全型垂直涡度倾向方程和倾斜涡度发展

文中证明了不仅包括动力因子,而且包括热力因子、摩擦耗散及非绝热加热作用的和可用于三维空间的全型垂直涡度倾向方程。证明经典的、平面上的涡度方程只是它的特例。并且用该全型涡度方程严格证明了倾斜涡度发展（ＳＶＤ）理论。沿着倾斜等熵面下滑的气块,当热力参数ＣＤ减小时,其垂直涡度将发展。最后通过用θ坐标模式模拟一次西南低涡的形成,证明ＳＶＤ引起的涡度发展要比传统所考虑的辐合项的贡献大一个量级。     

平均经圈环流在大气角动量和感热收支中的作用

本文研究相对座标系中近地表角动量的制造和自由大气中角动量的辐散之间的平衡机制,并与绝对参考系中的机制进行比较。 对1982年元月全球角动量和感热的收支分析证明,被激发的平均经圈环流具有下述特征:其下部水平支施加于大气的惯性矩与近地表角动量的制造相平衡,上部水平支反号的惯性矩与涡动角动量通量的辐合(散)相平衡;而其垂直支的绝热加热效应则平衡着自由大气中热通量的辐散和/或大气的非绝热加热。因而,无论动力上还是热力上,平均经圈环流在大气总环流中都起着重要的作用。     

赤道印度洋—太平洋地区海气系统的齿轮式耦合和ENSO事件 I.资料分析

利用历史观测数据,研究了印度洋海表温度（ＳＳＴ）的季节变化特征,证实赤道印度洋和东太平洋ＳＳＴ年际变化有显著的正相关,指出这种正相关是由于沿赤道印度洋上空纬向季风环流和太平洋上空Ｗａｌｋｅｒ环流之间显著的耦合造成的。这两个异常的纬向环流圈之间的耦合形式看起来很象是存在于赤道印度洋和太平洋上空的一对齿轮（简写为ＧＩＰ）,当一个作顺时向变化时,另一个则作反时向变化。文中还证明ＥＮＳＯ事件与ＧＩＰ的年际异常存在很好的对应关系,暖事件时ＧＩＰ为反向运转;冷事件时ＧＩＰ为正向运转;异常的ＧＩＰ的啮合点位于印尼群岛附近。对８０年代以来的ＥＮＳＯ事件的分析表明,每次事件前期异常的ＧＩＰ的啮合点首先出现在印度洋上空,然后逐渐传入太平洋,引起ＧＩＰ东侧的大气纬向风ｕ和ＳＳＴ同时发生异常变化。当这种风场和ＳＳＴ的异常变化发展东传到达赤道中东太平洋时,导致ＥＮＳＯ事件最终出现。本文由此指出印度洋上空纬向环流的异常可以通过印度洋和太平洋上空大气系统的齿轮式耦合去影响赤道中东太平洋的海－气相互作用并触发ＥＮＳＯ事件发生。     

1982-1983年冬季厄尔尼诺期间大气环流异常的诊断分析

本文利用ECMWF的逐日资料,对比分析了1982年12月和1980年12月的平均大气环流情况,结论是:1982—1983年El Nino事件对全球大气环流有重大影响。(1)El Nino事件不仅使Hadley环流得到加强,而且使所有经圈环流都有所加强;(2)El Nino事件使两个半球(特别是北半球)的中纬度西风加强,使对流层低层及中纬度200hPa附近的温度升高,中纬度的对流层低层有弱的降温;(3)El Nino事件使大气湿度明显增加,但在北半球副热带地区除近地面层外湿度都明显减小。 同大气环流基本状态的异常相应,El Nino事件也导致了大气中动量、热量和水汽输送的明显异常。这些物理量输送的异常不仅同平均环流的异常有关,而且扰动(特别是行星尺度的扰动)对此也有着重要贡献。      

Earth System Model FGOALS-s2: Coupling a dynamic global vegetation and terrestrial carbon model with the physical climate system model

Earth System Models （ESMs） are fundamental tools for understanding climate-carbon feedback. An ESM version of the Flexible Global Ocean-Atmosphere-Land System model （FGOALS） was recently developed within the IPCC AR5 Coupled Model Intercomparison Project Phase 5 （CMIP5） modeling framework, and we describe the development of this model through the coupling of a dynamic global vegetation and terrestrial carbon model with FGOALS-s2. The performance of the coupled model is evaluated as follows. The simulated global total terrestrial gross primary production （GPP） is 124.4 PgC yr-I and net pri- mary production （NPP） is 50.9 PgC yr-1. The entire terrestrial carbon pools contain about 2009.9 PgC, comprising 628.2 PgC and 1381.6 PgC in vegetation and soil pools, respectively. Spatially, in the tropics, the seasonal cycle of NPP and net ecosystem production （NEP） exhibits a dipole mode across the equator due to migration of the monsoon rainbelt, while the seasonal cycle is not so significant in Leaf Area Index （LAI）. In the subtropics, especially in the East Asian monsoon region, the seasonal cycle is obvious due to changes in temperature and precipitation from boreal winter to summer. Vegetation productivity in the northern mid-high latitudes is too low, possibly due to low soil moisture there. On the interannual timescale, the terrestrial ecosystem shows a strong response to ENSO. The model- simulated Nifio3.4 index and total terrestrial NEP are both characterized by a broad spectral peak in the range of 2-7 years. Further analysis indicates their correlation coefficient reaches -0.7 when NEP lags the Nifio3.4 index for about 1-2 months.     

青藏高原对亚洲夏季风爆发位置及强度的影响

通过数值模拟,研究了青藏高原位于不同经度位置时,亚洲夏季风的爆发和演变情况,从动力和热力学角度分析了青藏高原大地形对亚洲夏季风爆发位置的影响。结果表明,青藏高原的“热力滑轮”作用引起:高原东南面热带陆地上空的偏南气流加强,降水增加,凝结潜热加强;高原西南面热带陆地上空出现偏北气流,降水减弱,陆面的感热加热加强。青藏高原对于亚洲夏季风的爆发地点有锚定的作用,在热带海陆分布的背景下,使亚洲夏季风首先在高原东南面的海洋东岸—陆地西岸爆发,并使亚洲季风降水重新分布。     

An Updated Coupled Model for Land-Atmosphere Interaction. Part Ⅰ: Simulations of Physical Processes

A new two-way land-atmosphere interaction model (R42_AVIM) is fulfilled by coupling the spectral at- mospheric model (SAMIL_R42L9) developed at the State Key Laboratory of Numerical Modeling for Atmo- spheric Sciences and Geophysical Fluid Dynamics, Institute of Atmospheric Physics, Chinese Academy of Sci- ences (LASG/IAP/CAS) with the land surface model, Atmosphere-Vegetation-Interaction-Model (AVIM). In this coupled model, physical and biological components of AVIM are both included. Climate base state and land surface physical fluxes simulated by R42_AVIM are analyzed and compared with the results of R42_SSIB [which is coupled by SAMIL_R42L9 and Simplified Simple Biosphere (SSIB) models]. The results show the performance of the new model is closer to the observations. It can basically guarantee that the land surface energy budget is balanced, and can simulate June-July-August (JJA) and December-January- February (DJF) land surface air temperature, sensible heat flux, latent heat flux, precipitation, sea level pressure and other variables reasonably well. Compared with R42_SSIB, there are obvious improvements in the JJA simulations of surface air temperature and surface fluxes. Thus, this land-atmosphere coupled model will offer a good experiment platform for land-atmosphere interaction research.     

夏季青藏高原热力场和环流场的诊断分析 Ⅰ.盛夏高原西部地区的水汽状况

本文使用青藏高原气象科学实验测站观测资料、欧洲中心FGGE-Ⅲb资料、GMS1地球同步卫星云图资料、河流水文资料以及其他一些有关的资料,详细分析了1979年7月青藏高原地区,尤其是高原西部地区的水汽状况、水汽输入的通道,讨论了夏季青藏高原地区高湿状况的维持机制. 通过研究,发现在1979年盛夏青藏高原西部也是一个高水汽区域,有利于大量的湿对流系统活动,但西部比东南部的水汽含量要略低些;潜热加热是夏季高原西部重要的热源之一;除了过去已知的在高原东南和仲巴、定日一带的两条水汽通道外,水汽还可从高原西侧边界进入高原西部.在讨论夏季高原地区高湿状况的维持机制时发现,相对于高原东部,只需要较少的水汽输入就足以维持高原西部大气的高湿状态;高原西部的降水、蒸发和向土壤中渗透是接近于平衡的,水分循环主要是局地的内循环.     

One-dimensional self-weight consolidation with continuous drainage boundary conditions: Solution and application to clay-drain reclamation

Traditional consolidation theories cannot provide good predictions of consolidation settlement in land reclamation because of their assumptions that the influence of soil's self-weight is often neglected, and the drainage boundary is considered as fully pervious/impervious. In view of these limitations, an analytical solution is derived for one-dimensional self-weight consolidation problems with a continuous drainage boundary using the finite Fourier sine transform method. Following the classical Terzaghi's small strain theory, the soil's self-weight is considered to produce consolidation settlement in dredged materials with a constant coefficient of consolidation. The continuous drainage boundary can essentially describe the time-dependent variation of drainage capacity at the interface between two adjacent soil layers. By reducing the interface parameters, the effectiveness of the calculation is demonstrated against the Terzaghi's solution. The influence of interface parameters and soil's self-weight stress coefficient on self-weight consolidation is discussed. As expected, the rate of consolidation considering the self-weight stress is faster, although the dependency of consolidation rate on the material property of void ratio is neglected. Moreover, the plane of maximum excess pore-water pressure is estimated as a function of time factor, based on which a design chart is developed to optimize the layout of horizontal drains in land reclamation.     

青藏高原地表位涡密度强迫对2008年1月中国南方降水过程的影响Ⅱ:数值模拟

青藏高原东坡近地表的辐合能够增加地表的位涡密度（PVD）。高耸的青藏高原与等熵面相切, 其东坡近地表增加的位涡密度成为等熵面边界上的位涡密度强迫源。利用IAP/LASG FAMIL全球大气环流模式探究青藏高原地表位涡密度增长对2008年初中国华南地区雨雪灾害天气形成的影响。首先与观测资料对比发现, 通过张弛逼近动力初始化, 在参照试验中, 模式能够比较合理地再现青藏高原东部的地表位涡密度增长和1月24-27日中国华南的大气环流场及降水场。而在高原的地表位涡密度增长减弱的敏感性试验中高原下游区域特别是华南沿海、广西到山东一带的降水明显减小甚至消失。对结果的分析表明:青藏高原区域的地表位涡密度增长在低空能够增强中国华南沿海地区的南风和水汽输送以及负的绝对涡度平流输送;在高空, 高原上产生的正的位涡密度沿西风环流向下游输送, 形成高层正的绝对涡度平流。从而在高原下游形成绝对涡度平流随高度增强的大尺度环流背景, 有利于上升运动发展。同时, 高原地表位涡密度增长在低空所激发的气旋式环流增加了华南的水汽输送, 最终激发了华南极端降水的产生。该个例模拟的结果证实了青藏高原东部的地表位涡密度强迫激发其下游极端天气发生的一种新机制。