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1.
Using the regional climate model RegCM4.4.5, coupled with the land model CLM4.5, we investigated the effects of springtime soil moisture in the Indochina Peninsula on summer precipitation over the South China Sea and its surrounding areas in 1999. Results have indicated that there exists positive correlation between soil moisture and summer precipitation over the western Pacific Ocean and negative correlation between soil moisture and summer precipitation over the eastern Indian Ocean. Summer precipitation in the South China Sea and its surrounding areas responds to springtime soil moisture in the Indochina Peninsula (the northwest region is critical) because general atmospheric circulation is sensitive to the near-surface thermodynamic state. Increased (decreased) soil moisture would result in decreased (increased) local surface temperatures. Latitudinal, small-scale land–sea thermal differences would then result in northeasterly wind (southwesterly wind) anomalies in the upper layer and southwesterly wind (northeasterly wind) anomalies in the lower layer, which strengthen (weaken) monsoon development. As a result, precipitation would enter the Western Pacific region earlier (later), and water vapor over the eastern Indian Ocean would enter the South China Sea earlier (later), causing a precipitation reduction (increase) in the eastern Indian Ocean and increase (reduction) in the Western Pacific.  相似文献   
2.
This study assesses the direct and indirect effects of natural and anthropogenic aerosols(e.g., black carbon and sulfate)over West and Central Africa during the West African monsoon(WAM) period(June–July–August). We investigate the impacts of aerosols on the amount of cloudiness, the influences on the precipitation efficiency of clouds, and the associated radiative forcing(direct and indirect). Our study includes the implementation of three new formulations of auto-conversion parameterization [namely, the Beheng(BH), Tripoli and Cotton(TC) and Liu and Daum(R6) schemes] in Reg CM4.4.1,besides the default model's auto-conversion scheme(Kessler). Among the new schemes, BH reduces the precipitation wet bias by more than 50% over West Africa and achieves a bias reduction of around 25% over Central Africa. Results from detailed sensitivity experiments suggest a significant path forward in terms of addressing the long-standing issue of the characteristic wet bias in Reg CM. In terms of aerosol-induced radiative forcing, the impact of the various schemes is found to vary considerably(ranging from-5 to-25 W m~(-2)).  相似文献   
3.
This study evaluates the performance of the regional climate model RegCM4 in simulating tropical cyclone (TC) activities over the Western North Pacific (WNP) and their landfalling in China. The model is driven by ERA-Interim boundary conditions at a grid spacing of 25 km, with the simulation period as 1991–2010. Results show that RegCM4 performs well in capturing the main structural features of observed TCs, and in simulating the genesis number and annual cycle of the genesis. The model reproduces the general pattern of the observed TC tracks and occurrence frequency. However, significant underestimation of the occurrence frequency as well as the TC intensity is found. Number of the landfalling TCs over China is also much less than the observed. Bias of the model in reproducing the large-scale circulation pattern and steering flow may contribute to the underestimated landfalling TC numbers.  相似文献   
4.
A regional climate model(Reg CM4) is employed to investigate the impacts of land use/cover change(LUCC) on the climate over the eastern part of Northwest China(ENW) in the periods of 2001 and 2011. The results indicated that the LUCC in ENW, which was characterized by desert retreat, reforestation, and farmland expansion, led to significant local changes in surface air temperature(within ~0.3°C) and slight regional changes in precipitation(within ~15%) in summer. In the desert retreat area, the net absorbed shortwave radiation had a greater influence than evaporative cooling, leading to increases in the daily mean and maximum temperature. Besides, the daily mean and maximum temperatures increased in the reforestation area but decreased in the farmland expansion area. As surface albedo showed no significant change in these regions, the temperature increase in the reforestation area can be attributed to a decrease in evaporation, while the opposite effect appears to have been the case in the farmland expansion area.  相似文献   
5.
基于中国1∶100万植被图和1∶600万植被区划图,按照通用陆面模式CLM植被功能型分类标准,制作了可用于CLM及RegCM4区域气候模式的25 km×25 km分辨率的中国高精度土地覆盖数据(简称VEG数据).相比CLM默认使用的土地覆盖数据(简称ORG数据),VEG数据不仅能提供更多的土地覆盖局地特征,还纠正了ORG数据中裸地和农作物的比例偏高、灌木的比例偏低等误差.对比使用两套土地覆盖数据的RegCM4多年连续积分结果,分析了不同土地覆盖分布对气温、降水等的影响,并从地表能量收支的角度给出影响机理解释.结果显示:VEG数据的使用,使得模式对冬季气温和降水的模拟能力有一定提高,模式在南部区域偏干偏冷的系统误差有所减弱;采用VEG数据后,由于粗糙度、反照率等下垫面参数的改变及云量的变化,使得地表能量收支发生显著调整.青藏高原地区的气温变化与湍流通量和长波辐射的变化有密切的联系,主要源自粗糙度引起的湍流通量增加、以及云量引起的向下净长波辐射增加.而在中国中部和南部,短波辐射变化更为明显,它与地表反照率的变化相一致.基于所制作的土地覆盖数据,可广泛应用于CLM模式在中国区域的应用之中.  相似文献   
6.
本文基于一个水平分辨率为50 km的区域气候模式RegCM4(Regional Climate Model,version 4.0)的模拟与预估结果,对我国汛期江淮暴雨低涡在气候变化背景下的统计特征与合成结构进行分析,进一步对两种温室排放情景下未来中国汛期的江淮暴雨低涡特征进行预估。结果表明:RegCM4模式对环境要素及低涡都具有一定的模拟能力,低涡的伸展高度、生命期及暴雨位置模拟结果与观测较为接近,但模拟的低涡个数、最大暖区高度以及温、湿要素分布均比实际略偏低,而风速和低涡的强度模拟则偏强;在未来两种温室排放情景预估方面, RCP4.5(Representative Concentration Pathways,简称RCP)典型浓度排放情景下,暴雨低涡数量比例减少,强度减弱,但低涡发展高度仍以850 hPa为主,生命期多为2 d以内,低涡雨区分布及最大暖区高度均与历史时段相近;RCP8.5情景下,暴雨低涡比例明显大于RCP4.5情景,低涡发展高度以700 hPa为主,生命期达3 d的增多,强度增强,最大暖区厚度范围显著伸展。两种情景下均有低涡中温度锋区减弱,而湿度锋区增强,但RCP8.5情景减弱与增强更显著,显示更高的温室气体排放将导致未来出现更强的暴雨低涡,造成伴随暴雨的低涡灾害性天气的增加,因此应进一步深化对低涡暴雨灾害性天气发展趋势的研究。  相似文献   
7.
缪阿丽  李锋  王俊  祝涛  叶碧文 《地震》2021,41(4):192-202
对2018年4月6日无为ML4.1地震前的地下流体前兆异常特征以及该地震的震源机制解进行了分析, 结果表明, 无为地震前的异常分布在距震中64~233 km范围内, 这些异常在时间进程上, 可分为中期趋势背景异常和短临异常, 主要以中期趋势背景异常为主。 这些中期趋势背景异常均表现为水位的破年变变化。 从空间演化上看, 2018年安徽无为ML4.1地震前出现的中期趋势背景异常沿着长江破碎带有序分布。 这种比较明显的异常群体性特征为地震预测提供了较好的依据。 震源机制解结果显示, 节面I的走向为NE向, 节面Ⅱ的走向NW向。 反演的震源机制的P轴(主压轴)方向为NE向(70°), 倾角近水平(7°)。 无为地震震源机制解所得主压应力作用方向与无为地震前异常展布方向相同。 这说明地震孕育过程中区域应力加载作用和流体前兆响应具有密切关系。  相似文献   
8.
This work investigates the distribution of high winds above Beaufort scale 6 in the offshore zones of China using high-resolution satellite measurements.A numerical experiment is carried out in order to find out the effects of Taiwan Island on the formation of strong winds.The analysis indicates that the distribution of high wind occurrence is similar to that of the average wind velocity in winter.High winds tend to be anchored in special topographical regions,such as the Taiwan Strait,the Bashi Channel and the southeast coast of Vietnam.High winds occur much more frequently over the warmer than the colder flank of Kuroshio front as it meanders from Taiwan to Japan.The frequency of high winds decreases drastically in spring.The Taiwan Strait maintains the largest high wind occurrence.Besides,high winds remain frequent in the Bashi Channel,the southeast tip of Taiwan Island and the warmer flank of Kuroshio front.In summer,high winds generally occur infrequently except over a broad region off the southeast coast of Vietnam near 10°N and the frequency there decreases from southwest to northeast.High winds around Taiwan Island present near axisymmetric distribution with larger frequency along southeast-northwest direction and smaller frequency along southwest-northeast direction.The dominant direction of high winds exhibits a counterclockwise circulation surrounding the island.The frequency of high winds increases rapidly in autumn and almost repeats the distribution that appears in winter.The simulation results suggest that the effects of Taiwan Island topography on high winds vary with seasons.In winter,topography is the major cause of high winds in the surrounding oceanic zones.High winds in both Taiwan Strait and the southeast corner of the island disappear and the frequency decreases gradually from south to north when the terrain is removed.However,in summer,high wind frequency derived from two simulations with and without terrain is almost identical.We attribute this phenomenon to the factors which are responsible for the formation of high winds.  相似文献   
9.
The authors investigate monsoon change in East Asia in the 21st century under the Special Report on Emissions Scenarios (SRES) A1B scenario using the results of a regional climate model, RegCM3, with a high horizontal resolution. First, the authors evaluate the model’s performance compared with NCEP-NCAR reanalysis data, showing that the model can reliably reproduce the basic climatology of both winter and summer monsoons over East Asia. Next, it is found that the winter monsoon in East Asia would slightly weaken in the 21st century with spatial differences. Over northern East China, anomalous southerly winds would dominate in the mid-and late-21st century because the zonal land-sea thermal contrast is expected to become smaller, due to a stronger warming trend over land than over ocean. However, the intensity of the summer monsoon in East Asia shows a statistically significant upward trend over this century because the zonal land-sea thermal contrast between East Asia and the western North Pacific would become larger, which, in turn, would lead to larger sea level pressure gradients throughout East Asia and extending to the adjacent ocean.  相似文献   
10.
IPCC A1B情景下中国西南地区气候变化的数值模拟   总被引:1,自引:1,他引:0  
利用ECHAM5/MPI-OM全球海气耦合模式模拟的当代(1986-2000年)和IPCC A1B情景下未来(2011-2025年)2×15a的模拟输出格点场资料,驱动20 km高水平分辨率区域气候模式RegCM3进行西南地区气候变化的数值模拟,主要分析未来地面温度和降水的可能变化。结果表明:①通过与32个地面气象站观测资料和CRU资料对比分析,RegCM3能够很好的模拟研究区基准时段地面温度和降水的局地分布特征。②A1B情景下未来西南地区年、四季平均温度均明显增加,北部温度变化幅度大于南部。③最高/最低温度一致升高,冬季最高/最低温度变化幅度大于夏季;年、秋冬季降水有所增加,冬季降水增加明显,而春夏季降水略有减少。④研究区未来春夏季温度升高、降水减少的趋势可能导致局部地区高温、干旱等极端天气的可能性增大;同时冬季降水增加,可能加重局部地区洪涝灾害的风险。  相似文献   
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