中国东部气溶胶光学厚度季节变化的数值模拟
Numerical simulation of the seasonal variation of aerosol optical depth over eastern China
- 2016年20卷第2期 页码:205-215
纸质出版日期: 2016
DOI: 10.11834/jrs.20165106
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纸质出版日期: 2016 ,
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[1]李嘉伟,韩志伟.中国东部气溶胶光学厚度季节变化的数值模拟[J].遥感学报,2016,20(02):205-215.
LI Jiawei, HAN Zhiwei. Numerical simulation of the seasonal variation of aerosol optical depth over eastern China[J]. Journal of Remote Sensing, 2016,20(2):205-215.
气候模式对气溶胶光学厚度AOD的合理模拟
是模拟研究气溶胶气候效应的前提。利用在线耦合的区域气候—大气化学—气溶胶耦合模式系统RIEMS-Chem
模拟研究了2010年中国东部地区AOD的季节变化情况。模拟结果与卫星搭载的中分辨率成像光谱仪(MODIS)的反演资料和地基气溶胶观测网(AERONET)的站点观测资料分别进行了一年四季的详细对比
检验结果显示尽管模拟值有所低估
模式仍然能够合理地反映AOD的季节变化情况和空间分布特征
与AERONET站点观测值相比
整体相关系数为0.6。MODIS反演和相应模拟结果均显示
中国东部地区AOD整体水平夏季最大
春季次之
秋、冬季最小
华北平原、四川盆地和华中地区是AOD的主要大值区。只考虑日间AOD时
其季节分布特征略有不同
在华北平原地区
日间AOD夏季最大(1.1—1.5)
在长江中下游流域地区
日间AOD则在春季最大(1.1—1.7);在中国东部
日间AOD的大值在夏、冬两季分别主要分布在长江以北、以南地区
而在春、秋两季则主要位于长江中下游流域。
Aerosol Optical Depth(AOD) is a key factor that reflects the impact of atmospheric aerosol on the climate. The accurate simulation of AOD is the basis for a climatic model in modeling the aerosol climate effects. In this study
an online-coupled three-dimensional regional climate–atmospheric chemistry–aerosol model was used to investigate the AOD over eastern China in 2010 to understand the spatial and seasonal behavior of AOD and the role aerosol plays over this region.The Regional Integrated Environmental Modeling System online-coupled with atmospheric chemistry and aerosol processes(RIEMS-Chem) was used in this study.This model contains sophisticated atmospheric dynamic
atmospheric chemical
and aerosol chemical processes. The onlinecoupled system facilitates the model to simulate the impact of aerosol on climatic factors and the feedback of climate on aerosol distribution.Simulated AOD was verified by satellite retrieval of the Moderate-Resolution Imaging Spectroradiometer(MODIS) and insitu measurements from the Aerosol Robotic Network(AERONET) in four seasons.The comparison of the AOD simulation result with the corresponding MODIS retrieval indicated the capability of the model to reproduce the seasonal variation and spatial distribution of AOD over eastern China
although the model somewhat underestimated the magnitude in summer.The comparison of AOD measurements from the six AERONET sites also showed that the model was able to simulate the spatial and seasonal variation of AOD
but underestimated the magnitude over north China
with an overall correlation coefficient of 0.6 compared with all AERONET measurements. The MODIS retrieval and corresponding simulation result showed that
over eastern China
the AOD was generally higher in summer
followed by spring
and lower in autumn and winter. However
the daytime seasonal mean AOD showed different seasonal distribution patterns:For areas around the North China Plain
the daytime seasonal mean AOD reached its highest level in summer with values ranging from 1.1 to 1.5
but lowest in other seasons. By contrast
over areas of the middle and lower reaches of the Yangtze River
the daytime seasonal mean AOD was reached its highest level in spring with values ranging from 1.1 to 1.7
followed by autumn and winter
but lowest in summer. For the region of eastern China
the daytime seasonal mean AOD reach edits highest level over areas north of the Yangtze River in summer
over areas south of the Yangtze River in winter
and over areas along the middle and lower reaches of the Yangtze River in spring and autumn.Model verification indicated that RIEMS-Chem was able to reflect the characteristics of AOD distribution and its seasonal variation
but under predicted the observation by approximately 20% in terms of the annual mean. According to the model result
the daytime AOD distribution exhibited distinct subregional and seasonal characteristics over eastern China
implying that
over this region
aerosol optical and climatic effects could be subregional and seasonal dependent.
在线耦合区域模式气溶胶光学厚度AOD季节变化中国东部MODISAERONET
regional online-coupled modelAerosol Optical Depth(AOD)seasonal variationeastern ChinaMODISAERONET
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