应用IAP9L-AGCM对2002年中国夏季气候的预测及效果检验

利用中科院大气所9层大气环流格点模式(IAP9L-AGCM)和IAP-ENSO预测系统对2002年中国夏季气候进行实时集合预测及其检验。结果显示,IAP9L-AGCM较好地预测出了2002年夏季我国大范围旱涝的分布形势,如华南、我国西部多雨,黄河和长江流域之间大范围干旱等;850hPa减弱的夏季风、青藏高原辐散中心以及北太平洋上空的异常气旋性环流中心亦被较好地预报出来;不足的是,模式对降水异常细致分布的预测能力有限。预测结果还表明,该模式对夏季(6—8月)平均降水的预报技巧要高于月平均状况,且月平均预报的准确度从6—8月依次递减。

BCC-AGCM-Chem0模式对20世纪对流层臭氧变化趋势的模拟研究

利用IPCC第5阶段试验计划(CMIP5)整理提供的全球臭氧(O_3)分析资料和全球O_3和紫外线辐射数据中心(WOJDC)提供的O_3台站观测资料评估了国家气候中心最新发展的全球大气化学环流模式BCC-AGCM-Chem0对对流层大气O_3变化趋势的模拟能力。结果表明,BCC-AGCM—Chem0模式对对流层O_3的变化趋势具有较好的模拟能力,具体表现在:(1)BCC-AGCM—Chem0模式可以较好地模拟出1871-1999年全球对流层不同高度O_3浓度逐渐升高的基本特征;(2)BCC—AGCM-Chem0模式对1871-1999全球对流层O_3柱浓度纬圈平均异常变化的模拟与CMIP5资料一致,北半球升高趋势明显大于南半球,且升高最大区域的中心位置和强度也与CMIP5资料一致;(3)BCC-AGCM—Chem0模式对1000~300 hPa整体O_3柱浓度变化趋势模拟较好,对O_3柱浓度快速上升的区域和上升速度的模拟都与CMIP5资料一致,但对低层O_3柱浓度升高模拟偏强,对高层O_3柱浓度变化模拟偏弱;(4)与台站观测资料对比,在对流层中低层模拟结果在亚洲Sapporo站和欧洲Hohenpeissenberg站与实际观测比较接近,并与CMIP5资料相似,均呈升高趋势。对流层中高层模式模拟的O_3浓度异常存在明显的周期变化,与台站观测结果一致。

BCC-AGCM-Chem0模式对20世纪全球O_3气候平均态及季节变化特征的模拟研究

利用由国家气候中心最近研发的全球大气环流化学模式BCC-AGCM-ChemO对1871-1999年全球大气O_3浓度进行了模拟,并利用全球臭氧和紫外线辐射数据中心(WOUDC)提供的O_3台站观测资料以及第5次耦合模式国际比较计划(CMIP5)整理的一套全球O_3分析资料对BCC-AGCM-ChemO模拟的O_3的气候平均态及季节变化特征进行了评估。结果表明:(1)BCC-AGCM-ChemO模式模拟出了全球年平均的O_3空间分布特征,表现为北半球O_3浓度高于南半球,O_3的经向分布大致呈由低纬向高纬递增;模式可以再现台站观测的O_3浓度垂直分布结构;相对于CMIP5分析数据,BCC-AGCM-ChemO模拟的O_3气柱总量在40°S以南的南大洋区域,模拟值偏低3~6 DU,在40°S-50°N中低纬地区略偏高3~6DU,陆地地区差异明显大于海洋地区,这些模拟偏差与地面排放和模式中O_3水平和垂直平流输送的影响有关。(2)BCC-AGCM-ChemO模式对全球O_3浓度的季节变化特征也有较好的模拟能力,模拟的O_3柱浓度与CMIP5资料的结果在1、4、7和10月的全球格点空间相关系数分别达到0.89,0.97,0.86和0.91;模式再现了南、北半球O_3浓度春季偏大、秋季偏小的特点;(3)从模式模拟和台站观测的对比分析来看,500 hPa以上的对流层中高层与以下的对流层中低层的O_3季节变化峰值存在明显的不一致性,表明500 hPa以下的中低层区域O_3变化可能受地面排放和干、湿等过程的影响较大,而对流层中高层的O_3变化可能与化学过程和平流层向下的输送影响较大有关。

非线性迭代时间积分方案在IAP AGCM-II中的实施及其模拟结果

将非线性迭代时间积分方案用于大气环流模式 IAP AGCM-II中, 并用 Rossby-Hauwitz波进行了检验, 结果表明, 该方案能长期稳定的积分。此外, 还将采用该方案的模式(其中物理过程不变)和原 IAP AGCM-II模式作了模拟结果的比较, 以考察其效果; 发现采用该方案模式对降水尤其是东亚地区降水的模拟能力较原模式有所提高。

IAP AGCM中短波辐射方案的改进研究I·引入Fu-Liou短波辐射方案

冰云和水云对短波辐射性质(消光系数、单次散射反照率及不对称因子)的影响很不相同,应分别计算。Fu-Liou短波辐射方案(以下称Fu-Liou code)就是对冰云和水云分别采用了不同的参数化方案,云的短波辐射性质直接由云的物理性质来确定。因此,Fu-Liou code在云的处理方面物理意义更清晰且很合理。作者将Fu-Liou code引入IAP AGCM-II中,称为Version 2。对当代气候场的模拟结果表明,Version 2的各个物理过程是协调匹配的,且其对气候场的模拟性能是好的,从而为进一步改进IAP AGCM的短波辐射方案提供了很好的模式基础。

IAP AGCM 4.1对淮河流域夏季降水的预报技巧评估

基于中国科学院大气物理研究所新一代大气环流模式IAP AGCM 4.1共30 a(1981—2010年)的集合回报试验结果,评估了模式对淮河流域夏季降水的预报技巧。分析结果表明,模式总体上可以较好地再现出淮河流域夏季平均降水南多北少的空间分布特征,其中模式模拟的6月降水量与观测值的空间相关可达0.93。但降水强度与观测相比具有系统性的偏差,且模式模拟的降水年际变率显著偏弱。基于降水距平相关系数的确定性预报技巧分析表明,模式对流域西南部夏季降水的预测技巧较高,达到0.2以上,且模式对6月降水异常的预测能力相对最好,7月次之。针对淮河不同子流域的预报技巧分析表明,IAP AGCM 4. 1对蚌埠、鲁台子、王家坝水文控制站以上集水面积的夏季面雨量异常具有一定的预报技巧,30 a集合回报的时间相关系数分别为0. 11、0. 13、0. 16。基于降水等级的概率预报技巧评估表明,模式对7月淮河流域南部少雨事件具有很好的预报能力,同时对6月流域中部多雨事件的预报技巧也较高。

CCM3/NCAR的辐射方案在IAP-AGCM模式中的应用

利用NCAR的CCM3(The Community Climate Model version 3)辐射模块,对IAP9L-AGCM的辐射计算方案进行了替换,并对改进的结果做了细致的评估。分析表明,新版本的模式在大多数辐射场的空间平均和分布型的模拟上有了较为明显的改进,特别是较好地克服了原模式中陆面净辐射场的偏差。在此基础上,新版本计算的大气温度普遍升高。伴随这种变化,模式中的海平面气压、地表温度、位势高度、风场、降水、比湿等物理量都有了调整,但是变化并不明显,从而对模式的进一步发展和完善提出了新的要求。

陆面过程对气候影响的数值模拟:SSiB与IAP/LASG L9R15 AGCM耦合及其模式性能

利用陆面过程模式 SSi B与 IAP/LASG发展的 L9R1 5AGCM的耦合 1 0 a积分试验 ,研究了全球尺度大气与地表的水分和能量交换以及陆地与大气环流和气候的相互作用。模拟表明 :SSi B模式可模拟出陆地上较为真实的表面通量及其日变化 ,较好地定量描述土壤 -植被 -大气连续体系 ( SPAC)中能量和水分的传输过程。因此 ,将其引入气候模式中能够模拟出比 CTL- AGCM更合理的气候平均状态、水汽分布以及水汽输送的气候特征 ,特别是亚洲夏季风水汽输送独特的地域性 ,再现了大气环流 ,尤其是陆面气候的基本特征。并指出 ,陆面过程参数化的引进及其陆面状况的变化显著地改善了全球陆地上的水分平衡状况。利用改进的再循环降水模式 ,进一步研究了陆面过程参数化明显改进降水模拟的物理机制。指出全球陆地 ,特别是盛夏北半球干旱、半干旱地区的再循环降水率明显减小 ,与陆面上表面潜热通量的显著减小区一致 ,从而克服了许多未耦合陆面过程的 AGCMs因对地表水过程非常简单地参数化导致的普遍存在着整个陆地降水偏高 ,改善了全球陆地上的水分平衡状况。因此 ,在充分耦合的陆气环流模式中模拟的降水分布与实况接近。

热带太平洋SST异常对IAP-9LAGCM年际变率影响的模拟

通过1960~1989年实测的热带太平洋(30.5°N^30.5°S,120°E^70°W)SST(热带太平洋区域以外用气候平均值)强迫AGCM得到的结果,以此来研究热带SST的变化对全球大气环流年际变化的影响。首先,我们分析了南方涛动,分别给出了Tahiti和Darwin海平面气压异常及赤道附近(-5°S^5°N)外逸长波辐射(OLR)时间演变,都能很好与观测相比较。然后,讨论了全球大气环流对热带SST的变化的响应,全球主要的遥相关型都能很好地再现。最后,通过奇异值分解(SVD)技术研究了热带SST与冬季北半球500 hPa位势高度主要的耦合型,模拟的相关型与NCEP再分析资料的相关型非常相似。

IAP AGCM对全球海温异常的响应——CO_2引起气候变化的等效研究

本文用IAP AGCM研究全球海温异常引起的气候变化,这种变化可以看作是由于CO_2含量改变引起的响应。按照Ramanathan和Cess等的观点,太阳常数的改变、CO_2含量的增减及全球海温异常对地气系统能量收支的影响是一致的,主要受控于射出净辐射的改变.本工作分别以+4℃和-4℃作为全球海温异常得到两次积分,分别记为I和D,模式的长期气候平均用作基本状态试验,记为C. 当海温增加4℃时,地表气温约增加4.4℃,而且主要由于热带对流加热的影响,气温的变化随高度增加,冬半球地表气温的增加明显大于夏半球,这是由雪的反照率和垂直温度递减率的反馈作用引起的。虽然全球平均总云量随海温增加而减少,但其纬向分布是不均匀的,尤其对个别类型的云更是如此。云的反馈在辐射能量收支中起着重要作用,例如,热带模式层顶净向下太阳辐射(S)和净向上长波辐射(R)减少(或增加最少)就归咎于穿透性对流云的增加. 全球平均降水I比C多18％.降水的变化呈正反馈趋势,即热带降水最大的地区降水加大,而在副热带地区降水增加很小,甚至减少.纬度-时间图上,降水的变化呈带状分布,正象降水本身的变化一样. 虽然我们得到的全球平均和纬向平均与Mitchell的结果一致,但区域性海温异常响应存在很大差别.

The Mid-Holocene Climate Simulated by a Grid-Point AGCM Coupled with a Biome Model

The climate simulation for the mid–Holocene about 6000 years before present (6 ka BP) is carried out with a grid–point atmospheric general circulation model (AGCM) coupled with a biome model. This coupled model simulation employs orbital parameters of 6 ka BP but present forcing conditions. Results show that large–scale climate differences between now and then are substantial in summer with dramatically strong African–Asian monsoon flow and precipitation during mid–Holocene. Although the results of this coupled model are qualitatively close to those of the AGCM, the coupled model shows a larger changes in both precipitation and temperature in summer over the North African monsoon area with weaker cooling in the Northern autumn.

The Boreal Summer Intraseasonal Oscillation Simulated by Four Chinese AGCMs Participating in the CMIP5 Project

The performances of four Chinese AGCMs participating in the Coupled Model Intercomparison Project Phase 5 （CMIP5） in the simulation of the boreal summer intraseasonal oscillation （BSISO） are assessed. The authors focus on the major characteristics of BSISO： the intensity, significant period, and propagation. The results show that the four AGCMs can reproduce boreal summer intraseasonal signals of precipitation; however their limitations are also evident. Compared with the Climate Prediction Center Merged Analysis of Precipitation （CMAP） data, the models underestimate the strength of the intraseasonal oscillation （ISO） over the eastern equatorial Indian Ocean （IO） during the boreal summer （May to October）, but overestimate the intraseasonal variability over the western Pacific （WP）. In the model results, the westward propagation dominates, whereas the eastward propagation dominates in the CMAP data. The northward propagation in these models is tilted southwest-northeast, which is also different from the CMAP result. Thus, there is not a northeast-southwest tilted rain belt revolution off the equator during the BSISO＇s eastward journey in the models. The biases of the BSISO are consistent with the summer mean state, especially the vertical shear. Analysis also shows that there is a positive feedback between the intraseasonal precipitation and the summer mean precipitation. The positive feedback processes may amplify the models＇ biases in the BSISO simulation.

Evaluation of Spring Persistent Rainfall over East Asia in CMIP3/CMIP5 AGCM Simulations

The progress made fi＇om Phase 3 to Phase 5 of the Coupled Model Intercomparison Project （CMIP3 to CMIP5） in simulating spring persistent rainfall （SPR） over East Asia was examined from the outputs of nine atmospheric general circulation models （AGCMs）. The majority of the models overestimated the precipitation over the SPR domain, with the mean latitude of the SPR belt shifting to the north. The overestimation was about 1mm d-1 in the CMIP3 ensemble, and the northward displacement was about 3°, while in the CMIP5 ensemble the overestimation was suppressed to 0.7 mm d-i and the northward shift decreased to 2.5°. The SPR features a northeast-southwest extended rain belt with a slope of 0.4°N/°E. The CMIP5 ensemble yielded a smaller slope （0.2°N/°E）, whereas the CMIP3 ensemble featured an unre- alistic zonally-distributed slope. The CMIP5 models also showed better skill in simulating the interannual variability of SPR. Previous studies have suggested that the zonal land-sea thermal contrast and sensible heat flux over the southeastern Tibetan Plateau are important for the existence of SPR. These two ther- mal factors were captured well in the CMIP5 ensemble, but underestimated in the CMIP3 ensemble. The variability of zonal land-sea thermal contrast is positively correlated with the rainfall amount over the main SPR center, but it was found that an overestimated thermal contrast between East Asia and South China Sea is a common problem in most of the CMIP3 and CMIP5 models. Simulation of the meridional thermal contrast is therefore important for the future improvement of current AGCMs.

Simulation of East Asian Summer Monsoon by Using an Improved AGCM

The IAP 2-L AGCM is modified by introducing a set of climatological surface albedo data into the model for substituting the model′s original surface albedo parameterization. The comparison between the observations and the simulation results by the modified model shows that the general features of the East Asian summer monsoon can be well reproduced by the modified IAP 2-L AGCM. Especially for the simulation of monsoon precipitation, the modified model can well reproduce not only the monthly mean features of the summer monsoon rainfall over East Asia, but also the stepwise advance and retreat of the East Asian summer monsoon rainbelt. Analysis results demonstrate that the good simulation of the monsoon rainfall is closely related to the reasonable simulation of the large scale general circulation over East Asian region, such as the western Pacific subtropical high, Asian monsoon low and the low level flows. The good performance of the modified model in the rainfall simulation shows its great potential to serve as a useful tool for the prediction of summer drought/flood events over East Asia.

Simulating the Intraseasonal Variation of the East Asian Summer Monsoon by IAP AGCM4.0

ABSTRACT This study focuses on the intraseasonal variation of the East Asian summer monsoon （EASM） simulated by IAP AGCM 4.0, the fourth-generation atmospheric general circulation model recently developed at the Institute of Atmospheric Physics, Chinese Academy of Sciences. In general, the model simulates the intraseasonal evolution of the EASM and the related rain belt. Besides, the model also simulates the two northward jumps of the westem Pacific subtropical high （WPSH）, which are closely related to the convective activities in the warm pool region and Rossby wave activities in high latitudes. Nevertheless, some evident biases in the model were found to exist. Due to a stronger WPSH, the model fails to simulate the rain belt in southern China during May and June. Besides, the model simulates a later retreat of the EASM, which is attributed to the overestimated land-sea thermal contrast in August. In particular, the timing of the two northward jumps of the WPSH in the model is not coincident with the observation, with a later jump by two pentads for the first jump and an earlier jump by one pentad for the second, i.e., the interval between the two jumps is shorter than the observation. This bias is mainly ascribed to a shorter oscillating periodicity of convection in the tropical northwestern Pacific.

Evaluation of Surface Air Temperature Change over China and the Globe during the Twentieth Century in IAP AGCM4.0

Based on time series and linear trend analysis, the authors evaluated the performance of the fourth gen- eration atmospheric general circulation model developed at the Institute of Atmospheric Physics, Chinese Academy of Sciences （IAP AGCM4.0）, in simulating surface air temperature （SAT） during the twentieth century over China and the globe. The numerical experiment is con- ducted by driving the model with the observed sea surface temperature and sea ice. It is shown that IAP AGCM4.0 can simulate the warming trend of the global SAT, with the major wanning regions in the high latitudes of the Northern Hemisphere and the mid-latitudes of the South- ern Hemisphere. While the simulated trend over the whole globe is close to the observation, the model trader- estimates the observed trend over the continents. More- over, the model simulates the spatial distribution of SAT in China, with a bias of approximately -2℃ in eastern China, but with a more serious bias in western China. Compared with the global mean, however, the correlation coefficient between the simulation and observation in China is significantly lower, indicating that there is large uncertainty in simulating regional climate change.

The Relationship between the East Asian Subtropical Westerly Jet and Summer Precipitation over East Asia as Simulated by the IAP AGCM4.0

Based on a 30-year Atmospheric Model Intercomparison Project(AMIP) simulation using IAP AGCM4.0, the relationship between the East Asian subtropical westerly jet(EASWJ) and summer precipitation over East Asia has been investigated, and compared with observation. It was found the meridional displacement of the EASWJ has a closer relationship with the precipitation over East Asia both from model simulation and observation, with an anomalous southward shift of EASWJ being conducive to rainfall over the Yangtze-Huaihe River Valley(YHRV), and an anomalous northward shift resulting in less rainfall over the YHRV. However, the simulated precipitation anomalies were found to be weaker than observed from the composite analysis, and this would be related to the weakly reproduced mid-upper-level convergence in the mid-high latitudes and ascending motion in the lower latitudes.

南半球热带外准半年振荡及IAP9L AGCM模拟检验

基于1979—2000年的NCEP/NCAR海平面气压和位势高度场资料分析了南半球大气环流的准半年振荡(半年波)现象。结果表明:这一现象主要出现在南半球对流层低层的中高纬度和中高层的热带地区。对南半球热带外大气而言,40°S和65°S是低层大气环流准半年振荡最为显著的两个纬度带,半年波的贡献都超过了70%,低层南半球中高纬度海平面气压场季节变化的反位相也主要体现为各自半年波分量变化的反位相。在此基础上,检验了IAP 9L AGCM(大气物理研究所9层大气环流模式)对这一现象模拟的能力,模拟结果显示,模式成功模拟了65°S处海平面气压场的准半年振荡现象,其振幅略低于观测结果,但模式对40°S处气压场准半年振荡的模拟效果较差。

Quantifying the attribution of model bias in simulating summer hot days in China with IAP AGCM 4.1

Using lAP AGCM simulation results for the period 1961-2005, summer hot days in China were calculated and then compared with observations. Generally, the spatial pattern of hot days is reasonably reproduced, with more hot days found in northern China, the Yangtze and Huaihe River basin, the Chuan-Yu region, and southern Xinjiang. However, the model tends to overestimate the number of hot days in the above-mentioned regions, particularly in the Yangtze and Huaihe River basin where the simulated summer-mean hot days is 13 days more than observed when averaged over the whole region, and the maximum overestimation of hot days can reach 23 days in the region. Analysis of the probability distribution of daily maximum temperature （Trnax） suggests that the warm bias in the model-simulated Tmax contributes largely to the overestimation of hot days in the model. Furthermore, the discrepancy in the simulated variance of the Tmax distribution also plays a non- negligible role in the overestimation of hot days. Indeed, the latter can even account for 22% of the total bias of simulated hot days in August in the Yangtze and Huaihe River basin. The quantification of model bias from the mean value and variability can provide more information for further model improvement.

Comparison and Examination of Dynamic Frameworks of IAP and OSU AGCM

A brief description of the dynamic framework of the IAP 2-L AGCM (referred as 'IAP DF') is presented in contrast with the corresponding 'OSU DF' and preliminary comparison and examination of the IAP DF and the OSU DF with the aid of numerical experiments using a set of baroclinic Rossby-Haurwitz wave initial conditions is performed.The results of the numerical experiments show that both the IAP DF arid the OSU DF are long-term computational stable and are able to simulate the fundamental behavior of the Rossby-Haurwitz wave under the limitation of 7.5 minutes time interval. In the respect of the prediction of the large-scale wave, the IAP DF is better than the OSU DF, however, the OSU DF gives better predictions of zonal mean status than the IAP DF does. Another important contrast is that the level of small-scale noise of the IAP DF is higher than the OSU DF, on the contrary, the damping effect of the OSU DF on large-scale vortex field is stronger than the IAP DF.