华南前汛期降水异常与太平洋海表温度异常的关系

利用近50年华南地区站点逐日降水观测资料和全球大气、海洋分析资料,分析了华南前汛期降水异常的变化特征及其与太平洋海温异常的联系.结果表明,近50年来华南前汛期降水总体呈现减少趋势.影响华南前汛期降水异常的太平洋海温异常型是一个类似于ENSO的西太平洋暖池模态,即显著海温异常区域位于西太平洋暖池.西太平洋暖池区域(120°E-180°E,20°S-20°N)前期冬季海温异常同华南前汛期降水存在显著的负相关关系,是具有预报意义的海温关键区.该关键区海温异常影响华南前汛期降水的可能物理过程是:当前期冬季暖池异常偏暖时,菲律宾周围地区对流活动加强,导致Walker环流及东亚太平洋中低纬局地Hadley环流增强;该异常通过影响东亚－太平洋遥相关波列,使前汛期期间西太平洋副高加强西伸,脊线位置偏北,同时副热带西风急流减弱北退.随着Hadley环流上升支的增强,东亚副热带地区下沉运动也增强了,华南地区对流活动受到抑制.而且由于副高的增强,经过其北侧向华南地区的西南水汽输送辐合也减弱了,因此前汛期降水偏少.冷海温年的情形则相反,华南前汛期降水偏多.近50年来华南前汛期降水总体呈现趋势性减少正是由于前冬西太平洋暖池趋势性增暖所致.     

热带印度洋Dipole事件的两种模态

研究了印度洋Dipole事件期间热带太平洋．印度洋海洋次表层海温异常和海面风应力异常分布主要型,揭示了Dipole事件的两种模态,探讨了其形成机制,得到如下结果：（1）印度洋Dipole事件在热带印度洋次表层海温异常表现为“〈”型的东西向偶极子分布,“〈”以东的热带东印度洋为沿赤道呈舌状西伸的显著海温异常中心,“〈”以西的热带中西印度洋为反号的、以赤道为准对称的南强北弱显著海温异常中心．（2）印度洋Dipole事件由两种模态构成,二者具相同空间分布但具不同的时间变率,它们是两个独立的大尺度海气相互作用的结果．Dipole事件第一模态源于热带太平洋一印度洋尺度海气相互作用,它与ENSO事件共存．Dipole事件第二模态起因于热带印度洋尺度海气相互作用,它与Mascarene高压位置和强度变化紧密联系．当二者位相一致时,产生强Dipole事件,二者位相相反时,Dipole事件很弱或消失,一者较强时,Dipole事件一般也较强．（3）印度洋Dipole事件是热带印度洋海面异常风应力强迫的结果,海面异常风应力作用下产生的垂直输送导致海水堆积和涌升是造成次表层海温异常的主要动力过程．当赤道印度洋为异常东风时,热带东印度洋冷海水上升,热带西印度洋暖海水堆积,热带印度洋温跃层东浅西深;由于Coriolis力的作用,赤道海域离赤道流造成冷海水上升,赤道印度洋温跃层变浅;赤道两侧热带印度洋异常反气旋环流及旋度场,造成该异常旋度中心区域暖海水堆积,赤道外热带印度洋温跃层加深．三者共同作用产生正位相Dipole事件．热带印度洋为异常西风时,动力过程相反,产生负位相Dipole事件．     

夏季西北太平洋大气环流异常及其与热带印度洋-太平洋海温变化的关系

本文分析了夏季西北太平洋大气环流异常特征及其与海温变化的关系,发现夏季西北太平洋异常反气旋/气旋(WNPAC/WNPC)是西北太平洋地区对流层中低层存在的重要大气环流异常现象,与东亚-西北太平洋低纬度至高纬度的经向PJ波列及欧亚中高纬度东西纬向波列的变化有关,通过与中高纬度环流变化的联系,对东亚及欧亚中高纬度气候有重要影响.夏季WNPAC/WNPC与热带海温变化的关系存在明显的不对称性,显著的WNPAC一般出现在El Niño衰减年夏季,与前期El Niño成熟年冬季的赤道东太平洋暖海温异常和El Niño衰减年春夏季印度洋海盆尺度的暖海温异常有明显的正相关关系,进一步表明了WNPAC在El Niño事件影响夏季气候中的重要桥梁作用;而夏季显著的WNPC与前期和同期热带海温变化的关系存在明显的不确定性,主要与夏季热带印度洋和赤道中东太平洋之间东暖西冷的热力差异异常引起的孟加拉湾-赤道西太平洋西风异常有关.进一步分析WNPAC/WNPC与海温变化关系不对称的可能原因,发现El Niño和La Niña衰减年夏季热带印度洋和太平洋海温变化所引起的印-太之间海温(热力)差异的一致性特征可能是导致WNPAC/WNPC与海温变化关系不对称的主要原因.     

FOAM海气耦合模式中印度洋海温年际变化在厄尔尼诺不同发展阶段的影响

热带印度洋与热带太平洋是全球海气耦合最活跃的区域之一,两者的海温场中均存在着显著的年际变化模态,而且这两个洋盆间的海温异常模态间是相互联系的.本文采用一个复杂的全球海气耦合模式,模拟了两组分别包含和不包含热带印度洋海温年际变化对热带大气强迫的耦合试验,对比研究印度洋海温年际变化在厄尔尼诺事件演变中的贡献.结果表明,热带印度洋海温年际变化的存在使得厄尔尼诺事件的成熟期强度增加,且在厄尔尼诺的发展年秋季出现明显的快速增长.但在厄尔尼诺衰亡年,热带印度洋海温年际变化却使得热带太平洋暖海温减弱甚至转变为冷海温,使得厄尔尼诺事件的演变周期减短.具体来讲,发生于厄尔尼诺发展年的印度洋偶极子正异常事件能够在热带印度洋东部到热带西太平洋之间强迫出一支异常的下沉气流及异常Walker环流,加强原有的西太平洋低层西风异常,通过海洋平流及波动调整过程增强厄尔尼诺期间太平洋的暖海温异常;而在厄尔尼诺衰亡年出现的印度洋全洋盆增暖则在南亚季风爆发的背景下,在印度大陆上空产生一支明显的异常上升气流,激发西太平洋东传的Kelvin波及低层大气的东风异常,削弱了热带太平洋洋面的西风异常,促使厄尔尼诺从暖位相向冷位相转化,并使得西北太平洋出现反气旋式大气环流和降水的减少.因此,印度洋海温偶极子模态主要影响厄尔尼诺事件的发展阶段,而印度洋海温洋盆一致变化模态显著影响厄尔尼诺事件的衰亡阶段,两者均可通过改变大气环流而遥强迫太平洋海域.     

北太平洋海温与广西前汛期降水的联系

利用1979—2019年全国160站逐月降水资料、Hadley中心海温资料、NOAA以及NCEP/NCAR再分析资料,结合相关分析、信息流以及合成分析方法,分析了北太平洋海温异常与广西前汛期降水的同期联系,并初步探讨了前者对后者的影响及可能机制,结果表明：北太平洋关键区海温是广西前汛期降水的显著影响源,海温正位相(负位相)的异常分布在一定程度上导致了广西前汛期降水增多(减少).北太平洋关键区海温变化可以独立于赤道中东太平洋影响前汛期降水,而赤道中东太平洋海温变化可以起到调制作用,增强两者联系.北太平洋为正位相海温异常时,大气为“+-+”的经向三极型位势高度异常响应.与此同时,海温异常激发了向下游中高纬传播的Rossby波列,引起东亚沿岸位势高度正异常和反气旋环流异常.在上述机制下,贝加尔湖高压脊和东亚大槽均显著增强,使得中高纬冷空气更易南下.赤道中东太平洋海温的调制作用体现在对中低纬环流的影响.关键区海温正位相对应于赤道中东太平洋海温偏暖,后者引起局地异常上升运动,减弱Walker环流进而导致赤道西太平洋出现下沉异常,抑制了对流活动,在西北太平洋强迫出异常反气旋,使得副高加强西伸.副高...     

南海夏季风爆发与南大洋海温变化之间的联系

利用1979-2009年NCEP第二套大气再分析资料和ERSST海温资料,分析南海夏季风爆发时间的年际和年代际变化特征,考察南海夏季风爆发早晚与南大洋海温之间的联系.主要结果为:(1)南海夏季风爆发时间年际和年代际变化明显,1979-1993年与1994-2009年前后两个阶段爆发时间存在阶段性突变;(2)南海夏季风爆发时间与前期冬季(12-1月)印度洋-南大洋(0-80°E,75°S-50°S)海温、春季(2-3月)太平洋-南大洋(170°E -80°W,75°S-50°S)海温都存在正相关关系,当前期冬、春季南大洋海温偏低(高)时,南海夏季风爆发偏早(晚).南大洋海温信号,无论是年际还是年代际变化,都对南海夏季风爆发具有一定的预测指示作用;(3)南大洋海温异常通过海气相互作用和大气遥相关影响南海夏季风爆发的迟早.当南大洋海温异常偏低(偏高)时,冬季南极涛动偏强(偏弱),同时通过遥相关作用使热带印度洋-西太平洋地区位势高度偏低(偏高)、纬向风加强(减弱),热带大气这种环流异常一直维持到春季4、5月份,位势高度和纬向风异常范围逐步向北扩展并伴随索马里越赤道气流的加强(减弱),从而为南海夏季风爆发偏早(偏晚)提供有利的环流条件.初步分析认为,热带大气环流对南大洋海气相互作用的遥响应与半球际大气质量重新分布引起的南北涛动有关.     

厄尔尼诺/南方涛动与赤道远西太平洋准两年周期振荡之间相互作用的概念模式

建立了一个反映厄尔尼诺/南方涛动(ENSO)与热带远西太平洋准两年振荡(QBOWP)相互作用最基本物理过程的新概念模式. 在此概念模式中, QBOWP对ENSO的影响通过两种途径: (1) 沿赤道太平洋海洋Kelvin波和 (2) 大气的Walker环流; 而ENSO对QBOWP的影响则可通过大气的Walker环流异常来实现. 对该模式结果的分析诊断表明: 在ENSO与QBOWP相互作用过程中, 大气桥(Walker环流)的作用比海洋桥(沿赤道太平洋的Kelvin波)更重要; 通过QBOWP与ENSO的相互作用, 一个3~5年周期的ENSO振荡可以变为准两年振荡, 而赤道远西太平洋年际变化的主要周期也会变长; 热带太平洋大气-海洋耦合系统的多时间尺度的年际变化可以通过ENSO与QBOWP的相互作用来实现.     

海温异常对西太平洋副热带高压脊面演变影响的机制研究

根据欧洲中期数值预报中心提供的大气环流资料和NOAA提供的海温资料, 应用改进的低阶谱模式方法研究了海温异常对西太平洋副热带高压脊面演变影响的物理机制. 结果表明, 在El Niño型海温强迫下, 大气环流内部动力过程中的大尺度波波和波流相互作用较弱. 随着外部热源强迫从冬季型向夏季型推进, 西太平洋副热带高压脊面北进不明显, 使得夏季西太平洋副热带高压脊面相对偏南. 在La Niña型海温强迫下, 大气环流内部动力过程中的大尺度波波和波流相互作用明显. 随着外源强迫从冬季型向夏季型转变, 西太平洋副热带高压脊面将随之向北移动19个纬度左右, 使得夏季西太平洋副热带高压脊面偏北; 且北移到达一定纬度后, 西太平洋副热带高压脊面表现出较为显著的30~60 d季节内南北振荡, 振幅在4°~7°之间.不同海温异常型所导致的大气内部动力过程差异是造成西太平洋副热带高压脊面年际变化的重要原因之一.     

热带太平洋海洋混合层水体振荡与ENSO循环

研究了热带太平洋温跃层和海面风应力年际变率主要模态及它们之间的相互作用, 探讨了ENSO循环的可能形成机制, 得到如下结果: (1)热带太平洋温跃层异常具以160°W为纵轴的东西向偶极子分布和以6~8°N为横轴的南北向跷跷板分布等两种主要模态, 两者(相位差90°)组合构成El Niño/La Niña循环, 表现为混合层水体(指温跃层界面之上海温垂直分布较均匀的上层海洋)在赤道与12°N之间的热带太平洋海盆内反时针三维振荡; (2)热带太平洋风应力异常具两种主要分布型, 第一特征向量场反映了热带太平洋信风异常导致的赤道太平洋异常纬向风应力及散度场与离赤道北太平洋异常越赤道风应力及反相散度场, 第二特征向量场反映了热带辐合带(ITCZ)异常导致的异常风应力及相应散度场; (3)信风异常对ENSO事件的形成、强度和相变都有决定性的作用, 它导致海面倾斜, 提供了混合层水体振荡初始位能, 同时造成赤道太平洋西部与东部之间和赤道太平洋与12°N北太平洋海盆之间温跃层同步反相位移, 限定了热带太平洋混合层水体振荡的振幅和路线. ITCZ异常主要对ENSO相变过程有一定影响; (4)热带西太平洋海洋热力异常导致海面风应力异常, 它伴随热带太平洋混合层水体振荡沿赤道由西向东扩展, 造成热带太平洋信风异常, 产生有利于水体振荡的异常风应力及散度场, 反过来进一步加强混合层水体振荡. 这一海气耦合过程与混合层水体振荡一起为ENSO循环提供了相变和年际记忆机制. 研究指出, ENSO循环实质上是由信风异常和海气耦合过程共同作用下产生的热带太平洋海洋混合层水体在赤道与12°N之间热带太平洋海盆内的惯性振荡. 海气耦合过程产生的作用力大于或等于水体运动阻力时, ENSO循环将加强或维持, 不足以克服水体运动阻力时, 水体振荡减小, ENSO循环将逐渐减弱, 直至中断.     

外热带大气扰动对ENSO的影响

合成分析了20世纪80年代以来5次主要的ENSO事件，发现外热带大气扰动通过经向风异常不仅对ENSO的发生起到重要的触发作用，而且影响到ENSO的发展和衰减. 因此，尽管ENSO对外热带大气扰动有影响，但同时外热带大气扰动又与ENSO有相互作用. 在ENSO发生前，南印度洋中纬度为反气旋异常，并通过Rossby波的频散作用加强了澳大利亚附近的反气旋异常；同时，澳大利亚东部沿海的南风异常与菲律宾附近的北风异常在赤道辐合，促进了赤道西太平洋西风异常的爆发和其后ENSO的发生. 在ENSO发生之后，东南太平洋上的气旋异常及相关的南风异常进一步增强了赤道中东太平洋的西风异常和ENSO的发展. 当ENSO达到成熟时，澳大利亚东部的反气旋异常东移，使东南太平洋的气旋异常减弱，南方涛动型环流异常亦随之减弱；同时，阿留申气旋异常加强，尤其是副热带北太平洋的风场异常可加强赤道中东太平洋海水的涌升，使该地区海表温度降低，加速ENSO的消亡.     

The behavior of deep convective clouds over the warm pool and connection to the Walker circulation

As the deep convective clouds (DCCs) over the western Pacific and Indian Ocean warm pool may play different roles in the climate system, variations in DCC properties over these two sectors are investigated and compared. The DCC intensity and area varies more significantly in the Indian Ocean than the western Pacific sector, while the DCC frequency is comparable in both sectors at the seasonal scale. Although the Indian Ocean sector is strongly dominated by the seasonal evolution, the interannual variations in the two sectors are comparable for all three DCC properties (frequency, intensity, and area). Besides, Walker circulation is closely correlated with the interannual variability of DCCs in both sectors. The Walker circulation strengthens (weakens) as the DCCs shift eastward (westward) over the Indian Ocean sector and westward (eastward) over the western Pacific sector. When more or stronger DCCs occur over the Indian Ocean sector (western Pacific sector), the Walker circulation becomes stronger (weaker) and shifts westward (eastward). Interestingly, the response of the Walker circulation to DCC variability over the warm pool is asymmetry. The asymmetry response of the Walker circulation to the negative and positive DCC anomaly may be related to the non-linearity internal variability of the atmosphere. DCCs over the Indian Ocean sector have a much weaker nonlinear correlation with the Walker circulation than DCCs over the western Pacific sector.     

南印度洋副热带偶极模在ENSO事件中的作用

南印度洋副热带偶极模（Subtropical Dipole Pattern,SDP）是印度洋存在的另一种很明显的偶极型海温差异现象,在年际和年代际尺度上均有十分明显的表现.而目前有关印度洋海气相互作用的研究主要集中在赤道印度洋地区,针对南印度洋地区的工作还比较少,特别是有关南印度洋海温与ENSO（El NiDo-Southern Oscillation）事件关系的研究.本文初步探讨了年际尺度上南印度洋副热带偶极型海温变化差异与ENSO事件的关系,发现SDP与ENSO事件有密切的联系,SDP事件就像连接正负ENSO位相转换的一个中间环节,SDP事件前后期ENSO的位相刚好完全相反.进一步,本文通过分析SDP事件前后期海温、高低层风、低层辐合辐散、高空云量和辐射等的变化特征研究了南印度洋偶极型海温异常在ENSO事件中的作用,结果表明：SDP在ENSO事件中的作用不仅涉及海气相互作用的正负反馈过程,还与热带和副热带大气环流之间的相互作用有关,特别是与东南印度洋海温变化所引起的异常纬向风由赤道印度洋向赤道太平洋传播的过程等有十分直接的关系;同时,SDP对ENSO事件的影响在很大程度上还依赖于大尺度平均气流随季节的变换.     

Mixed-layer water oscillations in tropical Pacific for ENSO cycle

The main modes of interannal variabilities of thermocline and sea surface wind stress in the tropical Pacific and their interactions are investigated,which show the following results.(1) The thermocline anomalies in the tropical Pacific have a zonal dipole pattern with 160°W as its axis and a meridional seesaw pattern with 6-8°N as its transverse axis.The meridional oscillation has a phase lag of about 90° to the zonal oscillation,both oscillations get together to form the El Ni?o/La Ni?a cycle,which be-haves as a mixed layer water oscillates anticlockwise within the tropical Pacific basin between equator and 12°N.(2) There are two main patterns of wind stress anomalies in the tropical Pacific,of which the first component caused by trade wind anomaly is characterized by the zonal wind stress anomalies and its corresponding divergences field in the equatorial Pacific,and the abnormal cross-equatorial flow wind stress and its corresponding divergence field,which has a sign opposite to that of the equatorial region,in the off-equator of the tropical North Pacific,and the second component represents the wind stress anomalies and corresponding divergences caused by the ITCZ anomaly.(3) The trade winds anomaly plays a decisive role in the strength and phase transition of the ENSO cycle,which results in the sea level tilting,provides an initial potential energy to the mixed layer water oscillation,and causes the opposite thermocline displacement between the west side and east side of the equator and also between the equator and 12°N of the North Pacific basin,therefore determines the amplitude and route for ENSO cycle.The ITCZ anomaly has some effects on the phase transition.(4) The thermal anomaly of the tropical western Pacific causes the wind stress anomaly and extends eastward along the equator accompanied with the mixed layer water oscillation in the equatorial Pacific,which causes the trade winds anomaly and produces the anomalous wind stress and the corresponding divergence in favor to conduce the oscillation,which in turn intensifies the oscillation.The coupled system of ocean-atmo-sphere interactions and the inertia gravity of the mixed layer water oscillation provide together a phase-switching mechanism and interannual memory for the ENSO cycle.In conclusion,the ENSO cycle essentially is an inertial oscillation of the mixed layer water induced by both the trade winds anomaly and the coupled ocean-atmosphere interaction in the tropical Pacific basin between the equator and 12°N.When the force produced by the coupled ocean-atmosphere interaction is larger than or equal to the resistance caused by the mixed layer water oscillation,the oscillation will be stronger or maintain as it is,while when the force is less than the resistance,the oscillation will be weaker,even break.     

初夏西北太平洋副高东西变动对中国南部降水东西差异的影响

西北太平洋副热带高压(以下简称副高)是影响中国气候的大尺度环流系统,为了进一步了解副高对中国气候的影响,本文利用站点观测资料和大气环流再分析资料,通过资料诊断分析和数值模拟方法,探讨了6月副高东西变动对中国南部降水的影响,以及影响副高东西变动的前期海洋因子.结果表明副高东西变动对中国西南和华南地区降水的影响明显不同:副高偏东有利于降水西南偏多而华南偏少,偏西则降水变化刚好相反.其原因与副高东西变化引起的环流差异有关,华南降水与副高东(西)变动时西太平洋地区副高西北侧的东北(西南)风异常以及东亚中低纬度地区异常经向波列的变化直接有关,而西南降水异常不仅与副高东西变动在东南亚地区引起的纬向风异常有关,与青藏高原大地形动力作用对副高北侧异常纬向风的变化也有十分密切的联系.此外,副高东西变动时影响西南和华南地区的水汽来源不同,影响西南的水汽主要来源于赤道印度洋80°E附近越赤道气流,而影响华南的水汽主要来源于副高南侧偏东气流从西北太平洋地区输送的水汽.进一步分析发现前期冬春季热带西北太平洋和赤道西太平洋海温变化的偶极差异与后期初夏副高东西变动有密切联系,冬春季西北太平洋暖海温和赤道西太平洋冷海温变化有利于后期初夏副高偏西,相反则有利于副高偏东,数值模拟结果在一定程度证实了资料诊断分析结果.     

Two modes of dipole events in tropical Indian Ocean

By analyzing the distributions of subsurface temperature and the surface wind stress anomalies in the tropical Pacific and Indian Oceans during the Indian Ocean Dipole (IOD) events, two major modes of the IOD and their formation mechanisms are revealed. (1) The subsurface temperature anomaly (STA) in the tropical Indian Ocean during the IOD events can be described as a “<” -shaped and west-east-oriented dipole pattern; in the east side of the “<” pattern, a notable tongue-like STA extends westward along the equator in the tropical eastern Indian Ocean; while in the west side of the “<” pattern, the STA has opposite sign with two centers (the southern one is stronger than the northern one in intensity) being of rough symmetry about the equator in the tropical mid-western Indian Ocean. (2) The IOD events are composed of two modes, which have similar spatial pattern but different temporal variabilities due to the large scale air-sea interactions within two independent systems. The first mode of the IOD event originates from the air-sea interaction on a scale of the tropical Pacific-Indian Ocean and coexists with ENSO. The second mode originates from the air-sea interaction on a scale of the tropical Indian Ocean and is closely associated with changes in the position and intensity of the Mascarene high pressure. The strong IOD event occurs when the two modes are in phase, and the IOD event weakens or disappears when the two modes are out of phase. Besides, the IOD events are normally strong when either of the two modes is strong. (3) The IOD event is caused by the abnormal wind stress forcing over the tropical Indian Ocean, which results in vertical transports, leading to the upwelling and pileup of seawater. This is the main dynamic processes resulting in the STA. When the anomalous easterly exists over the equatorial Indian Ocean, the cold waters upwell in the tropical eastern Indian Ocean while the warm waters pileup in the tropical western Indian Ocean, hence the thermocline in the tropical Indian Ocean is shallowed in the east and deepened in the west. The off-equator component due to the Coriolis force in the equatorial area causes the upwelling of cold waters and the shallowing of the equatorial India Ocean thermocline. On the other hand, the anomalous anticyclonic circulations and their curl fields located on both sides of the equator, cause the pileup of warm waters in the central area of their curl fields and the deepening of the equatorial Indian Ocean thermocline off the equator. The above three factors lead to the occurrence of positive phase IOD events. When anomalous westerly dominates over the tropical Indian Ocean, the dynamic processes are reversed, and the negative-phase IOD event occurs. Supported by National Natural Science Foundation of China (Grant No. 40776013), National Basic Research Program of China (Grant No. 2006CB403601) and the Knowledge Innovation Project of Chinese Academy of Sciences (Grant No. KZCX-SW-222)     

The emergence of equatorial deep jets in an idealised primitive equation model: an interpretation in terms of basin modes

Ocean circulation models do not generally exhibit equatorial deep jets (EDJs), even though EDJs are a recognised feature of the observed ocean circulation along the equator and they are thought to be important for tracer transport along the equator and even equatorial climate. EDJs are nevertheless found in nonlinear primitive equation models with idealised box geometry. Here we analyse several such model runs. We note that the variability of the zonal velocity in the model is dominated by the gravest linear equatorial basin mode for a wide range of baroclinic vertical normal modes and that the EDJs in the model are dominated by energy contained in vertical modes between 10 and 20. The emergence of the EDJs is shown to involve the linear superposition of several such neighbouring basin modes. Furthermore, the phase of these basin modes is set at the start of the model run and, in the case of the reference experiment, the same basin modes can be found in a companion experiment in which the amplitude of the forcing has been reduced by a factor of 1000. We also argue that following the spin-up, energy must be transferred between different vertical modes. This is because the model simulations are dominated by downward phase propagation following the spin-up whereas our reconstructions imply episodes of upward and downward propagation. The transfer of energy between the vertical modes is associated with a decadal modulation of the EDJs.     

顶部电离层电子密度和温度的统计背景及其地磁活动变化

通过对DEMETER卫星从2004年11月7日至2005年11月30日期间探测到的710 km高度顶部电离层的电子数据进行网格化(纬度2°×经度4°)统计平均,本文分析了不同地磁条件下顶部电离层电子密度和温度的全球分布情况.不论是在地磁宁静还是地磁活动期间,顶部电离层电子密度的分布都存在着一个巨大的威德尔海异常(夜间电...