritime Continent and western Pacific) during the positive phase of the PIOAM. The anomalous circulation is almost the opposite in the negative phases of the PIOAM. This anomalous circulation and moisture can modulate the activity of the MJO. The stronger moistening over the Indian Ocean induced by zonal and vertical moisture advection leads to the stronger MJO activity over the Indian Ocean in the negative phase of the PIOAM. During the positive phase of the PIOAM, the MJO propagates farther east over the central Pacific owing to the stronger moistening there, which is mainly attributable to the meridional and vertical moisture advection, especially low-frequency background state moisture advection by the MJO’s meridional and vertical velocities. 相似文献
55.
By analyzing NCEP-NCAR reanalysis daily data for 1979–2016, the modulation by Madden-Julian Oscillation (MJO) of the wintertime surface air temperature (SAT) over high latitude is examined. The real-time multivariate MJO (RMM) index, which divides the MJO into eight phases, is used. It is found that a significantly negative SAT anomaly over the northern high latitude region of (180°–60 °W, 60°–90 °N) lags the MJO convection for 1∼2 weeks in phase 3, in which the enhanced convective activity exists over the Indian Ocean. While a significantly positive SAT anomaly appears over the same region following the MJO phase 7, as the tropical heating shows an opposite sign. Analysis of the anomalous circulation indicates that the observed SAT signal is probably a result of the northeastward propagating Rossby wave train triggered by MJO-related tropical forcing through Rossby wave energy dispersion. By using an anomalous atmospheric general circulation model (AGCM), the significant effect of tropical forcing on organizing the extratropical circulation anomaly is confirmed. Analysis of a temperature tendency equation further reveals that the intraseasonal SAT anomaly is primarily attributed to the advection of the mean temperature by the wind anomaly associated with the anomalous circulation of the MJO-related variability. 相似文献
56.
利用国家气象信息中心提供的753站降水资料,澳大利亚气象局提供的RMM MJO指数资料和NECP/NCAR逐日再分析资料,分析了2013年夏季长江中下游地区降水持续异常与MJO位相异常的可能联系。结果表明:2013年夏季长江中下游地区持续干旱期间,MJO位相分布明显异常,MJO东传停滞,长时间维持在第1、8位相;西太平洋副热带高压偏北偏强。当MJO位于第1、8位相时,东亚高纬度地区的环流距平场呈现“西高东低”的分布特征,不利于西伯利亚地区的冷空气南下至长江中下游地区;当MJO位于第1位相时,副热带高压西北侧水汽主要输送至长江中下游地区,第8位相时,输送至长江中下游地区的水汽异常偏少。总之,当MJO位于第1、8位相时,冷空气活动较弱,冷暖空气无法在长江中下游地区交汇,同时该地区深厚的下沉运动从近地面一直延伸至对流层上层,不利于降水的发生,导致2013年夏季降水持续偏少。 相似文献
57.
热带MJO对2009年11月我国东部大范围雨雪天气的可能影响 总被引:12,自引:1,他引:11
结合对历史资料的分析,研究了2009年11月热带地区一次强的热带大气季节内振荡(MJO)过程与11月我国东部大范围雨雪天气的可能联系,结果表明2009年11月强的MJO过程是我国东部大范围雨雪天气的一个重要的影响因子。MJO对流11月上中旬在印度洋地区异常活跃,尤其是MJO对流中心在第3位相(印度洋中东部)维持了9天(7—16日),对应了11月两次最强的降水(雪)过程。对MJO历史事件的合成分析显示,当MJO对流位于印度洋时,我国东部大部地区降水概率明显增加,温度偏低,与2009年11月的实况一致。中高纬地区大气环流的异常有可能受到热带MJO对流强迫的影响,这种影响可能通过遥相关的方式来实现。当MJO对流位于印度洋时,有利于欧亚中高纬环流维持两脊一槽的分布,同时西太平洋副热带高压偏强偏西,东亚东部地区维持一条显著的对流活跃带,这些环流异常形势与2009年11月的实况也较一致,体现了MJO对热带外地区环流异常影响的一般特征。热带地区MJO对流的异常通过对流加热强迫,除引起大尺度纬向环流异常外,同样会引起经向环流异常,从而影响热带外地区环流。当MJO对流位于印度洋时,西太平洋地区为异常的下沉运动控制,东亚东部辐合上升,在热带和中纬度地区之间形成一个异常的经向环流圈,经向环流的存在进一步有利于低层低纬度水汽的向北输送,造成东部降水偏多。利用MJO的发展和演变,对于把握类似2009年11月这样的大范围雨雪气候异常很有帮助。 相似文献
58.
利用澳大利亚气象局MJO(Madden-Julian Oscillation)指数(1979—2015年)资料、NCEP/NCAR全球再分析格点资料和中国气象局上海台风研究所台风资料,分析了MJO不同位相、强度与7—10月影响海南岛的热带气旋活动的关系。结果表明:7—10月影响海南岛的热带气旋活跃期和沉寂期与MJO的位相和强度有关,但7—8月和9—10月的热带气旋活跃期和沉寂期对应的MJO位相和强度有所不同。在7、8月,当MJO处于强的第3、6位相或弱的第4位相时有利于热带气旋影响海南岛,当MJO处于强的第1、2、8位相时则不利于热带气旋影响海南岛。在9、10月,当MJO处于7位相时有利于热带气旋影响海南岛,当MJO处于1位相时则不利于热带气旋影响海南岛。无论是7、8月还是9、10月,有利于热带气旋偏多和偏少的MJO位相对应的环流形势基本相反。 相似文献
59.
Impacts of a GCM's Resolution on MJO Simulation 总被引:3,自引:0,他引:3
Long-term integrations are conducted using the Spectral Atmospheric Model (referred to as SAMIL), which was developed in the Laboratory for Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics (LASG) in the Institute of Atmospheric Physics (IAP), with different resolutions to inves-tigate sensitivity of the Madden-Julian Oscillation (MJO) simulations to the model's resolution (horizontal and vertical). Three resolutions of the model, R15L9, R42L9 and R42L26, with identical physical processes, all produced the basic observed features of the MJO, including the spatiotemporal space-time spectra and eastward propagation. No fundamental differences among these simulations were found. This indicates that the model resolution is not a determining factor for simulating the MJO. Detailed differences among these modeling results suggest, however, that model resolution can substantially affect the simulated MJO in certain aspects. For instance, at a lower horizontal resolution, high frequency disturbances were weaker and the structures of the simulated MJO were better defined to a certain extent. A higher vertical resolution led to a more realistic spatiotemporal spectrum and spatial distribution of MJO precipitation. Meanwhile, increasing the model's resolution improved simulation of the climatology. However, increasing the resolution should be based on improving the cumulus parameterization scheme. 相似文献
60.
热带大气季节内振荡对西北太平洋台风的调制作用 总被引:5,自引:1,他引:4
利用澳大利亚气象局的RMM-MJO (Real-time Multivariate MJO) 指数, 分析研究了热带大气季节内振荡 (简称MJO) 对西北太平洋台风的调制作用及其机理, 结果表明MJO活动对西北太平洋台风的生成有比较明显调制作用。在MJO活跃期, 对流中心位于赤道东印度洋 (即MJO第2、3位相) 和对流中心越过海洋性大陆来到西太平洋地区 (即MJO 第5、6位相) 时台风生成的个数比例为2∶1。本文对西太平洋地区的大气环流场进行了多种气象要素的合成分析, 在MJO的不同位相, 西太平洋地区的动力因子分布形势有很明显不同。在第2、3位相, 各种因子均呈现出抑制西太平洋地区对流及台风发展的态势; 而在第5、6位相则明显有促进对流发生发展, 为台风生成和发展创造了有利条件的大尺度环流动力场。这说明MJO 在不断东移的过程中, 将改变大气环流形势, 最终影响了台风的生成和发展。接着, 我们从积云对流这个联系台风和MJO的重要因子出发, 研究了不同MJO位相时凝结加热的水平和垂直分布, 以及与台风环流、 水汽通量的配置情况。结果表明在MJO不同位相, 热源分布明显不同, 而这种水平和垂直方向的不同分布特征必然反映潜热释放和有效位能向有效动能转换的差异, 再与水汽的辐合辐散相配合, 就从台风获得的能量角度揭示了大气MJO调节台风的生成和发展, 造成不同位相时台风生成有根本差别的原因。 相似文献