A GCM Study on the Mechanism of Seasonal Abrupt Changes

ＡＧＣＭＳｔｕｄｙｏｎｔｈｅＭｅｃｈａｎｉｓｍｏｆＳｅａｓｏｎａｌＡｂｒｕｐｔＣｈａｎｇｅｓＷａｎｇＨｕｉｊｕｎ（王会军）ａｎｄＺｅｎｇＱｉｎｇｃｕｎ（曾庆存）（ＬＡＳＧ，ＩｎｓｔｉｔｕｔｅｏｆＡｔｍｏｓｐｈｅｒｉｃＰｈｙｓｉｃｓ，ＣｈｉｎｅｓｅＡｃ...     

The Effect of Weak Shear－induced Motion on Brownian Coagulation of Aerosol Particles

ＴｈｅＥｆｆｅｃｔｏｆＷｅａｋＳｈｅａｒ－ｉｎｄｕｃｅｄＭｏｔｉｏｎｏｎＢｒｏｗｎｉａｎＣｏａｇｕｌａｔｉｏｎｏｆＡｅｒｏｓｏｌＰａｒｔｉｃｌｅｓＷｉｎｊｉｎｇｓｏｎｓ（Ｃ．Ｓ．Ｗｉｎ）（温景嵩）（Ｄｅｐａｒｔｍｅｎｔｏｆｐｈｙｓｉｃｓ，Ｎａｎｋａｉ...     

Simulation of East Asian Summer Monsoon with IAP CGCM

ＳｉｍｕｌａｔｉｏｎｏｆＥａｓｔＡｓｉａｎＳｕｍｍｅｒＭｏｎｓｏｏｎｗｉｔｈＩＡＰＣＧＣＭＣｈｅｎＱｉｙｉｎｇ（陈起英），①ＹｕＹｏｎｇｑｉａｎｇ（俞永强）ａｎｄＧｕｏＹｕｆｕ（郭裕福）ＩｎｓｔｉｔｕｔｅｏｆＡｔｍｏｓｐｈｅｒｉｃＰｈｙｓｉｃｓ，Ｃｈ...     

On Mechanisms of Nucleation of Ice Crystals by Aerodynamic Cooling

ＯｎＭｅｃｈａｎｉｓｍｓｏｆＮｕｃｌｅａｔｉｏｎｏｆＩｃｅＣｒｙｓｔａｌｓｂｙＡｅｒｏｄｙｎａｍｉｃＣｏｏｌｉｎｇＨｕａｎｇＳｈｉｈｏｎｇ（黄世鸿）；ＱｉａｎＣｈａｎｇｇｕｏ（钱昌国）；ＷａｎｇＷｅｉｍｉｎ（王伟民）；ＬｉＲｕｘｉａｎｇ（李如祥）（Ｄ...     

Symmetric Development of Meso Perturbation in Zonally Curved Basic Flow

ＳｙｍｍｅｔｒｉｃＤｅｖｅｌｏｐｍｅｎｔｏｆＭｅｓｏＰｅｒｔｕｒｂａｔｉｏｎｉｎＺｏｎａｌｙＣｕｒｖｅｄＢａｓｉｃＦｌｏｗ①ＺｈｏｕＷｅｉｃａｎ（周伟灿），ＣｈｅｎＪｉｕｋａｎｇ（陈久康）ａｎｄＺｈｏｕＳｈｕｎｗｕ（周顺武）ＮａｎｊｉｎｇＩｎｓｔｉｔ...     

The Capability of Atmospheric Profile Retrieval from Satellite High Resolution Infrared Sounder Radiances

ＴｈｅＣａｐａｂｉｌｉｔｙｏｆＡｔｍｏｓｐｈｅｒｉｃＰｒｏｆｉｌｅＲｅｔｒｉｅｖａｌｆｒｏｍＳａｔｅｌｌｉｔｅＨｉｇｈＲｅｓｏｌｕｔｉｏｎＩｎｆｒａｒｅｄＳｏｕｎｄｅｒＲａｄｉａｎｃｅｓＬｉＪｕｎ（李俊）（Ｃｏｏｐｅｒａｔｉｖｅｉｎｓｔｉｔｕｔｅｆｏ...     

Impacts of Land Surface on Climate of July and On set of Summer Monsoon:A Study with an AGCM plus SSiB

ＩｍｐａｃｔｓｏｆＬａｎｄＳｕｒｆａｃｅｏｎＣｌｉｍａｔｅｏｆＪｕｌｙａｎｄＯｎｓｅｔｏｆＳｕｍｍｅｒＭｏｎｓｏｏｎ：ＡＳｔｕｄｙｗｉｔｈａｎＡＧＣＭｐｌｕｓＳＳｉＢ①ＬｉｕＨｕｉ（刘辉）ａｎｄＷｕＧｕｏｘｉｏｎｇ（吴国雄）ＳｔａｔｅＫｅｙＬａｂｏｒ...     

Global Oceanic Climate Anomalies in 1980''''s

ＧｌｏｂａｌＯｃｅａｎｉｃＣｌｉｍａｔｅＡｎｏｍａｌｉｅｓｉｎ１９８０′ｓＦｕＣｏｎｇｂｉｎ（符淙斌）ａｎｄＸｉｅＬｉ（谢力）ＩｎｓｔｉｔｕｔｅｏｆＡｔｍｏｓｐｈｅｒｉｃＰｈｙｓｉｃｓ,ＣｈｉｎｅｓｅＡｃａｄｅｍｙｏｆＳｃｉｅｎｃｅｓ,Ｂｅｉｊｉｎｇ...     

Effect of the Interaction of Different Scale Vortices on the Structure and Motion of Typhoons

ＥｆｆｅｃｔｏｆｔｈｅＩｎｔｅｒａｃｔｉｏｎｏｆＤｉｆｆｅｒｅｎｔＳｃａｌｅＶｏｒｔｉｃｅｓｏｎｔｈｅＳｔｒｕｃｔｕｒｅａｎｄＭｏｔｉｏｎｏｆＴｙｐｈｏｏｎｓＣｈｅｎＬｉａｎｓｈｏｕ（陈联寿）（ＣｈｉｎｅｓｅＡｃａｄｅｍｙｏｆＭｅｔ６ｏｒｏｌｏｇｉｃ...     

Seasonal and Extraseasonal Predictions of Summer Monsoon Precipitation by Gcms

ＳｅａｓｏｎａｌａｎｄＥｘｔｒａｓｅａｓｏｎａｌＰｒｅｄｉｃｔｉｏｎｓｏｆＳｕｍｍｅｒＭｏｎｓｏｏｎＰｒｅｃｉｐｉｔａｔｉｏｎｂｙＧｃｍｓ①ＺｅｎｇＱｉｎｇｃｕｎ（曾庆存），ＹｕａｎＣｈｏｎｇｇｕａｎｇ（袁重光），ＬｉＸｕ（李旭），ＺｈａｎｇＲｏｎｇ...     

The urban heat island in the city of Poznań as derived from Landsat 5 TM

Deforestation is expanding and accelerating into the remaining areas of undisturbed forest, and the quality of the remaining forests is declining today. Assessing the climatic impacts of deforestation can help to rectify this alarming situation. In this paper, how historical deforestation may affect global climate through interactive ocean and surface albedo is examined using an Earth system model of intermediate complexity (EMIC). Control and anomaly integrations are performed for 1000 years. In the anomaly case, cropland is significantly expanded since AD 1700. The response of climate in deforested areas is not uniform between the regions. In the background of a global cooling of 0.08 °C occurring with cooler surface air above 0.4 °C across 30° N to 75° N from March to September, the surface albedo increase has a global cooling effect in response to global-scale replacement of forests by cropland, especially over northern mid-high latitudes. The northern mid-latitude (30° N–60° N) suffers a prominent cooling in June, suggesting that this area is most sensitive to cropland expansion through surface albedo. Most regions show a consistent trend between the overall cooling in response to historical deforestation and its resulting cooling due to surface albedo anomaly. Furthermore, the effect of the interactive ocean on shaping the climate response to deforestation is greater than that of prescribed SSTs in most years with a maximum spread of 0.05 °C. This difference is more prominent after year 1800 than that before due to the more marked deforestation. These findings show the importance of the land cover change and the land surface albedo, stressing the necessity to analyze other biogeophysical processes of deforestation using interactive ocean.     

Possible climatic impacts of land cover transformations,with particular emphasis on tropical deforestation

The climatic impact of albedo changes associated with land-surface alterations has been examined. The total surface global albedo change resulting from major land-cover transformations (i.e. deforestation, desertification, irrigation, dam-building, urbanization) has been recalculated, modifying the estimates of Sagan et al., (1979). Tropical deforestation (11.1 million ha yr^-1, or 0.6% yr^-1, Lanly, 1982) ranks as a major cause of albedo change, although uncertainties in the areal extent of desertification could conceivably render this latter process of similar significance. The maximum total global albedo change over the last 30 yr for the various processes lies between 0.000 33 and 0.000 64, corresponding to a global temperature decrease of between 0.06 K and 0.09 K (scaled from the 1-D radiative convective model of Hansen et al., 1981), which falls well below the interannual and longer period variability.An upper bound to the impact of tropical deforestation was obtained by concentrating all vegetation change into a single region. The magnitude of this modification is equivalent to 35–50 yr of global deforestation at the current rate, but centered on the Brazilian Amazon. The climatic consequences of such tropical deforestation were simulated, using the GISS GCM (Hansen et al., 1983). In the simulation, a total area of 4.94 × 10⁶ km² of tropical moist forest was removed and replaced by a grass/crop cover. Although surface albedo increased from 0.11 to 0.19, the effect upon surface temperature was negligible. However, other climate parameters were altered. Rainfall decreased by 0.5–0.7 mm day^-1 and both evapotranspiration and total cloud cover were reduced. The absence of a temperature decrease in spite of the increased surface albedo arises because the reduction in evapotranspiration has offset the effects of radiative cooling. The decrease in cloud cover also counteracts the increase in surface albedo. These locally significant changes had no major impact on regional (Hadley or Walker cells) or the global circulation patterns.We conclude that the albedo changes induced by current levels of tropical deforestation appear to have a negligibly small effect on the global climate.     

A dampened land use change climate response towards the tropics

In climate simulations we find a pronounced meridional (equator to pole) gradient of climate response to land cover change. Climate response approaches zero in the tropics, and increases towards the poles. The meridional gradient in climate response to land cover change results from damping feedbacks in the tropics, rather than from polar amplification. The main cause for the damping in the tropics is the decrease in cloud cover after deforestation, resulting in increased incoming radiation at the surface and a lower planetary albedo, both counteracting the increase in surface albedo with deforestation. In our simulations, deforestation was also associated with a decrease in sensible heat flux but not a clear signal in evaporation. Meridional differences in climate response have implications for attribution of observed climate change, as well as for climate change mitigation strategies.     

Boreal forest and tundra ecosystems as components of the climate system

The effects of terrestrial ecosystems on the climate system have received most attention in the tropics, where extensive deforestation and burning has altered atmospheric chemistry and land surface climatology. In this paper we examine the biophysical and biogeochemical effects of boreal forest and tundra ecosystems on atmospheric processes. Boreal forests and tundra have an important role in the global budgets of atmospheric CO₂ and CH₄. However, these biogeochemical interactions are climatically important only at long temporal scales, when terrestrial vegetation undergoes large geographic redistribution in response to climate change. In contrast, by masking the high albedo of snow and through the partitioning of net radiation into sensible and latent heat, boreal forests have a significant impact on the seasonal and annual climatology of much of the Northern Hemisphere. Experiments with the LSX land surface model and the GENESIS climate model show that the boreal forest decreases land surface albedo in the winter, warms surface air temperatures at all times of the year, and increases latent heat flux and atmospheric moisture at all times of the year compared to simulations in which the boreal forest is replaced with bare ground or tundra. These effects are greatest in arctic and sub-arctic regions, but extend to the tropics. This paper shows that land-atmosphere interactions are especially important in arctic and sub-arctic regions, resulting in a coupled system in which the geographic distribution of vegetation affects climate and vice versa. This coupling is most important over long time periods, when changes in the abundance and distribution of boreal forest and tundra ecosystems in response to climatic change influence climate through their carbon storage, albedo, and hydrologic feedbacks.     

中国地区MODIS地表反照率反演结果的时空分布研究

应用2003—2015年MODIS地表反照率反演质量数据MCD43A2,统计分析中国地区MODIS地表反照率反演质量的时空分布特征,结果表明:1)中国地区MODIS地表反照率反演质量在空间分布上具有明显的差异,高质量全反演结果(质量标记0)主要分布在东北、华北、西北地区和西南地区的中西部;当量反演结果(质量标记3)主要分布在华东、华中、华南地区和西南地区的中东部;填充值(质量标记15)主要分布在华中、华南、华东地区及西南地区的部分区域。2)在东北、华北和西北地区,只有春、夏和秋季才有超过60%的区域可能获得高精度MODIS地表反照率;可能获得高精度M ODIS地表反照率的区域,在西南地区全年各时段都只有40%~60%,在华东、华中和华南地区全年各时段都不足20%。3)各地当量反演结果的比例一般不足50%,华东和华中地区夏季和秋季当量反演结果的比例超过40%;4)华中和华东地区夏季和冬季,以及华南地区春、夏和冬季,填充值的比例超过50%,华南和华中地区最高甚至超过80%。     

Climatic change due to land surface alterations

A primitive equations global zonally averaged climate model is developed. The model includes biofeedback mechanisms. For the Northern Hemisphere the parameterization of biofeedback mechanisms is similar to that used by Gutman et al. (1984). For the Southern Hemisphere new parameterizations are derived. The model simulates reasonably well the mean annual zonally averaged climate and geobotanic zones.Deforestation, desertification and irrigation experiments are performed. In the case of deforestation and desertification there is a reduction in the surface net radiation, evaporation and precipitation and an increase in the surface temperature. In the case of irrigation experiment opposite changes occurred. In all the cases considered the changes in evapotranspiration overcome the effect of surface albedo modification. In all the experiments changes are smaller in the Southern Hemisphere.     

Biogeophysical impacts of land use on present-day climate: near-surface temperature change and radiative forcing

Changes in land cover affect climate through the surface energy and moisture budgets, but these biogeophysical impacts of land use have not yet been included in General Circulation Model (GCM) simulations of 20th century climate change. Here, the importance of these effects was assessed by comparing climate simulations performed with current and potential natural vegetation. The northern mid-latitude agricultural regions were simulated to be approximately 1–2 K cooler in winter and spring in comparison with their previously forested state, due to deforestation increasing the surface albedo by approximately 0.1 during periods of snow cover. Some other regions such as the Sahel and India experienced a small warming due to land use. Although the annual mean global temperature is only 0.02 K lower in the simulation with present-day land use, the more local temperature changes in some regions are of a similar magnitude to those observed since 1860. The global mean radiative forcing by anthropogenic surface albedo change relative to the natural state is simulated to be −0.2 Wm², which is comparable with the estimated forcings relative to pre-industrial times by changes in stratospheric and tropospheric ozone, N₂O, halocarbons, and the direct effect of anthropogenic aerosols. Since over half of global deforestation has occurred since 1860, simulations of climate since that date should include the biogeophysical effects of land use.     

Rain follows logging in the Amazon? Results from CAM3–CLM3

The impact of logging on precipitation in the Amazon region is investigated based on numerical experiments using the community atmosphere model version 3 coupled with the community land surface model version 3 (CAM3–CLM3). Three different representations of logging are examined, ranging from selective logging, to partial deforestation, to clear cut. Precipitation increases in response to modest selective logging, and decreases as the severity of logging progresses to partial deforestation and clear cut. Further experiments indicate that the increase of precipitation is mostly due to the decrease of surface albedo following selective logging, resulting from a low contrast between bare soil albedo and vegetation optical properties (i.e., leaf reflectance) in CLM3. This study demonstrates the complexity of representing land cover changes in climate models, and underlines the importance of accuracy in albedo measurement from satellite remote sensing.     

Simulation of desert-scrub growth: A forcing to warmer and more pluvial climate

Desert-fringe vegetation growing over bright, sandy soils reduces the surface albedo from above 0.4 to well be-low 0.3. Called desert-scrub, these shrubs form a predominantly vertical clumps protruding from the soil-level, thereby significantly increasing the coefficient of turbulent heat transfer from the surface. The impact on global and desert-belt climate of changes in these two surface characteristics was simulated by a multi-layer energy balance model. Evaluated only as a forcing to a further climatic change (that is, without accounting for any possible feedbacks) the results are: if vegetation (such as apparently existed under the warmer climate of 6,000 BP) grows over large areas in the arid, currently bare-soil regions, the annual Northern Hemisphere surface temperature increases by 0.7oC (by 0.6oC in July ), the surface temperature over land in the 20-30oN zone increases by 0.9oC in both the annual and the July means, and the land-ocean annual temperature contrast in this zone increases by 0.25oC (0.2oC in July). These results represent the combined influence of the reduction in the surface albedo and of the increase in the coefficient of turbulent heat transfer. In the desert-belt zones, the increase in the transfer coefficient sharply reduces the land temperature and the land-ocean temperature contrast from the values produced by the albedo change alone. This reduction must be attributed to the increased land-to-ocean circulation (which our model does not evaluate ex-plicitly). Considering that a stronger circulation (resulting from land-ocean temperature contrast) generally forces a higher rainfall, the vegetation which emerged in the arid regions during the post-glacial optimum should be consid-ered a. significant positive feedback towards a still warmer, and also a more pluvial, climate. Our study may have im-plications for the 21st century, if the global warming expected from the enhanced greenhouse effects is accompanied by increased precipitation over the continents.     

Land Cover, Rainfall and Land-Surface Albedo in West Africa

Land surface albedo is an important variable in General Circulation Models (GCMs). When land cover is modified through anthropogenic land use, changes in land-surface albedo may produce atmospheric subsidence and reduction of rainfall. In this study we examined albedo time series and their relationships with rainfall, land cover, and population in West Africa. This particular region was selected because it has become a focal point in debates over biophysical impacts of desertification and deforestation. Our analyses revealed that albedo and rainfall were related only modestly at short time scales (monthly and annual) and that mean annual albedo values remained relatively stable from 1982–1989 over a widerange of climatic and vegetation zones in West Africa. The relationship between long-term mean rainfall and mean albedo was strong and curvilinear(r² = 0.802). The same was true for the relationship betweenpercent tree cover and mean albedo (r² = 0.659). These results suggest that long-term climate patterns, which control vegetation type and canopy structure, have greater influence on albedo than short-term fluctuations in rainfall. Our results reinforce other recent studies based on satellite data that have questioned the extent and pervasiveness of desertification in West Africa.