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1.
大气环流模式IAP AGCM4.0对东亚高空副热带西风急流的模拟及偏差原因分析 总被引:1,自引:1,他引:0
基于中国科学院大气物理所大气环流模式IAP AGCM4.0总共30年(1979~2008年)的AMIP(大气环流模式比较计划)数值模拟试验结果,评估了模式对东亚高空副热带西风急流的模拟能力,分析了模式模拟偏差的可能原因,以及不同对流参数化方案对模拟结果的影响。结果表明,IAP AGCM4.0可以较好地模拟出东亚高空副热带西风急流冬季和夏季的空间结构及其季节变化特征;与JRA-25再分析资料相比,模式模拟的急流强度总体偏弱;就急流位置而言,模式模拟的急流位置冬季略偏南,夏季则相对偏北;模式可以较好地模拟出夏季西风急流的季节内演变特征,包括夏季西风急流位置逐月北跳的特征,只是模式模拟的逐月西风急流位置仍偏北。夏季200 h Pa纬向风EOF分解结果表明,模式模拟和再分析资料的EOF第一模态空间型态较为接近,均反映了西风急流的年际变化特征,但两者的时间系数相关较小,表明模式对西风急流南北位置年际变化的模拟偏差较大。针对模式模拟的地表感热通量及对流层中上层经向温度差(MTD)的分析结果表明,模式对阿拉伯半岛东南部、阿拉伯海西北部及印度北部的地表感热通量的模拟存在偏差,影响到对流层中高层温度场、高度场的模拟,使得IAP AGCM4.0模拟的MTD强度较再分析资料相对偏弱,MTD变化最大的区域位置相对偏北,且模式模拟的MTD年际变化与再分析资料相比也有较大偏差,从而造成模式对西风急流模拟的偏差。此外,不同积云对流参数化方案也可影响对流层中上层经向温度差的模拟,进而影响模式对东亚高空副热带西风急流的模拟。 相似文献
2.
P-σ区域气候模式对东亚副热带西风急流的数值模拟 总被引:1,自引:0,他引:1
为评估P-σ九层区域气候模式模拟对流层上层东亚副热带西风急流季节变化的能力,比较模式模拟的东亚副热带西风急流季节变化与NCEP/NCAR再分析资料之间的差异及其与对流层中上层大气南北温度差异的关系。结果表明,模式模拟东亚副热带西风急流的能力在洋面上空强于大陆上空,模拟低纬度急流的能力好于高纬度。模拟的东亚副热带西风急流垂直结构、水平结构和季节变化等的主要特征与NCEP/NCAR再分析资料基本一致,但模拟的急流强度全年偏弱。分析急流与对流层中上层经向温度梯度的季节变化发现,急流出现的位置总是对应着经向温度梯度较大区域,急流中心有随气温南北差异大值中心移动的趋势,急流中心与最大温差中心相对应,表明急流中心的位置变化是对气温南北差异季节变化的响应。与再分析资料相比,模拟的经向温度梯度比再分析资料偏小约2K/10纬距,与此相对应的模拟的急流中心风速偏小约10 m.s-1。由于大气温度变化与非绝热加热有关,进一步分析发现,模式模拟的夏季副热带急流偏差与东亚地区的地面感热及潜热等非绝热加热的模拟偏差具有密切的关系。 相似文献
3.
FGOALS模式对梅雨期东亚副热带西风急流变化特征的模拟 总被引:1,自引:0,他引:1
中国科学院大气物理研究所参与CMIP5项目的海—陆—气耦合气候系统模式(FGOALS),能较好地模拟东亚副热带西风急流时空变化特征。FGOALS模式输出的1960~2005年风场再现了梅雨期东亚副热带西风急流气候态的三维结构,模拟出以120°E为界的急流海陆分布型,与NCEP/NCAR再分析资料风场空间分布一致,但FGOALS模式模拟的急流中心强度偏弱、位置偏北偏西。FGOALS模式也模拟出了ENSO年际演变过程中的海陆空间分布型,但对ENSO背景下西风急流强度、位置和形态演变过程的模拟与NCEP/NCAR再分析资料存在较大差异。基于热成风原理、地转风关系和波活动通量等研究了模式模拟急流位置和强度偏差产生的可能原因:FGOALS模式模拟的青藏高原加热效应偏弱、低纬度对流活动偏弱,导致对流层中上层上升运动偏弱和潜热加热减弱,使得中低纬度对流层中上层温度出现冷偏差、南亚高压偏弱,温度经向梯度和南亚高压北侧气压梯度力偏弱以及大气内部动力作用偏弱,从而造成急流中心强度和位置出现偏差。梅雨期西风急流空间分布型与长江中下游强降水落区有着密切联系,FGOALS模式模拟的西风急流中心强度偏弱和位置偏北偏西,模式输出的长江中下游地区降水量与观测值相比偏少。此外,FGOALS模式对ENSO背景下大气环流异常的模拟有待改善。 相似文献
4.
一个气候系统模式FGCM0对东亚副热带西风急流季节变化的模拟 总被引:2,自引:1,他引:2
对IAP/LASG气候系统模式试验版(FGCM0)模拟对流层上层东亚副热带西风急流季节变化的能力进行评估, 分析FGCM0模拟的东亚副热带西风急流季节变化与NCEP/NCAR再分析资料的差异及其与对流层大气南北温差的关系.结果表明, FGCM0模拟的冬季和夏季西风急流垂直结构、水平结构和季节变化与NCEP/NCAR再分析资料基本一致, 但FGCM0模拟的东亚副热带西风急流在高原附近地区冬季和夏季都偏强, 沿115°E中国大陆地区上空模拟的急流强度冬季偏弱, 夏季明显偏强.夏季FGCM0模拟的急流中心位于高原东北部的40°N附近地区, 强度偏强, 位置偏东, 而此时NCEP/NCAR再分析资料中的急流中心却位于高原北侧.此外, FGCM0模拟的急流在5月份的北移和8月份的最北位置上与NCEP/NCAR再分析资料差异较大.分析副热带西风急流与对流层南北温差的季节变化发现, 急流出现的位置总是对应着对流层南北温度差较大区域, 与再分析资料相比, FGCM0模拟的温度差在冬季基本一致, 夏季差异较大.与降水的模拟相联系发现, FGCM0模拟得到的与实际不一致的偏西偏北的强降水中心与200 hPa上的东亚副热带急流位置和强度不合理具有密切关系.相关分析表明, 冬季西风急流强度与日本南部海区的感热通量、夏季与青藏高原地区的地面感热通量有明显的正相关关系, 而FGCM0能够较好地模拟冬季西风急流强度与地面感热通量之间的相关关系, 但模拟夏季青藏高原地区感热通量和副热带西风急流之间相关关系的能力相对较差, 夏季西风急流强度与OLR之间却有一定的关系.由于与强降水区相联系的OLR低值区对应着较大的对流凝结加热, 再加上模式中位于青藏高原东南部较大的地面感热加热, 增强了对流层的南北向温度差, 进而影响东亚副热带急流强度和位置.因此, FGCM0模拟的夏季副热带急流位置和强度偏差与高原附近地区的地面感热加热、大气射出长波辐射等的模拟偏差具有密切的关系. 相似文献
5.
基于大涡模拟对两类典型边界层参数化方案的评估分析 总被引:1,自引:0,他引:1
《高原气象》2016,(1)
在WRF模式的三维动力框架和同一种外强迫下,基于大涡模拟结果对Yonsei University(YSU)和Mellor-Yamada-Janiic(MYJ)边界层参数化方案进行了评估。模式初始场由一个探空观测给定,模式的外强迫为观测得到随时间变化的地面感热、潜热通量及辐射传输模式得到的辐射冷却率。通过显式解析边界层的大涡模拟试验和采用边界层参数化方案的模拟试验结果表明,与大涡模拟结果相比,YSU方案模拟的混合偏强,MYJ方案偏弱;YSU方案模拟的边界层高度偏高,边界层内偏暖、偏干;MYJ方案模拟的边界层高度偏低,边界层内偏冷、偏湿。 相似文献
6.
热带加热异常影响冬季平流层极涡强度的数值模拟 总被引:1,自引:0,他引:1
本文利用大气环流模式SAMIL/LASG,通过选择两种对流参数化方案,研究了热带加热异常对热带外平流层模拟的影响。结果表明,因不同对流参数化方案引起的热带对流加热状况的差异,可显著影响模式对北半球冬季平流层极涡强度的模拟偏差。与采用Manabe对流参数化方案相比,采用Tiedtke参数化方案可以显著改善对平流层极涡强度的模拟,使平流层极涡“过强”及极区“过冷”的模拟偏差得到明显改善。研究其中的影响过程发现,由于Manabe方案最大凝结潜热加热高度过低,在对流层中低层;而Tiedtke方案的最大凝结潜热加热位置在对流层中上层,因而Tiedtke(Manabe)方案时热带大气温度在对流层中上层较为偏暖(偏冷),在平流层低层较为偏冷(偏暖)。自秋季开始,与热带对流层高层温度的暖偏差相联系,热带外对流层高层以及热带平流层低层出现伴随的温度冷偏差;与之对应,平流层中纬度从秋季开始也出现持续的温度暖偏差。另外,随着秋冬季节平流层行星波活动的出现,Tiedtke方案时热带外地区行星波1波的强度也明显强于Manabe方案,使得秋冬季节涡动引起的向极热通量在Tiedtke方案时明显偏强,从而造成了冬季平流层极区温度偏暖、极涡强度偏弱。 相似文献
7.
耦合模式FGOALS_s模拟的东亚夏季风 总被引:9,自引:6,他引:3
本文评估了中国科学院大气物理研究所大气科学和地球流体力学数值模拟国家重点实验室的海气耦合模式FGOALS_s对东亚夏季风的模拟能力, 并通过与观测海温强迫下单独大气模式SAMIL试验结果的比较, 分析了海气耦合过程对模式性能的影响。结果表明, FGOALS_s基本能够模拟出东亚夏季风系统的气候态分布及其演变过程, 但也存在明显偏差, 主要表现为模拟的温度场在对流层中上层一致性偏冷, 导致模式中环流系统强度偏弱; 而温度经向梯度模拟的不足, 直接影响到东亚副热带西风急流的模拟。通过与观测海温强迫下SAMIL模拟结果的对比发现, SAMIL模拟的温度场、 环流场以及风场较之耦合模式结果更接近观测, 但也存在与FGOALS_s类似的模式偏差。因此, 大气模式固有的偏差对耦合模式的模拟偏差有重要影响。分析发现, 对于西太平洋降水的模拟而言, 耦合模式结果更加合理, 表明海气相互作用过程对模式性能有重要影响。本文的结果表明, 大气模式自身的误差是导致耦合模式误差的主要原因。通过更新云-辐射模块改进大气模式模拟的温度场, 应是FGOALS_s后续发展的首要工作。 相似文献
8.
两个大气环流模式SAMIL和BCC_AGCM对北半球冬季极涡振荡的模拟对比 总被引:1,自引:1,他引:1
基于与NCEP再分析资料的比较, 本文利用大气环流模式SAMIL和北京气候中心大气环流模式BCC_AGCM的1950~1999年的AMIP试验模拟数据, 对北半球冬季环流及平流层极涡振荡的模拟性能进行了评估分析。结果表明两个模式都可以再现北半球环流基本型以及环流振荡的主导模态。对冬季气候平均态的模拟, 两个模式模拟的热带—热带外温度梯度均偏大, 极夜急流偏强, 极涡偏冷偏强;100~20 hPa平均位势高度场谐波分析表明两个模式模 拟的行星波偏弱;气候平均的10 hPa极夜急流均存在1个月的季节漂移, 200 hPa副热带西风急流较NCEP偏弱。两个模式模拟的环流变化的主导模态均代表极涡振荡, SAMIL极涡振荡的强度大于BCC_AGCM, BCC_AGCM极涡振荡的频率要高于SAMIL。连续功率谱分析表明, NCEP资料中极涡振荡存在4.6个月的显著周期, 相应地, SAMIL中为5.5个月的显著周期, BCC_AGCM中为4.8个月。NCEP资料中的极涡振荡主要发生在12~3月, SAMIL模拟的极涡振荡主要发生在2~3月, BCC_AGCM模拟的极涡振荡主要发生在2~4月。 相似文献
9.
利用NCEP/NCAR月平均再分析资料,采用奇异值分解方法分析200 hPa纬向风场与东亚地表加热场的空间耦合变化特征,揭示影响东亚副热带西风急流位置及强度变化的加热关键区域。研究结果表明,冬季西太平洋黑潮暖流区是表面感热、潜热通量场的大值区,其加热强度主要影响东亚副热带西风急流的强度变化,当加热增强(减弱)时,急流加强(减弱)。热带和副热带地区地表加热的反相变化对应纬向风的整体一致变化,且影响关键区在热带地区, 这种耦合分布型主要体现为年代际的变化特征。夏季,海陆感热加热差异主要影响中低纬纬向风的变化,而影响急流位置南北移动的加热关键区位于阿拉伯海及印度半岛北部,这种加热分布体现感热的局地性变化,可能与高原大地形分布有关。由于夏季降水的不均匀性,潜热加热与200 hPa纬向风场的耦合关系较为复杂。通过分析加热异常年的环流形势差异发现,对流层中上层经向温差对地表加热场异常变化的响应是导致高层纬向风变化的原因,这种地面加热变化导致高层温度场及流场的响应可通过热力适应理论得到较好的解释。 相似文献
10.
大气环流模式和耦合模式模拟的降水-海温关系之比较 总被引:9,自引:6,他引:3
本文讨论了气候系统耦合模式FGOALS_s模拟的局地降水和海温的关系, 并通过与单独大气模式SAMIL的AMIP试验结果进行对比分析, 考察了海气耦合过程对局地降水和海温关系模拟的影响。结果表明, 耦合模式FGOALS_s和单独大气模式SAMIL在模拟局地降水和海温关系上各有优势。在赤道中东太平洋地区, 观测中局地降水和海温的关系是海洋强迫为主, FGOALS_s模拟的海洋对大气的强迫比观测偏弱, 因此, SAMIL相对于FGOALS_s更有优势。在西北太平洋东部地区, 观测中夏秋季节降水和海温的关系是大气强迫为主, 由于考虑了海气相互作用过程, FGOALS_s对降水和海温关系的模拟能力要优于单独的大气模式。此外, 由于大气模式SAMIL的云参数化方案导致的模拟偏差, 在赤道中东太平洋地区 (9~11月), 降水增加时入射的短波辐射通量也是增加的, 并且这种模拟的偏差在耦合后仍然保留了下来, 导致了与观测不符的云[CD*2]辐射反馈过程。因此, 改进大气模式的云参数化方案是未来工作重点之一。此外, 分析发现耦合模式模拟的潜热通量的变化过分依赖海气湿度差。 相似文献
11.
The simulation characteristics of the seasonal evolution of subtropical anticyclones in the Northern Hemisphere are documented for the Flexible Global Ocean-Atmosphere-Land Systemmodel, Spectral Version 2 (FGOALS-s2), developed at the State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics, the Institute of Atmospheric Physics. An understanding of the seasonal evolution of the subtropical anticyclones is also addressed. Compared with the global analysis established by the European Centre for Medium-Range Forecasts, the ERA-40 global reanalysis data, the general features of subtropical anticyclones and their evolution are simulated well in both winter and summer, while in spring a pronounced bias in the generation of the South Asia Anticyclone(SAA) exists. Its main deviation in geopotential height from the reanalysis is consistent with the bias of temperature in the troposphere. It is found that condensation heating (CO) plays a dominant role in the seasonal development of the SAA and the subtropical anticyclone over the western Pacific (SAWP) in the middle troposphere. The CO biases in the model account for the biases in the establishment of the SAA in spring and the weaker strength of the SAA and the SAWP from spring to summer. CO is persistently overestimated in the central-east tropical Pacific from winter to summer, while it is underestimated over the area from the South China Sea to the western Pacific from spring to summer. Such biases generate an illusive anticyclonic gyre in the upper troposphere above the middle Pacific and delay the generation of the SAA over South Asia in April. In midsummer, the simulated SAA is located farther north than in the ERA-40 data owing to excessively strong surface sensible heating (SE) to the north of the Tibetan Plateau. Whereas, the two surface subtropical anticyclones in the eastern oceans during spring to summer are controlled mainly by the surface SE over the two continents in the Northern Hemisphere, which are simulated reasonably well, albeit with their centers shifted westwards owing to the weaker longwave radiation cooling in the simulation associated with much weaker local stratiform cloud. Further improvements in the related parameterization of physical processes are therefore identified. 相似文献
12.
Performances of two LASG/IAP(State Key Laboratory of Numerical Modeling for Atmospheric Sci- ences and Geophysical Fluid Dynamics/Institute of Atmospheric Physics)Atmospheric General Circulation Models(AGCMs),namely GAMIL and SAMIL,in simulating the major characteristics of the East Asian subtropical westerly jet(EASWJ)in the upper troposphere are examined in this paper.The mean vertical and horizontal structures and the correspondence of the EASWJ location to the meridional temperature gradient in the upper troposphere are well simulated by two models.However,both models underestimate the EASWJ intensity in winter and summer,and are unable to simulate the bimodal distribution of the ma- jor EASWJ centers in mid-summer,relative to the observation,especially for the SAMIL model.The biases in the simulated EASWJ intensity are found to be associated with the biases of the meridional temperature gradients in the troposphere,and furthermore with the surface sensible heat flux and condensation latent heating.The models capture the major characteristics of the seasonal evolution of the diabatic heating rate averaged between 30°-45°N,and its association with the westerly jet.However,the simulated maximum diabatic heating rate in summer is located westward in comparison with the observed position,with a rela- tively strong diabatic heating intensity,especially in GAMIL.The biases in simulating the diabatic heating fields lead to the biases in simulating the temperature distribution in the upper troposphere,which may further affect the EASWJ simulations.Therefore,it is necessary to improve the simulation of the meridional temperature gradient as well as the diabatic heating field in the troposphere for the improvement of the EASWJ simulation by GAMIL and SAMIL models. 相似文献
13.
The seasonal variations of the Asian monsoon were explored by applying the atmospheric general circulation model R42L9 that was developed recently at the State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics, Institute of Atmospheric Physics, Chinese Academy of Sciences (LASG/IAP/CAS). The 20-yr (1979-1998) simulation was done using the prescribed 20-yr monthly SST and sea-ice data as required by Atmospheric Model Intercomparison Project (AMIP)Ⅱ in the model. The monthly precipitation and monsoon circulations were analyzed and compared with the observations to validate the model‘s performance in simulating the climatological mean and seasonal variations of the Asian monsoon. The results show that the model can capture the main features of the spatial distribution and the temporal evolution of precipitation in the Indian and East Asian monsoon areas. The model also reproduced the basic patterns of monsoon circulation. However, some biases exis tin this model. The simulation of the heating over the Tibetan Plateau in summer was too strong. The overestimated heating caused a stronger East Asian monsoon and a weaker Indian monsoon than the observations. In the circulation fields, the South Asia high was stronger and located over the Tibetan Plateau. The western Pacific subtropical high was extended westward, which is in accordance with the observational results when the heating over the Tibetan Plateau is stronger. Consequently, the simulated rainfall around this area and in northwest China was heavier than in observations, but in the Indian monsoon area and west Pacific the rainfall was somewhat deficient. 相似文献
14.
Influence of the Tibetan Plateau on the Summer Climate Patterns over Asia in the IAP/LASG SAMIL Model 总被引:2,自引:0,他引:2
A series of numerical experiments are carried out by using the Spectral Atmospheric Model of State Key Laboratory of Numerical Modeling Atmospheric Sciences and Geophysical Fluid Dynamics/Institute of Atmospheric Physics (SAMIL) to investigate how the Tibetan Plateau (TP) mechanical and thermal forcing affect the circulation and climate patterns over subtropical Asia. It is shown that, compared to mechanical forcing, the thermal forcing of TP plays a dominant role in determining the large-scale circulation in summer. Both the sensible heating and the latent heating over TP tend to generate a surface cyclonic circulation and a gigantic anticyclonic circulation in the mid- and upper layers, whereas the direct effect of the latter is much more significant. Following a requirement of the time-mean quasi-geostrophic vorticity equation for large-scale air motion in the subtropics, convergent flow and vigorous ascending motion must appear to the east of TP. Hence the summer monsoon in East China is reinforced efficiently by TP. In contrast, the atmosphere to the west of TP is characterized by divergent flow and downward motion, which induces the arid climate in Mid-Asia. 相似文献
15.
16.
SAMIL大气环流模式海面湍流通量参数化方案研究 总被引:1,自引:1,他引:0
将中国科学院大气物理研究所大气科学和地球流体力学数值模拟国家重点实验室发展的大气环流谱模式SAMIL_R42L26 2.08中的海气通量参数化方案——Louis方案, 与新发展的一种新型近海层湍流通量参数化方案——LGLC方案进行比较和分析。离线测试结果表明, LGLC方案计算的通量结果与观测数据具有更好的一致性, 且由于其区分热力粗糙度和动力粗糙度, 使得对热量通量的计算更加准确。在线测试则证明, 引入LGLC方案的SAMIL模式对洋面风应力、 感热通量、 潜热通量和降水率的模拟能力有了进一步的提高, 尤其对北半球夏季印度季风和南海季风区的降水改善明显。 相似文献
17.
Spring Arctic Oscillation-East Asian summer monsoon connection through circulation changes over the western North Pacific 总被引:5,自引:0,他引:5
Dao-Yi Gong Jing Yang Seong-Joong Kim Yongqi Gao Dong Guo Tianjun Zhou Miao Hu 《Climate Dynamics》2011,37(11-12):2199-2216
In the present study the links between spring Arctic Oscillation (AO) and East Asian summer monsoon (EASM) was investigated with focus on the importance of the North Pacific atmospheric circulation and sea surface temperature (SST). To reduce the statistical uncertainty, we analyzed high-pass filtered data with the inter-annual time scales, and excluded the El Ni?o/Southern Oscillation signals in the climate fields using a linear fitting method. The significant relationship between spring AO and EASM are supported by the changes of multi-monsoon components, including monsoon indices, precipitation, and three-dimensional atmospheric circulations. Following a stronger positive spring AO, an anomalous cyclonic circulation at 850?hPa appears in southeastern Asia and the western North Pacific in summer, with the easterly anomalies spanning from the Pacific to Asian continent along 25°N?C30°N and the westerly anomalies south of 15°N. At the same time, the summer western North Pacific subtropical high becomes weaker. Consistently, the positive precipitation anomalies are developed over a broad region south of 30°N stretching from southern China to the western Pacific and the negative precipitation anomalies appear in the lower valley of the Yangtze River and southern Japan. The anomalous cyclone in the western North Pacific persisting from spring to summer plays a key role in modulating EASM and monsoon precipitation by a positive air-sea feedback mechanism. During spring the AO-associated atmospheric circulation change produces warmer SSTs between 150°E?C180° near the equator. The anomalous sensible and latent heating, in turn, intensifies the cyclone through a Gill-type response of the atmosphere. Through this positive feedback, the tropical atmosphere and SST patterns sustain their strength from spring to summer, that consequently modifies the monsoon trough and the western North Pacific subtropical high and eventually the EASM precipitation. Moreover, the SST response to AO-circulation is supported by the numerical simulations of an ocean model, and the anomalous atmospheric circulation over the western North Pacific is also reproduced by the dedicated numerical simulations using the coupled atmosphere?Cocean model. The observation evidence and numerical simulations suggest the spring AO can impact the EASM via triggering tropical air-sea feedback over the western North Pacific. 相似文献
18.
Yuyang GUO Yongqiang YU Pengfei LIN Hailong LIU Bian HE Qing BAO Bo AN Shuwen ZHAO Lijuan HUA 《大气科学进展》2020,37(10):1133-1148
This study documents simulated oceanic circulations and sea ice by the coupled climate system model FGOALS-f3-L developed at the State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics, Institute of Atmospheric Physics, Chinese Academy of Sciences, under historical forcing from phase 6 of the Coupled Model Intercomparison Project (CMIP6). FGOALS-f3-L reproduces the fundamental features of global oceanic circulations, such as sea surface temperature (SST), sea surface salinity (SSS), mixed layer depth (MLD), vertical temperature and salinity, and meridional overturning circulations. There are notable improvements compared with the previous version, FGOALS-s2, such as a reduction in warm SST biases near the western and eastern boundaries of oceans and salty SSS biases in the tropical western Atlantic and eastern boundaries, and a mitigation of deep MLD biases at high latitudes. However, several obvious biases remain. The most significant biases include cold SST biases in the northwestern Pacific (over 4°C), freshwater SSS biases and deep MLD biases in the subtropics, and temperature and salinity biases in deep ocean at high latitudes. The simulated sea ice shows a reasonable distribution but stronger seasonal cycle than observed. The spatial patterns of sea ice are more realistic in FGOALS-f3-L than its previous version because the latitude–longitude grid is replaced with a tripolar grid in the ocean and sea ice model. The most significant biases are the overestimated sea ice and underestimated SSS in the Labrador Sea and Barents Sea, which are related to the shallower MLD and weaker vertical mixing. 相似文献
19.
The tropical intraseasonal oscillation in SAMIL coupled and uncoupled general circulation models 总被引:4,自引:1,他引:3
Simulations of tropical intraseasonal oscillation(TISO) in SAMIL,the Spectral Atmospheric Model from the Institute of Atmospheric Physics(IAP) State Key Laboratory of Numerical Modeling for Atmospheric Sciences and Geophysical Fluid Dynamics(LASG) coupled and uncoupled general circulation models were comprehensively evaluated in this study.Compared to the uncoupled model,the atmosphere-ocean coupled model improved the TISO simulation in the following aspects:(1) the spectral intensity for the 30-80-day peak eastward periods was more realistic;(2) the eastward propagation signals over western Pacific were stronger;and(3) the variance distribution and stronger signals of Kelvin waves and mixed Rossby gravity waves were more realistic.Better performance in the coupled run was assumed to be associated with a better mean state and a more realistic relationship between precipitation and SST.In both the coupled and uncoupled runs,the unrealistic simulation of the eastward propagation over the equatorial Indian Ocean might have been associated with the biases of the precipitation mean state over the Indian Ocean,and the unrealistic split of maximum TISO precipitation variance over the Pacific might have corresponded to the exaggeration of the double Intertropical Convergence Zone(ITCZ) structure in precipitation mean state.However,whether a better mean state leads to better TISO activity remains questionable.Notably,the northward propagation over the Indian Ocean during summer was not improved in the mean lead-lag correlation analysis,but case studies have shown some strong cases to yield remarkably realistic northward propagation in coupled runs. 相似文献
20.
Sensitivity of regional climate simulations of the summer 1998 extreme rainfall to convective parameterization schemes 总被引:1,自引:0,他引:1
In this paper, a comparison study of three cumulus parameterization schemes (CPSs), Kain-Fritsch2 (KF2), Grell (GR) and Anthes-Kuo (AK), is carried out using the Pennsylvania State University-National Center for Atmospheric Research mesoscale model (i.e., MM5). The performances of three CPSs are examined in simulations of the long-term heavy Meiyu-frontal rainfall events over the middle to lower reaches of the Yangtze River Basin (YRB-ML) during the summer of 1998. The initial and lateral boundary atmosphere conditions are taken from the National Centers for Environmental Prediction/Department of Energy Reanalysis-2 (R-2) data. The experiment with KF2 scheme (EX_KF2) reproduces reasonably well the major rainfall events, especially the heavy rainfall over YRB-ML during the later stage, and the middle and lower troposphere circulation patterns. In contrast, the experiments with both GR and AK schemes (EX_GR and EX_AK) only simulate the heavy rainfall during the first Meiyu rainy phase with weak intensity, and almost miss the rainfall along YRB-ML during the second phase. The analyses show that the location of 500?hPa western Pacific subtropical high during the first rainy phase, the northward advance during the transition period and the retreat during the second rainy phase, observed from the R-2 data, are successfully captured by EX_KF2, compared to the poor performance of EX_GR and EX_AK. A reasonable proportion of the subgrid-scale rainfall and smaller biases of temperature and moisture from lower to middle troposphere in EX_KF2 decide its good rainfall simulations, in contrast with the absolutely high proportions and the cold and dry biases caused by the decreased vertically convective transportation and the weak southwesterly wind in EX_GR and EX_AK. Overall, the three CPSs show substantial intersimulation differences in rainfall as well as in three-dimensional atmospheric structures, and KF2 shows superior performances. The results suggest that the realistic subgrid-scale CPS is still highly required for the high-resolution regional climate models to simulate the heavy rainfall events. 相似文献