Changes in the seasonal amplitude of northern ecosystem productivity under future global warming

Observations have shown a largely enhanced seasonal amplitude of northern atmospheric CO₂ in the past several decades, and this enhancement is attributable to the increased seasonal amplitude of northern net ecosystem productivity (NEP amplitude). In the future, however, the changes in NEP amplitude are not clear, because of the uncertainties in climate change and vegetation dynamics. This study investigated the changes in NEP amplitude north of 45°N under future global warming by using a dynamic global vegetation model (DGVM). The authors conducted two sets of simulations: a present-day simulation (1981–2000) and future simulations (2081–2100) forced by RCP8.5 outputs from CMIP5. The results showed an overall enhanced northern NEP amplitude under the RCP8.5 scenario because of the increased maximum NEP and the decreased minimum NEP. The increases (decreases) in the maximum (minimum) NEP resulted from stronger (weaker) positive changes in gross primary production (GPP) than ecosystem respiration (ER). Changes in GPP and ER are both dominantly driven by surface air temperature and vegetation dynamics. This work highlights the key role of vegetation dynamics in regulating the northern terrestrial carbon cycle and the importance of including a DGVM in Earth system models.摘要观测显示过去几十年北半球大气二氧化碳季节幅度大幅增加, 这主要是由北半球陆地净生态系统生产力季节幅度的增加所致. 但是, 因为气候变化和植被动态的不确定性, 未来陆地净生态系统生产力季节幅度的变化还很不清楚. 本工作利用全球植被动力学模式研究了全球变暖背景下北纬45°以北陆地净生态系统生产力季节幅度的变化. 作者做了两大类试验: 当代试验 (1981−2000) 和CMIP5 RCP8.5 变暖情景驱动的未来试验 (2081−2100) . 结果显示, 在RCP8.5变暖情景下北半球中高纬陆地净生态系统生产力季节幅度整体增加, 这是因为陆地净生态系统生产力的月最大值增加且月最小值减小. 最大 (最小) 陆地净生态系统生产力的增加 (减小) 是由于总初级生产力的增加强 (弱) 于生态系统总呼吸. 总初级生产力和生态系统总呼吸的变化都主要受地表气温和植被动态的驱动. 本工作强调了植被动态对北半球中高纬陆地生态系统碳循环的关键调制作用, 也强调了在地球系统模式中包含全球植被动力学模式的重要性.     

Changes in mixed layer depth and spring bloom in the Kuroshio extension under global warming

The mixed layer is deep in January–April in the Kuroshio Extension region. This paper investigates the response in this region of mixed layer depth(MLD) and the spring bloom initiation to global warming using the output of 15 models from CMIP5. The models indicate that in the late 21 st century the mixed layer will shoal, and the MLD reduction will be most pronounced in spring at about 33?N on the southern edge of the present deep-MLD region. The advection of temperature change in the upper 100 m by the mean eastward flow explains the spatial pattern of MLD shoaling in the models. Associated with the shoaling mixed layer, the onset of spring bloom inception is projected to advance due to the strengthened stratification in the warming climate.     

全球气候变暖背景下索马里急流变化的预估研究

索马里急流的变化对亚洲季风和气候变动具有重要的影响,未来索马里急流到底会如何演变？如何受全球变暖的影响？针对这个问题,文中利用IPCC第四次评估报告（IPCC AR4）的多个海气耦合模式的模拟结果,评估了多个模式在当前气候（20C3M）条件下对夏季低空索马里急流的模拟能力;预估模式在SRESA2排放情景下对21世纪（2010—2099）的索马里急流变化。研究结果表明,18个模式在现代气候条件下对索马里急流有较好的模拟能力;18个模式的集合平均结果预测夏季索马里低空急流在21世纪的变化过程是：初期（2010—2040）增强至减弱,中期（2050—2060）增加至最强,末期（2070—2090）减至最弱。与现代气候条件模拟结果相比,夏季索马里低空急流在未来气候变暖背景条件下是趋于减弱的过程,在21世纪末期最弱。研究还表明了夏季低空索马里急流的变化幅度与全球平均气温的变化幅度是一个非线性的关系,各模式对二者关系的描述存在不确定性,鉴于索马里急流对印度季风和东亚季风及中国气候的重要性,索马里急流的变化规律和未来演变是科学界特别需要深入研究的问题。     

Changes in aridity in response to the global warming hiatus

The global warming slowdown or warming hiatus, began around the year 2000 and has persisted for nearly 15 years. Most studies have focused on the interpretation of the hiatus in temperature. In this study, changes in a global aridity index (AI) were analyzed by using a newly developed dynamical adjustment method that can successfully identify and separate dynamically induced and radiatively forced aridity changes in the raw data. The AI and Palmer Drought Severity Index produced a wetting zone over the mid-to-high latitudes of the Northern Hemisphere in recent decades. The dynamical adjustment analysis suggested that this wetting zone occurred in response to the global warming hiatus. The dynamically induced AI (DAI) played a major role in the AI changes during the hiatus period, and its relationships with the North Atlantic Oscillation (NAO), Pacific Decadal Oscillation (PDO), and Atlantic Multi-decadal Oscillation (AMO) also indicated that different phases of the NAO, PDO, and AMO contributed to different performances of the DAI over the Northern Hemisphere. Although the aridity wetting over the mid-to-high latitudes may relieve long-term drying in certain regions, the hiatus is temporary, and so is the relief. Accelerated global warming will return when the NAO, PDO, and AMO revert to their opposite phases in the future, and the wetting zone is likely to disappear.     

Vegetation feedback under future global warming

It has been well documented that vegetation plays an important role in the climate system. However, vegetation is typically kept constant when climate models are used to project anthropogenic climate change under a range of emission scenarios in the Intergovernmental Panel on Climate Change (IPCC) Special Report on Emission Scenarios. Here, an atmospheric general circulation model, and an asynchronously coupled system of an atmospheric and an equilibrium terrestrial biosphere model are forced by monthly sea surface temperature and sea ice extent for the periods 2051?C2060 and 2090?C2098 as projected with 17 atmosphere?Cocean general circulation models participating in the IPCC Fourth Assessment Report, and by appropriate atmospheric carbon dioxide concentrations under the A2 emission scenario. The effects of vegetation feedback under future global warming are then investigated. It is found that the simulated composition and distribution of vegetation during 2051?C2060 (2090?C2098) differ greatly from the present, and global vegetation tends to become denser as expressed by a 21% (36%) increase in global mean leaf area index, which is most pronounced at the middle and high northern latitudes. Vegetation feedback has little effect on globally averaged surface temperature. On a regional scale, however, it induces statistically significant changes in surface temperature, in particular over most parts of continental Eurasia east of about 60°E where annual surface temperature is expected to increase by 0.1?C1.0?K, with an average of about 0.4?K for each future period. These changes can mostly be explained by changes in surface albedo resulting from vegetation changes in the context of future global warming.     

Thermal regime in the Rybinsk Reservoir under global warming

Presented are the results of studying the water temperature changes in the Rybinsk Reservoir during the ice-free period caused by the climate warming. Linear trends are revealed and estimated. The trend is observed for the period of 1976?C2008 towards the increase in the average water surface temperature during all months at the maximum rise rate of 0.89°C/10 years in July. It is demonstrated that the average water temperature in the reservoir in May?COctober has been above the norm since 1995.     

Changes in a modeled MJO with idealized global warming

This study estimates how the Madden-Julian oscillation (MJO) will change with uniform global warming of 2 and 4 K at the Earth surface using an aqua-planet version of the NCAR CAM2 implemented with the Tiedtke convection scheme. Solar insolation is specified at the vernal equinox with a diurnal cycle. Thirty-year integrations are carried out for each case and the last 20-year’s results are used for analysis. For the warmer cases, the modeled MJO’s eastward propagation remains dominant at zonal wave numbers 1–4, and notable increase occurs in variance, power spectra, and the number of prominent MJO events. The convective heating is enhanced more in upper troposphere, and the MJO power spectra increase more on 20–30 days than on 30–60 days. In all cases, composite life cycles of prominent MJO events show that the anomalous surface latent heat flux lags precipitation by about 90° in phase, characterizing the nonlinear wind induced surface heat exchange (WISHE) to destabilize the MJO. Interacting with a warmer surface in the 4 K case, perturbations of zonal wind and temperature at bottom model level contribute to the nonlinear WISHE coherently with the latent heat flux. Meanwhile anomalous boundary layer convergence leads precipitation by some 45° in phase, indicating the frictional moisture convergence to maintain the enhanced MJO.     

Air temperature trends in Georgia under global warming conditions

Air temperature trends under conditions of global warming are studied using the observational data from 87 meteorological stations of Georgia for the period of 1936–2011. Plotted are the geographic information maps of the spatial structure of temperature variation rate.     

Future pattern of Asian drought under global warming scenario

This study investigates the effect of global warming on drought patterns over Asia at the end of the twenty-first century by a multi-model ensemble method based on daily precipitation data of 15 coupled climate models simulations under SRES A1B scenario, thereby assessing the consistency of responses among different models. The projected precipitation climatology was translated into the change in drought climatology using the effective drought index. The results of the models were consistent in that they project an increase in the mean and the standard deviation of precipitation over most of Asia, and the increase was considerably greater in higher latitude areas. Therefore, it is expected that in future, drought over most of Asia will occur less frequently with weaker intensity and shorter duration than those prevalent currently. However, two special regions were detected. One was the Asian monsoon regions (AMRs: South Asia and East Asia), which showed a greater increase in the standard deviation of precipitation than the mean precipitation, with an amplified seasonal precipitation cycle. As a result, part of the AMRs exhibited slight increases in drought properties such as frequency and intensity. The other region was West Asia. The region showed decreased mean precipitation, especially in its northern part (Syria and its vicinity), and more frequent droughts were projected for this region with enhanced drought intensity and lengthened drought duration. The worsening trends in drought patterns over both regions were more significant in extreme drought, the likelihood of which is relatively higher in summer in West Asia and from spring to summer in the AMRs.     

Changes in African temperature and precipitation associated with degrees of global warming

For almost two decades, politicians have been negotiating temperature limits to which anthropogenic global warming should be restricted, and 2 °C has emerged as benchmark for danger. However, there has been a lack of scientific research into the implications of such a change for African climate. This study aims to provide information for mitigation debates; through an examination of temperature and precipitation changes in Africa associated with 1 °C, 2 °C, 3 °C, and 4 °C of global warming. Data from Global Climate Models show little significant precipitation change at 1 °C, then larger anomalies at 2 °C which are strengthened and extended at 3 °C and 4 °C, including a wet signal in East Africa, and dry signals in Southern Africa, the Guinea Coast, and the west of the Sahel. Some of the models project changes with potential for severe societal implications. Despite the uncertainty attached to these projections, they highlight risks associated with 2 °C and beyond. Using these findings as a framework for impact assessment and evaluation, further research has the potential to uncover the implications of global warming for African regions.     

Spatiotemporal variations in climate moisture indices in Georgia under global warming

Using observational data from 50 weather stations in Georgia for the period of 1936-2013, the following climate indices of moisture regime are studied: maximum 1-day precipitation, maximum 5-day precipitation, the simple daily intensity index, the number of days with precipitation equal to not less than 10, 20, and 50 mm, number of consecutive wet and dry days. Geoinformation maps of the spatial structure are plotted, and the dynamics of these indices is studied for the period of global warming. Expected changes in the moisture regime in different physiographic regions in Georgia are assessed.     

Boreal summer quasi-monthly oscillation in the global tropics

The boreal summer intraseasonal oscillation (ISO) in the global tropics is documented here using a 7-year suite (1998–2004) of satellite measurements. A composite scenario was made of 28 selected events with reference to the oscillation in the eastern equatorial Indian Ocean (EIO), where the oscillation is most regular and its intensity is indicative of the strength of the subsequent northward propagation. The average oscillation period is about 32 days, and this quasi-monthly oscillation (QMO) is primarily confined to the tropical Indian and Pacific Oceans. Topics that were investigated are the partition of convective versus stratiform clouds, the vertical structure of precipitation rates, and the evolution of cloud types during the initial organization and the development of intraseasonal convective anomalies in the central Indian Ocean. During the initiation of the convective anomalies, the stratiform and convective rains have comparable rates; the prevailing cloud type experiences a trimodal evolution from shallow to deep convection, and finally to anvil and extended stratiform clouds. A major northwest/southeast-slanted rainband forms as the equatorial rainfall anomalies reach Sumatra, and the rainband subsequently propagates northeastward into the west Pacific Ocean. The enhanced precipitation in the west Pacific then rapidly traverses the Pacific along the Intertropical Convergence Zone, meanwhile migrating northward to the Philippine Sea. A seesaw teleconnection in rainfall anomalies is found between the southern Bay of Bengal (5–15°N, 80–100°E) and the eastern Pacific (5–15°N, 85–105°W). Local sea-surface temperature (SST)-rainfall anomalies display a negative simultaneous correlation in the off-equatorial regions but a zero correlation (quadrature phase relationship) near the equator. We propose that atmosphere–ocean interaction and the vertical monsoon easterly shear are important contributors to the northeastward propagation component of the intraseasonal rainband. The observed evidence presented here provides critical information for validating the numerical models, and it supports the self-induction mechanism theory for maintenance of the boreal summer ISO.     

全球变暖情景下中国气温分区的未来变化

利用SRES A2情景下IPCC AR4的13个模式资料,结合我国月平均温度观测资料对当前和未来我国气温的分区进行对比研究。结果表明：1961-1990、2021-2050年和2071-2097年三个时段年平均气温分区在我国西部变化不大,而在我国东部发生了显著变化。1961-1990年我国东部被华北分区带分为南、北两个区;2021-2050年由于1961-1990年间的华北分区带北移,而在两广以北同时出现另一分区带,使得该时段我国东部分成东北区、华北和华中区以及华南区三个区,在2071-2097年北方分区带消失,而南方的分区带北移至长江一带,使得该时段我国东部仍可分为南、北两区。通过比较三个时段不同分区年平均温度时间变化发现,导致分区变化的原因主要是由于在不同时段各分区年平均温度的变率和增温幅度不一致所致。     

Projection of the East Asian westerly jet under six global warming targets

东亚高空急流(简称急流)对夏季东亚地区的天气和气候有着重要影响。本文利用CMIP5的历史气候模拟试验和RCP8.5路径下的未来气候变化预估试验数据,预估了急流在6个全球变暖阈值(1.5℃,2.0℃,2.5℃,3.0℃,3.5℃和4.0℃)下相对于当代气候的变化情况。结果表明东亚高空西风在1.5℃阈值下略微减弱。在2.0℃阈值下,西风在急流轴(约40°N)南侧增强,北侧减弱。这种变化趋势在2.5℃和更高的变暖阈值下愈加明显,使急流轴逐渐向南移动,但急流强度变化不大。研究表明,在急流的入口和出口区,对流层中上层大气升温速度相对较慢,导致在急流轴南(北)侧出现向南(北)的负(正)经向温度梯度,使西风在南(北)侧增强(减弱).     

全球变暖背景下北极海冰与东亚冬季风关系的变化及其机制

为了进一步了解全球变暖背景下北极海冰与东亚冬季风的关系及其变化,本文选用东亚冬季风北模态及南模态作为东亚冬季风指数,利用滑动相关分析、回归分析及合成分析研究了全球变暖背景下1953—2021年北极海冰密集度与东亚冬季风关系的变化特征及其机制。结果表明:11月巴伦支海海冰密集度与东亚冬季风北模态之间的关系发生了显著变化,从1962—1977年显著正相关转为1983—1999年显著负相关,2000年以后两者无显著关系。1962—1977年11月巴伦支海海冰偏多对应东亚冬季风偏强,这是大气环流影响海冰的结果,11月的大气环流异常特征维持到了冬季,使得欧亚大陆上空大气呈现出北极涛动(Arctic Oscillation,AO)负位相,在增强东亚冬季风的同时将中高纬大陆干冷空气输送至巴伦支海,在表面风应力的作用下巴伦支海海冰增多。1983—1999年则由前一时期的大气环流影响海冰变为海冰影响大气环流,11月巴伦支海海冰显著减少在冬季激发出了北极涛动负位相,加强东亚大槽及东亚高空西风急流,从而使得东亚冬季风偏强。2000年以后北极海冰与东亚冬季风北模态的关系明显减弱,此时东亚冬季风与北极涛动的负相关关系更为显著。     

Polar Low genesis over the North Pacific under different global warming scenarios

Following an earlier climatological study of North Pacific Polar Lows by employing dynamical downscaling of NCEP1 reanalysis in the regional climate model COSMO-CLM, the characteristics of Polar Low genesis over the North Pacific under different global warming scenarios are investigated. Simulations based on three scenarios from the Special Report on Emissions Scenarios were conducted using a global climate model (ECHAM5) and used to examine systematic changes in the occurrence of Polar Lows over the twenty first century. The results show that with more greenhouse gas emissions, global air temperature would rise, and the frequency of Polar Lows would decrease. With sea ice melting, the distribution of Polar Low genesis shows a northward shift. In the scenarios with stronger warming there is a larger reduction in the number of Polar Lows.     

Increased population exposure to precipitation extremes in China under global warming scenarios

极端降水(暴雨)是我国最为主要的自然灾害之一,每年均造成巨大经济损失和人员伤亡。现有预估研究表明,未来全球持续增暖使得我国极端降水发生频次显著增加,强度增强。那么,未来极端降水增加会对社会,尤其是人们生活造成多大影响?围绕这个问题,本研究基于多个高分辨率区域气候模式模拟和人口数据,分析了未来我国极端降水人口暴露度的可能变化。结果指出,在RCP4.5-SSP2情景下,到了21世纪末,虽然预估的我国人口数量大幅减少,但极端降水人口暴露度却显著增加,相对当前气候增加了约21.6%,其中东部地区是增加最为显著的区域。进一步研究发现,人口暴露度的增加不依赖于情景的选择,但高排放情景增加幅度更大,而且增加主要是由于气候变化的贡献。