塔克拉玛干沙漠腹地复合沙垄的流场和上覆沙丘组合及动态特征

复合沙垄是最大的沙丘地貌类型之一，表现为简单沙丘类型的垂直叠加和水平连接，在沙垄的高大地形影响下，沙垄不同部位形成不同的风沙环境特征。以塔克拉玛干沙漠腹地/复合沙垄为例，通过野外实地观测研究其流场和上覆沙丘组合特征。研究结果表明，复合沙垄的流场可分为沙垄迎风坡气流加速区、沙垄背风坡气流转向减速区、垄间粗沙平地气流风速风向恢复区和气流风速稳定区。受沙垄流场和地形的控制，沙垄上覆新月形沙丘链，垄间地分有简单新月形沙丘、沙堆、沙片、侵蚀地、简单线形沙丘。上覆沙丘分布特征表现为：垄间地上覆新月形沙丘疏密度较小，沙垄迎风坡和沙垄背风坡上覆新月形沙丘疏密度较大，而且超过1，说明沙垄迎背风坡上覆沙丘有叠置现象。沙垄上覆沙丘高度自沙垄迎风坡底部到顶部增高，背风坡上覆沙丘高度自沙垄顶部到背风坡底部减小，上覆沙丘在自身形态、地形和流场的共同影响下，存在相对运动，表现为分布进一步集中，因此沙垄有增高的趋势。     

Spatial distribution of wind erosion and its driving factors in China

Soil erosion by wind means the soil particles are eroded and transported by wind. Fine particles of soil are transported as suspended load and may travel much greater distances than the coarse coarse materials do which are transported as creep and saltation. The finest particles and chemical microsome constitute the aerosol which can even keep for several years in atmosphere from descending. Wind erosion is a serious problem in many parts of the world. In China, up to 2400 km2 of land is dese…     

Sand-dust storms in China: temporal-spatial distribution and tracks of source lands

1 IntroductionSand-dust storms include both sand storms and dust storms[1]. When the visibility in local areas is greater than or equal to 50 m but less than 200 m, they are called severe sand-dust storms. When extremely severe sand-dust storm, the most severest type of sand-dust storm, occurs, the local instantaneous maximum wind speed can be greater than 25 m/s and a local visibility be less than 50 m or even descend to 0 m[2].Sand-dust storm is a critical environmental problem and is also a…     

99洪水和对进一步治理太湖的探讨

1999年太湖流域发生了特大洪水,太湖最高洪水位达5.08m,创历史新高.文中分析了1999年洪水的雨情、水情及其特点.阐述了已建治理太湖工程的防洪作用和减灾效益,并对太湖流域的进一步治理作了探讨.     

Storm deposits and storm-generated coarse carbonate breccias on a pelagic outer shelf (South-East Basin, France)

Uppermost Jurassic limestones of the South‐East Basin (France) are organized into four facies associations that were deposited in four distinct zones: (1) peritidal lagoonal limestones; (2) bioclastic and reefal limestones; (3) pelagic lime mudstones; (4) lime mudstones/calcarenites/coarse breccias. Calcarenite deposits of zone 4 exhibit sedimentary structures that are diagnostic of deposition under wave‐induced combined flow. In subzone 4a, both vertical and lateral transitions from lime mudstone/calcarenite to breccia indicate in situ brecciation under wave‐cyclic loading. Breccias were produced by heterogeneous liquefaction of material previously deposited on the sea floor. Deposits in subzone 4a record relatively long periods (>400 kyr) of sedimentation below wave base, alternating with periods of deposition under wave‐induced currents and periods of in situ deformation. In this zone, storm waves were attenuated by wave–sediment interaction, and wave energy was absorbed by the deformation of soft sediment. With reference to present‐day wave attenuation, water depths in this zone ranged between 50 and 80 m. Landwards of the attenuation zone, in zone 3, storm waves were reduced to fair‐weather wave heights. Storm wave base was not horizontal and became shallower landwards. As a consequence, water depth and wave energy were not linearly related. On a small area of the seaward edge of subzone 4a, cobbles were removed by traction currents and redeposited in subzone 4b. There, they formed a 100‐m‐thick wedge, which prograded over 3 km and was built up by the stacking of 5‐ to 20‐m‐thick cross‐stratified sets of coarse breccia. This wedge records the transport and redeposition of cobbles by a high‐velocity unidirectional component of a combined flow. The increase in flow velocity in a restricted area is proposed to result from flow concentration in a channel‐like structure of the downwelling in the gulf formed by the basin. In more distal subzone 4c, the hydrodynamic effect of wave‐induced currents was quasi‐permanent, and brecciation by wave–sediment interaction occurred only episodically. This indicates that, seawards of the attenuation zone, hydrodynamic storm wave base was deeper than mechanical storm wave base. Uppermost Jurassic carbonates were deposited and soft‐sediment deformed on a hurricane‐dominated ramp of very gentle slope and characterized by a zone of storm wave degeneration, located seawards of a zone of sedimentation below wave base.     

Soil Loss by Wind Erosion for Three Different Textured Soils Treated with Polyacrylamide and Crude Oil, Iraq

ＩＮＴＲＯＤＵＣＴＩＯＮＬａｒｇｅａｒｅａｓｏｆａｒｉｄａｎｄｓｅｍｉａｒｉｄｒｅｇｉｏｎｓｏｆｔｈｅｗｏｒｌｄａｒｅａｆ ｆｅｃｔｅｄｂｙｗｉｎｄｅｒｏｓｉｏｎ .Ａｐｐｒｏｘｉｍａｔｅｌｙ 2 8.4%ｏｆｔｈｉｓａｒｅａａｒｅａｆｆｅｃｔｅｄｂｙｓｅｖｅｒｅａｎｄｖｅｒｙｓｅｖｅｒｅｗｉｎｄｅｒｏｓｉｏｎ (Ｋａｔｅｓｅｔａｌ.,1977) .ＩｎＩｒａｑ ,ｔｈｅａｒｉｄａｎｄｓｅｍｉａｒｉｄｒｅｇｉｏｎｓｒｅｐｒｅｓｅｎｔｎｅａｒｌｙ 75%ｏｆｔｈｅｔｏｔａｌｌａｎｄ .5 0 %ｏｆｔｈｉｓｌａｎｄｉｓｓｕｂｊｅｃ…     

赤道印度洋-太平洋地区海气系统的齿轮式耦合和ENSO事件 II.数值模拟

首先应用IAP/LASG GOALS气候模式的多年积分的结果，对赤道中西太平洋和印度洋 的SST和纬向风场进行分析，发现在模式中也同样存在与观测资料分析结果相似的“印太齿 轮式耦合”。基于此，设计了赤道太平洋和印度洋海域纬向风应力异常的4组敏感性试验， 去研究太平洋和印度洋海气相互作用的联系。结果表明，在太平洋或印度洋上的大气异常 信号通过印-太齿轮组合（GIP）作为桥梁（atmospheric bridge），影响到另一地的海气 相互作用，从而将太平洋上的ENSO类年际变率信号与印度洋环流和亚洲季风纬向分量的变 化联系起来。     

平凉“95．7．19”强对流风暴分析

分析具有代表性的平凉局地强对流风暴过程，揭示了平凉发生强对流天气独特的地形因素。     

二维滞弹性非静力平衡云模式第二部分──中低空风切变对云微物理过程的影响

本文运用已建立的二维时变云模式［1］，就中低空风垂直切变对对流和云微物理过程的影响进行了模拟研究。为此设计了五种方案进行了对比试验。结果表明：中低空风切变较小时，容易爆发对流；中低空切变不超过某一值时，对流发展缓慢，但最终会爆发强对流；一旦中低空风切变超过某一值时，则对流发展不起来。另一方面，中低空风切变可加强各云微物理过程及地面降水量。     

加拿大东海岸冬季风暴的分析

利用加拿大大气环境局第二次冬季风暴观测（简称ＣＡＳＰⅡ）的部分资料，对加拿在东海岸冬季风暴的发生，发展情况进行了分析，结果表明，大多数风暴能达到爆发性发展程度，并对其中一个形成眼区的强风暴例子做了进一步讨论。