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1.
东亚海陆热力差指数与中国夏季降水的关系 总被引:9,自引:0,他引:9
定义了东亚海陆热力差指数(ILSTD),讨论了它与东亚夏季风的强弱年际变化及夏季降水的关系。结果表明:该海陆热力差指数较好地反映了我国东部季风区夏季降水的异常变化、强海陆热力差指数年,华北地区降水偏多,长江、淮河流域明显干旱;弱海陆热力差指数年,长江,淮河流域降水又异常偏多。TLSTD的异常变化对影响我国东部季风区降水的大气环流型具有较强的识别力,尤其是对夏季西太平洋副热带高压的位置与强度的识别。 相似文献
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亚洲冬夏季风对ENSO事件的响应 总被引:121,自引:26,他引:95
根据NCEP/NCAR_1980~1995年的再分析资料,分析了1980年以来5个El Ni?o和La Ni?a年冬、春和夏季200、500和850 hPa合成高度场、风场、流函数场及温度场。发现在冬季El Ni?o(La Ni?a)年亚洲上空的环流型不利(有利)于寒潮向南爆发,导致亚洲冬季风和大洋洲夏季风弱(强)。在El Ni?o(La Ni?a)年冬季华南和青藏高原降水或降雪量为正(负)距平,这使得在晚春和初夏南亚的加热慢(快),导致夏季海陆的热力对比小(大),因而出现弱(强)夏季风。我们还发现强El Ni?o年冬季,在印度洋-亚洲上空出现类似于东太平洋-北美上空的PNA遥相关,我们称之为印度洋-亚洲遥相关型(IA),引起亚洲冬夏季风年际变化的物理过程都是由IA遥相关型引起的。 相似文献
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大气环流的奇偶对称性(Ⅰ)理论依据和气候特征 总被引:1,自引:0,他引:1
文中使用奇偶对称分析方法,利用观测资料对全球环流的奇偶对称分量的分布做了分析,指出奇偶分布的气候特征及其时间演变能反映南北半球海陆差异带来的影响,揭示大气对辐射加热响应的时间尺度、环流的波动结构及全球环流季节性调整等一些特征。 相似文献
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气候平均状况下亚洲夏季风的季节内演变过程 总被引:5,自引:0,他引:5
根据1979—1995年美国NOAA的向外长波辐射逐日资料,用功率谱分析和带通滤波方法,对气候平均状况下亚洲夏季风的季节内演变过程进行分析,归纳得到亚洲季风区各个子系统季节内变化的8个关键阶段。利用1979—1999年NCEP/NCAR的大气环流再分析资料及中国气象局降水资料CMAP,对每个关键阶段亚洲夏季风的环流和降水的时空演变特征进行分析,得到亚洲季风区环流和降水季节内变化的物理图像。研究表明,在不同的季节内演变阶段,亚洲夏季风各个子系统成员的环流系统的变化特征可以将亚洲夏季风系统的季节内演变过程较好地描述出来。 相似文献
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本文通过对大气环流模式的平均气候模拟以及GCM敏感性试验,比较外部条件和内部反馈的相对贡献,研究了海陆温差和亚洲夏季风强度的基本概念。 相似文献
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亚洲夏季风建立格局和南海季风爆发特征及其成因初探 总被引:5,自引:1,他引:5
使用1980 ̄1986年欧洲中期预报中心(ECMWF)格点资料和1980 ̄1992年日本地球静止气象卫星(GMS)观测到的黑体辐射(TBB)资料,分析了南海季风爆发和亚洲夏季风建立格局及其可能机制。发现亚洲夏季风建立征兆最早出现在中南半岛-南海地区,随后自该地区分别向西、向东扩展;中南半岛地区是东亚季风和印度季风的天然分界线,其两侧夏季风的建立特征和形成机制迥然不同。亚洲夏季风自东向西逐渐建立的格 相似文献
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对43aNCEP/NCAR再分析资料和台站实际观测资料的分析,揭示了对流层温度变化和印度夏季风环流减弱之间的联系。印度夏季风的变化与东亚上空对流层温度具有密切的关系,主要表现为对流层平均温度与整个印度夏季降雨和季风环流强度之间存在显著的正相关。结果表明:印度夏季风环流在近几十年经历了两次减弱过程,第一次减弱约发生在20世纪60年代中期,第二次减弱则发生在20世纪70年代后期;通过改变海陆热力对比,对流层平均温度在印度夏季风减弱过程中可能起着重要作用,东亚地区与东印度洋至西太平洋热带地区之间的对流层温度差异导致了印度夏季风环流的减弱。 相似文献
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亚洲季风区是全球热力变化最为显著的区域,亚洲夏季风活动必定会对其它环流系统产生影响。本文通过夏季风指数与北半球环流的相关计算以及强、弱季风候北半球环流异常合成的分析发现,亚洲夏季风的活动会激发北半球夏季大气环流遥相关型,其主要相关中心均出现在季风区的下游地区,即从亚洲经太平洋至北美洲一带,除了表现出正负中心交替出现的波列状结构外,该遥相关型在太平洋地区还表现为一对南北向的偶极子异常型,我们将这一遥相关型称为亚洲太平洋北美(APN)型。 相似文献
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利用T42L9全球大气环流谱模式进行数值试验 ,以揭示南海夏季风强度异常的特征及其影响。控制试验结果表明 ,该模式不仅能够很好地模拟出气候平均的西风带槽脊和高低空气流分布以及它们的季节性变化 ,而且对于与亚洲季风有关的各个主要系统 ,如南亚高压、副高进退及越赤道气流等都有较强的模拟能力。在亚洲季风区及热带太平洋这一大范围区域的大气内部热源异常强迫下 ,模式显示出了南海夏季风持续异常的特征、北半球热带外环流的响应以及亚洲季风区降水异常分布。南海夏季风长时间强度异常所引起的大气内部热源异常 ,一方面通过三维垂直环流的异常联结着南海夏季风对北半球热带内外环流的影响 ,另一方面它又通过持续异常期的波列传播 ,即能量的传播 ,不仅影响我国长江流域降水 ,还会逐渐影响到北半球中高纬环流结构。这样西风带环流形势将会发生相应的变化和调整 ,南海夏季风持续异常影响到了北半球大气环流和天气气候的变化。 相似文献
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青藏高原地区大气顶净辐射与地表净辐射的关系 总被引:14,自引:0,他引:14
地表净辐射为地气系统净辐射与大气层净辐射之差。对大气层净辐射作不同的假定,可将地表净辐射与大气顶辐射收支之间的关系表示成不同的形式。本文利用1982年8月—1983年7月青藏高原地区地面辐射收支观测资料及同期NOAA-7辐射收支资料,用统计方法讨论了大气顶净辐射与地表净辐射之间的相关性,建立了两者之间的回归方程,并在此基础上分析了青藏高原地区月平均地表净辐射的时空分布特征。 相似文献
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LUO Huibang 《Acta Meteorologica Sinica》2000,14(2):200-209
Values of the net radiative heating(QRT)at the top of atmosphere(TOA) are derived from the satellite-observed outgoing long wave radiation(OLR)and the TOA short wave net irradiance (SHT) for the region of the Tibetan Plateau and surrounding areas(40°S-40°N,0-180°E)and the period of months from January 1979 to December 1988.The anomalous QRT(QRTA)in relation to the interannual variability of Asian monsoon is discussed.QRTA for the earth-atmosphere system in the domain may be linked to the thermal contrasts between continents and oceans and between the plateau and surrounding free atmosphere. 相似文献
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利用卫星和再分析数据,评估了区域气候模式Reg CM4对中国东部地区辐射收支的基本模拟能力,重点关注地表净短波(SNS)、地表净长波(SNL)、大气顶净短波(TNS)、大气顶净长波(TNL)4个辐射分量。结果表明:1)短波辐射的误差值在夏季较大,而长波辐射的误差值在冬季较大。但各辐射分量模拟误差的空间分布在冬、夏季都有较好的一致性。2)对于地表辐射通量,SNS表现为正偏差(向下净短波偏多),在各分量中误差最大,区域平均误差值近50 W/m2;SNL表现为负偏差(向上净长波偏多);对于大气顶辐射通量,TNS和TNL分别表现为"北负南正"的误差分布和整体正偏差。3)利用空间相关和散点线性回归方法对4个辐射分量的模拟误差进行归因分析,发现在云量、地表反照率、地表温度三个直接影响因子中,云量模拟误差的贡献最大,中国东部地区云量模拟显著偏少。 相似文献
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中国地区云对地-气系统辐射强迫温度效应的气候研究 总被引:4,自引:2,他引:4
文中利用地球辐射平衡试验 (ERBE)和国际卫星云气候计划 (ISCCP)提供的地 气系统行星反射率、射出长波辐射 (OLR)和云量资料 ,计算了中国地区年、月平均总云量对地 气系统短波辐射、长波辐射以及净辐射强迫的温度效应和敏感性系数 ,并讨论了云对各辐射分量强迫的温度效应与总云量的关系。结果表明 :地 气系统云辐射强迫温度效应与总云量间具有较明显的曲线相关。云辐射强迫温度效应及其敏感性系数具有明显的时空变化特点。就中国全国平均而言 ,各月地 气系统云辐射强迫净温度效应一般表现为降温作用。 相似文献
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基于云和地球辐射能量系统观测数据集(CERES),对比分析了耦合模式比较计划第五(CMIP5)和第六阶段(CMIP6)模拟的历史大气层顶和地表辐射收支的年际变化和空间分布,明确了多模式间不确定性大的关键区域。结果表明:在年际尺度上,除地表向上长波辐射外,CMIP6的辐射分量的集合均值较CMIP5更接近于CERES观测值,全球地表向下短波辐射的高估和大气逆辐射的低估在CMIP6中分别降低了1.9 W/m2和3.3 W/m2。除大气逆辐射外,CMIP6的辐射分量在多模式间的一致性较CMIP5提高。在北极,CMIP6对大气层顶反射短波、大气层顶出射长波和地表向下短波辐射的模拟偏差较CMIP5大。在南北纬60°,CMIP6对大气逆辐射的模拟偏差较CMIP5大。其他区域CMIP6的辐射分量更接近CERES观测值。CMIP6模拟的地表向下短波辐射和大气逆辐射的不确定性较大区域面积较CMIP5减小,但不确定性极大区域面积无变化。地表净辐射的不确定性空间分布在两代CMIP间变化甚小。青藏高原、赤道太平洋、热带雨林、阿拉伯半岛和南极洲沿海依然是地球系统模式模拟辐射收支不确定性极大的关键区域。 相似文献
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Summary The concept of effective cloud cover, elaborated on the basis of an assumption that changes in the net radiation at the top of the atmosphere are mainly caused by changing cloudiness, has been used to deduce solar surface radiation from satellite data. It has been shown that the method permits a calculation of solar surface absorption distributions that agree well with the results obtained by other authors and that the existing disagreement can be to a great extent ascribed to the differences in the data sets and analysis periods. The method allows use of early satellite measurements to get longer time series of the surface radiation budget. In this study, it has been applied to the Nimbus-7 ERB WFOV data for 1979–1986.The net solar flux at the TOA (top of the atmosphere) can be partitioned into absorption at the surface and within the atmosphere. The geographical distributions of all the three quantities as well as the zonal averages of the surface absorption for January and July have been described. Special objectives of the present study are to estimate the interannual standard deviation for the 8-year period and to analyse the shortwave cloud-radiative forcing distributions at the surface and especially within the atmosphere.The standard deviation of the TOA and the surface solar absorption shows a temporal asymmetry, being much larger in January than in July. Noticeable is the disappearance of the wintertime strong variability over the central Pacific in July. As can be expected, the strong variability areas coincide with the strong variability areas of the cloud amount, showing the values up to 27 Wm–2 at the surface.According to our estimate, the shortwave cloud forcing at the surface is everywhere stronger than that at the TOA, so that the cloud forcing of the atmosphere is negative. This means that in the belt of 58.5° N–58.5° S a cloudy atmosphere absorbs more solar energy than a cloud-free atmosphere. Our mean annual value of the atmospheric cloud forcing for this belt is –11 Wm–2 which is somewhat stronger than that obtained by other investigators. It must be stressed that this value is within the uncertainty limits.Shortwave cloud forcing of the atmosphere is the strongest in the lower latitude areas of heavy cloudiness above the continents and negligible in the midlatitudes in winter. This gives evidence that the value of the shortwave cloud forcing of the atmosphere is modified by a combination of cloud absorption and cloud albedo.With 4 Figures 相似文献
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Lei WANG Qing BAO Wei-Chyung WANG Yimin LIU Guo-Xiong WU Linjiong ZHOU JiANDong LI Hua GONG Guokui NIAN Jinxiao LI Xiaocong WANG Bian HE 《大气科学进展》2019,(7):697-710
Cloud dominates influence factors of atmospheric radiation, while aerosol–cloud interactions are of vital importance in its spatiotemporal distribution. In this study, a two-moment(mass and number) cloud microphysics scheme, which significantly improved the treatment of the coupled processes of aerosols and clouds, was incorporated into version 1.1 of the IAP/LASG global Finite-volume Atmospheric Model(FAMIL1.1). For illustrative purposes, the characteristics of the energy balance and cloud radiative forcing(CRF) in an AMIP-type simulation with prescribed aerosols were compared with those in observational/reanalysis data. Even within the constraints of the prescribed aerosol mass, the model simulated global mean energy balance at the top of the atmosphere(TOA) and at the Earth's surface, as well as their seasonal variation, are in good agreement with the observational data. The maximum deviation terms lie in the surface downwelling longwave radiation and surface latent heat flux, which are 3.5 W m-2(1%) and 3 W m-2(3.5%), individually. The spatial correlations of the annual TOA net radiation flux and the net CRF between simulation and observation were around 0.97 and 0.90, respectively. A major weakness is that FAMIL1.1 predicts more liquid water content and less ice water content over most oceans. Detailed comparisons are presented for a number of regions, with a focus on the Asian monsoon region(AMR). The results indicate that FAMIL1.1 well reproduces the summer–winter contrast for both the geographical distribution of the longwave CRF and shortwave CRF over the AMR. Finally, the model bias and possible solutions, as well as further works to develop FAMIL1.1 are discussed. 相似文献
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南半球中高纬度区域不同类型云的辐射特性 总被引:1,自引:0,他引:1
利用CloudSat的2B-CLDCLASS-LIDAR云分类产品和2B-FLXHR-LIDAR辐射产品4 a(2007-2010年)的数据,定量分析了单层云(高云、中云、低云)和3种双层云(如:高云与中云共存、高云与低云共存以及中云与低云共存)在南半球中高纬度(40°-65°S)的云量、云辐射强迫和云辐射加热率。其中云辐射加热率定义为有云时的大气加热率廓线与晴空大气加热率廓线的差值。结果表明:研究区域盛行单层低云和单层中云,其云量分别为44.1%和10.3%。并且,中云重叠低云在双层云中云量也是最大(8.7%)。不同类型云的云量也显著影响着其云辐射强迫。单层低云在大气层顶、地表以及大气中的净云辐射强迫分别是-64.8、-56.5和-8.4 W/m2,其绝对值大于其他类型云。虽然单层的中云在大气层顶和地表的净辐射强迫也为负值,但其在大气中的净云辐射强迫为正值(2.3 W/m2)。最后,讨论了不同类型云对大气中辐射能量垂直分布的影响。所有类型云的短波(或长波)云辐射加热率都随高度升高表现为由负值转为正值(或由正值转为负值)。对于大部分云,其净云辐射加热率主要由长波云辐射加热率决定。这些研究结果旨在为模式中云重叠参数化方案在区域的适用性评估及改进提供观测依据。 相似文献
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Cloud–radiation processes play an important role in regional energy budgets and surface temperature changes over arid regions. Cloud radiative effects (CREs) are used to quantitatively measure the aforementioned climatic role. This study investigates the characteristics of CREs and their temporal variations over three arid regions in central Asia (CA), East Asia (EA), and North America (NA), based on recent satellite datasets. Our results show that the annual mean shortwave (SW) and net CREs (SWCRE and NCRE) over the three arid regions are weaker than those in the same latitudinal zone of the Northern Hemisphere. In most cold months (November–March), the longwave (LW) CRE is stronger than the SWCRE over the three arid regions, leading to a positive NCRE and radiative warming in the regional atmosphere–land surface system. The cold-season mean NCRE at the top of the atmosphere (TOA) averaged over EA is 4.1 W m–2, with a positive NCRE from November to March, and the intensity and duration of the positive NCRE is larger than that over CA and NA. The CREs over the arid regions of EA exhibit remarkable annual cycles due to the influence of the monsoon in the south. The TOA LWCRE over arid regions is closely related to the high-cloud fraction, and the SWCRE relates well to the total cloud fraction. In addition, the relationship between the SWCRE and the low-cloud fraction is good over NA because of the considerable occurrence of low cloud. Further results show that the interannual variation of TOA CREs is small over the arid regions of CA and EA, but their surface LWCREs show certain decreasing trends that correspond well to their decreasing total cloud fraction. It is suggested that combined studies of more observational cloud properties and meteorological elements are needed for indepth understanding of cloud–radiation processes over arid regions of the Northern Hemisphere. 相似文献