北太平洋冬季年代际尺度海气相互作用

为了更深了解北太平洋年代际尺度海气相互作用,本文通过对湍流热通量和SST的相关关系进行了研究。当热通量和SSTA正相关时,代表海洋影响大气,而当二者相关系数为负时,表示大气强迫海洋。将整个北太平洋SSTA求平均和把北太平洋分成3个区域求SSTA平均,分别对热通量和SST的关系进行研究。结果表明,北太平洋冬季年代际尺度上的海气相互作用主要表现为海洋强迫大气,而在日本附近海域以及北太平洋中东部,海洋对大气的强迫作用最明显,因此这两个区域是北太平洋冬季年代际尺度上海气相互作用的关键区。

年代际尺度海岸演化机制与动力—统计建模方法

发展中长时间尺度的海岸演化预测方法与机理模型,是目前国际海岸演化研究领域关注的焦点和最具挑战性课题。本文系统性地回顾了近半个世纪以来不同时间尺度海岸演化模式的研究发展历程和成果,从动力机制和时间尺度两个方面对海岸演化机理模型存在的主要建模瓶颈问题进行了系统总结。通过对渤海湾西岸近一个半世纪以来海岸演化机制的初步分析,提出了以泥沙收支、环流输送、波浪掀沙以及波气候变化等要素作为年代际尺度海岸演化主要驱动因子,基于驱动力概化与统计升尺度有机衔接的年代际尺度海岸演化机理模型的动力—统计建模方法框架新思路,为推动海岸演化动力学理论体系和中长时间尺度海岸演化预测方法创新,提供了重要科学依据和借鉴。

年代际气候低频变率诊断研究进展

对近十年年代际气候低频变率的诊断研究作了综合评述 ,指出年代际及以上尺度的变率可能就是气候系统数十年尺度低频振荡或气候基本态的自然表征 ,并控制着更小时间尺度的 ENSO变率 ,对这一问题的深入研究不仅有助于提高气候变率的认识 ,而且对检测人为因素在全球变暖中的相对贡献也具有重要的意义。

中国冬季气温不同年代际的季节内变化特征及成因分析

利用1951~2020年中国观测站气温资料、NCEP/NCAR再分析资料和统计方法,分析了不同年代际时间尺度背景下我国冬季气温的季节内变化特征及相联系的大气环流异常。结果表明,1986年前、后为两个年代际时间尺度阶段,各阶段内前冬(12月)与后冬(1~2月)气温异常反位相年的比例均高于同位相年。1986年之前,季节内的优势空间模态为前冬全国冷(暖)转为后冬南方暖(冷)的可能性大,即南方地区季节内变率大;而1986年之后的优势空间模态为前冬北方冷(暖)转为后冬全国明显暖(冷)的可能性大,即北方地区季节内变率大。冬季气温的季节内变化显著受到冬季风系统关键环流季节内变化的影响。对应优势模态的正异常年份,1986年之前,欧亚中高纬地区对流层环流异常信号从前冬到后冬显著性减弱,其中西北太平洋地区对流层中高层的环流调整更明显,副热带高度场增强,热带东风急流北扩,前冬到后冬的环流调整有利于前冬全国大范围偏冷而后冬我国南方地区气温升高,造成南方地区季节内反位相变率增大。1986年之后,欧亚高中低纬地区的环流异常从前冬到后冬显著性增强,欧亚中高纬度环流发生较大调整,而低纬度的环流变化不大,北方地区前冬冷到后冬全国明显转暖,造成北方地区季节内反位相变率大。即副热带环流和中高纬度环流分别在两个年代际尺度阶段南方和北方的冬季气温季节内变率中起到主导作用。

不同时间尺度上黄淮地区夏季降水异常成因及预测研究

利用1961—2006年中国降水资料、NCEP/NCAR再分析资料、NOAA海表温度资料,分析了黄淮地区夏季降水的年代际和年际变化特征,研究了不同时间尺度上降水异常成因。结果表明,年代际尺度上,当太平洋年代际振荡处在暖(冷)位相时,南方涛动偏弱(强),黄淮地区夏季降水偏多(少)。在年际及以下尺度上,当印度洋北部海温偏高、南部偏低时,500 hPa位势高度场上,中高纬乌拉尔山以东和鄂霍次克海附近出现明显的双阻塞高压,副热带高压偏强;200 hPa风场上,西风急流略偏南,黄淮流域上空西风偏强,为反气旋环流;850 hPa风场上,黄淮流域上空出现西南—东北风的切变,使得急流出口区右侧次级环流的异常上升支恰好位于黄淮流域上空,高低空环流的这种配置导致了黄淮流域上空降水偏多。进一步分析发现,利用印度洋海温作为预测因子,建立预测模型,对黄淮流域降水年际变率有较高的预测能力。

2592～1225 a B.P.湖北神农架石笋氧同位素记录及区域气候意义

选择处于典型季风区中国内部湖北神农架地区青天洞一支具有连续清晰年纹层发育的石笋样品(QT6),通过精确的年纹层计数,结合高精度230Th年龄,建立2592～1225aB.P.期间长达1367a的石笋δ18O时间序列。石笋δ18O记录的17个持续时间在80a左右的峰谷旋回,与格陵兰冰芯δ18O记录具有非常好的一一对应关系,说明在年代际尺度上石笋δ18O同样能反映区域性气候变化,可能的机制是北高纬温度的变化通过大气传输影响热带辐合带(ITCZ)的迁移,从而影响东亚季风的强弱变化。

华北农牧交错带夏季极端气候的趋势分析

利用1956～2001年日降水量及日平均气温资料,分析华北农牧交错带极端气候事件的长期变化趋势.对降水极端事件的分析季节为5～9月,温度为6～8月.结果发现暴雨(日降水≥50 mm)频数没有显著的线性变化趋势,但1980年前后发生了明显的年代际尺度变化,1980年代到1990年代初,频次显著减少,此期间暴雨发生的时间更加分散.定义连续无雨的天数为干燥事件.发现虽然降水量没有显著的变化,但是严重干燥事件(连续0降水日≥10天)的频数却呈显著增加趋势(+8.3%/10a),超过99%信度水平.最高和最低的10%温度分别定义异常高温和异常低温,则异常高温的频数有显著增加趋势(+20.9%/10a),特别是1990年代后期以来增加非常突出.异常低温频次有减少的趋势(-15.1%/10a),超过99%信度水平.严重干燥事件及异常高温事件的强烈增加,可能是造成近来北方干旱频繁发生的重要原因.

中国玛珥湖及其研究意义

随着全球变化研究的深入,科学家们认识到古气候变化除轨道尺度的冰期/间冰期旋回之外还存在年代际-千年尺度的高频变化和突变事件。要认知这些变化,古气候记录的时间分辨率要达到"年-年代际"。因此,寻求时间跨度长、连续性好、信息丰富的高分辨率记录是过去全球变化研究面临的主要任务之一。玛珥湖为火山射汽喷发形成的封闭湖泊,由于其独特的形成机制及水文背景,使其能够提供数万年乃至几十万年连续稳定的沉积记录,是高分辨率古气候、古环境变化研究的重要对象。中国玛珥湖得天独厚,从热带到寒温带均有分布,为系统研究中国不同气候区各种时间尺度古气候变化规律提供了理想材料。本文基于中国玛珥湖的分布及沉积特征,探讨玛珥湖沉积记录能够为古全球变化研究做出怎样的贡献,解决什么科学问题,具体包括以下三个方面的内容:(1)在轨道尺度上,精确定位现代气候在地质历史中的位置是未来最具挑战性的科学问题之一。我国热带地区玛珥湖沉积物跨越了至少4个冰期-间冰期旋回,能够为理解冰期驱动机制、下一次冰期来临、高低纬关联等关键科学问题提供多学科数据;(2)千年尺度古气候变化,其成因可能源于不同的动力学机制,是气候系统对各种外部和内部驱动因子响应的结果,因此千年震荡可能存在明显的时空差异。集成不同气候带的玛珥湖沉积记录将为理解千年震荡规律及其驱动因子做出贡献;(3)年-年代际气候变化是预测未来气候变化的基础,PAGES、IPCC以及PAGES-Asia 2K均将过去2千年来气候变化作为预测未来几十年至百年尺度上重大全球变化的背景,并为此构建全球数据体系,玛珥湖沉积特别是纹层沉积记录能够填补某些地区高分辨率数据的空白。

长江中下游夏季降水异常变化与若干强迫因子的关系

首先，利用三次样条函数方法对1905-2000年长江中下游夏季降水量和太阳黑子、地球自转速率、赤道东太平洋海温和北极涛动等强迫因子序列进行年代际和年际尺度的分离，并分析了它们年代际尺度的位相变化特征。然后，使用30年滑动相关的方法，分析了长江中下游夏季降水量与上述各因子之间的相关随时间的变化。最后，利用旋转因子分析方法，对年代际及年际尺度因子的潜在结构对长江中下游夏季降水的影响进行了研究。结果表明，长江中下游夏季降水量和强迫因子序列均存在显著的年代际变化特征，它们之间的相关系数随时间变化呈现显著的阶段性，甚至出现相关位相的改变。影响长江中下游夏季降水异常的因子潜在结构主要包括以年代际尺度因子和海气年际尺度因子两类。在第一类因子结构中，太阳活动、地球自转速率和北极涛动的年代际变化贡献较大，其中太阳黑子的贡献最显著。20世纪40年代以后，年代际尺度因子的作用明显增强。在第二类因子结构中，前期秋季、同期夏季的赤道东太平洋海温及前期冬、春季北极涛动的年际变化对长江中下游夏季降水异常的贡献突出。

大洋间SST遥联与亚太夏季风异常的关系

用奇异值分解(Singular Value Decomposition,SVD)方法,给出了四季年代际和年际时间尺度上北大西洋和北太平洋海表温度(Sea Surface Temperature,SST)的显著遥相关。用SVD主模态时间系数构造了海温异常指数I,分析了它们与同期亚太夏季风和我国东部夏季降水异常的关系。结果表明:两大洋间的SST遥联在年际、年代际时间尺度上都与亚太夏季风相关,其中,年际尺度的两大洋SST遥联与长江流域的降水存在显著相关。

Climate modulation on sea surface height in China seas

The climate modulation on the sea surface height （SSH） in China seas is investigated using a China Ocean Reanalysis （CORA） dataset from 1958-2008. The dataset is constructed by assimilating the temperature/salinity profiles derived from the satellite altimetry data and historical observational temperature/salinity profiles. Based on the Empirical Orthogonal Function （EOF）, the CORA sea surface height anomaly （SSHa） is decomposed, and the interannual and decadal variability of the first three leading modes are analyzed. On the interannual timescale, the first principal component （PC1） is significant positively correlated with the E1 Nifio/Southern Oscillation （ENSO）. On the decadal timescale, North Pacific Gyre Oscillation （NPGO） has significant negative correlation with PC 1 whereas Pacific Decadal Oscillation （PDO） is in phase with PC3. Analysis shows that the decadal variability of SSH is mainly modulated by the wind stress curl variability related to the NPGO and PDO. In addition, the effect of net heat flux associated to the NPGO and PDO on SSH is also investigated, with net heat flux variability in the Luzon strait and tropic Pacific found to influence the decadal variability of SSH.

Variability of Tropical Cyclone in High Frequent Occurrence Regions over the Western North Pacific

In this study, three high frequent occurrence regions of tropical cyclones(TCs), i.e., the northern South China Sea(the region S), the south Philippine Sea(the region P) and the region east of Taiwan Island(the region E), are defined with frequency of TC's occurrence at each grid for a 45-year period(1965–2009), where the frequency of occurrence(FO) of TCs is triple the mean value of the whole western North Pacific. Over the region S, there are decreasing trends in the FO of TCs, the number of TCs' tracks going though this region and the number of TCs' genesis in this region. Over the region P, the FO and tracks demonstrate decadal variation with periods of 10–12 year, while over the region E, a significant 4–5 years' oscillation appears in both FO and tracks. It is demonstrated that the differences of TCs' variation in these three different regions are mainly caused by the variation of the Western Pacific Subtropical High(WPSH) at different time scales. The westward shift of WPSH is responsible for the northwesterly anomaly over the region S which inhibits westward TC movement into the region S. On the decadal timescale, the WPSH stretches northwestward because of the anomalous anticyclone over the northwestern part of the region P, and steers more TCs reaching the region P in the greater FO years of the region P. The retreating of the WPSH on the interannual time scale is the main reason for the FO's oscillation over the region E.

Southern Ocean SST Variability and Its Relationship with ENSO on Inter-Decadal Time Scales

Empirical orthogonal function （EOF） analysis reveals a co-variability of Sea surface temperatures （SSTs） in the Southern Hemisphere （0°-60°S）. In the South Indian and Atlantic Oceans, there is a subtropical dipole pattern slanted in the southwest-northeast direction. In the South Pacific Ocean, a meridional tripole structure emerges, whose middle pole co-varies with the dipoles in the South Indian and Atlantic Oceans and is used in this study to track subtropical Pacific variability. The South Indian and Atlantic Ocean dipoles and the subtropical Pacific variability are phase-locked in austral summer. On the inter-decadal time scales, the dipoles in the South Indian and Atlantic Oceans weaken in amplitude after 1979/1980. No such weakening is found in the subtropical South Pacific Ocean. Interestingly, despite the reduced amplitude, the correlation of the Indian Ocean and Atlantic dipoles with E1 Nino and Southern Oscillation （ENSO） are enhanced after 1979/1980. The same increase in correlation is found for subtropical South Pacific variability after 1979/1980. These inter-decadal modulations imply that the Southern Hemisphere participates in part of the climate shift in the late 1970s. The correlation between Southern Hemisphere SST and ENSO reduces after 2000.

Dominant modes of geopotential height in the northern hemisphere in summer on interdecadal timescales

Empirical orthogonal function （EOF） analysis is performed on the field of the northem hemisphere geopotential height at 200-hPa using a 54-year （1958-2011） record of summer data on an interdecadal time scale. The first dominant mode, which shows smooth semi-hemispheric variation with maximum action centers in the western hemisphere in the mid-latitudes over the eastern Pacific, North America, and the North Atlantic, is related to global warming. The second mode, which has a pronounced tropical-extratropical alternating pattern with active centers located over the eastern hemisphere from Western Europe across East Asia to the western Pacific, has a close relationship with the Arctic Oscillation. Further analysis results indicate that the two dominant modes show good correlation with the Arctic sea ice concentration （SIC）, with correlation coefficients between these two modes and the first two EOF modes of the Arctic SIC reaching 0.88 and 0.86, respectively.

Variability of Summer Monsoon Rainfall in India on Inter-Annual and Decadal Time Scales

Indian Summer Monsoon Rainfall （ISMR） exhibits a prominent inter-annual variability known as troposphere biennial oscillation.A season of deficient June to September monsoon rainfall in India is followed by warm sea surface temperature （SST） anomalies over the tropical Indian Ocean and cold SST anomalies over the westem Pacific Ocean.These anomalies persist until the following monsoon,which yields normal or excessive rainfall.Monsoon rainfall in India has shown decadal variability in the form of 30 year epochs of alternately occurring frequent and infrequent drought monsoons since 1841,when rainfall measurements began in India.Decadal oscillations of monsoon rainfall and the well known decadal oscillations in SSTs of the Atlantic and Pacific oceans have the same period of approximately 60 years and nearly the same temporal phase.In both of these variabilities,anomalies in monsoon heat source,such as deep convection,and middle latitude westerlies of the upper troposphere over south Asia have prominent roles.

Long Term Sea Level Change and Water Mass Balance in the South China Sea

Sea level anomalies observed by altimeter during the 1993-2006 period, thermosteric sea level anomalies estimated by using subsurface temperature data produced by Ishii and SODA reanalysis data, tide gauge records and HOAPS freshwater flux data were analyzed to investigate the long term sea level change and the water mass balance in the South China Sea, The altime- ter-observed sea level showed a rising rate of （3.5±0.9）mmyr-1 during the period 1993-2006, but this figure was considered to have been highly distorted by the relatively short time interval and the large inter-decadal variability, which apparently exists in both the thermosteric sea level and the observed sea level. Long term thermosteric sea level from 1945 to 2004 gave a rising rate of 0.15±0.06 mmyr-1. Tide gauge＇data revealed this discrepancy and the regional distributions of the sea-level trends. Both the ＇real＇ and the ther- mosteric sea level showed a good correspondence to ENSO： decreasing during El Nino years and increasing during La Nina years. Amplitude and phase differences between the ＇real＇ sea level and the thermosteic sea level were substantially revealed on both sea- sonal and interannual time scales. As one of the possible factors, the freshwater flux might play an important role in balancing the water mass.

MULTI-TIMESCALE VARIATIONS OF SOMALI JET AND ITS RELATION WITH PRECIPITATION IN CHINA

Based on the ERA reanalysis winds data, the multi-time scale variations of Somali jet are analyzed synthetically. The jet's influences on rainfall in China on interannual, interdecadal and sub-monthly scales are also studied using correlation and composite analyses. The results demonstrate that the interdecadal variations of the jet are significant.The Somali jet became weaker in the 1960 s and became the weakest in the early 1970 s before enhancing slowly in the late 1970 s. Moreover, the relation between the Somali jet and summer precipitation in China is close, but varies on different timescales. Preliminary analysis shows that the intensity variations in May and June during the early days of establishment are well correlated with summer precipitation in China. The Somali jet intensity on the interdecadal scale is closely related with interdecadal variations of the precipitation in China. Regardless of leading or contemporaneous correlation, the correlations between the Somali jet intensity and the rainfall in northern and southern China show obvious interdecadal variations. Moreover, the link between the anomalies of the jet intensity in May-August and precipitation evolution on synoptic scale in China is further studied. China has more rainfall with positive anomalies of the Somali jet but less rainfall with negative anomalies during the active period of the jet. The influence of positive Somali jet anomalies on China precipitation is more evident.