包含超梯度力作用的台风次级环流诊断方程

次级环流在台风的发展和维持中起着重要作用,基于梯度风平衡的Sawyer Eliassen（SE）方程常用于台风次级环流的诊断。然而梯度风平衡关系在台风边界层及边界附近有较大误差,这导致SE方程求解出的次级环流在边界层也会有较大误差。本文在梯度风平衡方程中保留包含径向摩擦力项在内的超梯度力项,得到包含超梯度力作用的SE方程,从方程形式上看超梯度力主要是通过调节与斜压性相关的系数来影响次级环流的。对“森拉克”（2008）台风次级环流的诊断结果显示,在不人为改变边界层流场结构的情况下,新的SE方程能显著改善次级环流的求解效果,避免眼墙外侧边界层附近的虚假对流并且减小虚假入流。     

DISSIPATION EFFECT ON THE FLOW OVER MOUNTAINS

In the paper,the turbulent dissipation is considered in the model for studying the flow overmountains.The governing equation is a first order ordinary differential equation derived from analgebraic equation without dissipation case.The solution is sensitive to the upstream condition ofdissipation.The dissipation not only reduces the strength of discontinuity but also changes theproperties of the governing equation.In the paper,the qualitative characteristic features of thegoverning equation are discussed.The numerical results with super and sub-critical cases are alsodiscussed in detail.The results show that the turbulent dissipation is an important factor and is notnegligible.     

DISSIPATION EFFECT ON THE FLOW OVER MOUNTAINS*

In the paper,the turbulent dissipation is considered in the model for studying the flow over mountains.The governing equation is a first order ordinary differential equation derived from an algebraic equation without dissipation case.The solution is sensitive to the upstream condition of dissipation.The dissipation not only reduces the strength of discontinuity but also changes the properties of the governing equation.In the paper,the qualitative characteristic features of the governing equation are discussed.The numerical results with super and sub-critical cases are also discussed in detail.The results show that the turbulent dissipation is an important factor and is not negligible.     

边界微分方程及其应用

本文讨论二维Helmholtz方程外边值问题的求解,以较为严格的方式建立了更精准的新的边界微分方程.在贴体坐标系下,Helmholtz方程可转化为非齐次Bessel方程.将Bessel方程的一般解代入Sommerfeld辐射条件可以得到等价于原Helmholtz方程的积分-微分方程,再利用分部积分消去其中积分,即可建立高频问题的边界微分方程.文中通过若干算例对新得到的边界微分方程进行了数值验证.     

Discussion on the complete-form vorticity equation and slantwise vorticity development

The complete form of the vertical vorticity tendency equation (the complete-form vorticity equation) is derived from the Ertel potential vorticity equation to contain thermodynamic factors. In this study, a new complete-form vorticity equation, which has the same form as the original complete-form vorticity equation, is deduced from the absolute vorticity vector equation combined with the continuity equation and the expression of three-dimensional (3D) entropy gradient. By comparing the complete-form vorticity equation with the classical vertical vorticity equation, it is found that regardless of whether or not the isentropic surface is tilting, the two vorticity equations are in essence the same. The “baroclinic term” of the complete-form vorticity equation is exactly equal to the solenoidal term of the classical one, and there is a significant amount of cancellation between the two baroclinic items (the “slantwise term” and the horizontal vorticity change term) in the complete-form vorticity equation. In operational weather analysis, the tilt of the isentropic surface can be diagnosed according to the density of the isotherm on the upper-level isobaric map. For synoptic-scale motion, the vertical vorticity produced by the tilt of the isentropic surface is due to the contribution of atmospheric baroclinicity, which is measured by the solenoid. The 3D solenoid is parallel to the isentropic surface, so the more tilted the isentropic surface, the bigger the projection of the 3D solenoid in the vertical direction. The baroclinic contribution can be interpreted based on the PV thinking theory, but the relationship between the vorticity field and the potential vorticity field is not immediate.     

Rossby波的能量、能量通量与Lagrange函数

利用正压涡度方程计算波动能量通量时,它的形式将不同于直接利用运动方程所求得的通量,这是一个于六十年代初所提出的问题。在本文中,对此问题进行再次分析与研究。结果表明,如果将运动方程进行改写,使其包含了与涡度方程相等的条件,对于波动而言,就整个波动范围求平均且假定波动振幅为常数,则可得到相同的表示式。于文中,还利用此改写的运动方程,导得了波动位能的表示式,这为进一步研究非线性Rossby波提供了一个物理基础。     

ENERGY,ENERGY FLUX AND LAGRANGIAN OF ROSSBY WAVE

The energy flux derived from the barotropic vorticity equation differs from that obtained directly from the momentum equation.We re-study this problem raised in the early 1960s.The results show that if the momentum equation is rewritten in such a way that it contains the same conditions as that for the barotropic vorticity equation,then the same form of average energy flux can be obtained for the waves with constant amplitudes.With this new momentum equation,the potential energy of Rossby wave is derived and Lagrangian of nonlinear barotropic vorticity equation can be approximately found with this potential energy.This provides a physical basis for studying the dynamics of nonlinear Rossby wave with the approach of calculus of variation.     

非线性平衡方程初值化方法及其在中期数值天气预报试验中的应用

本文给出了一种求解非线性平衡方程的新的有效的方法及有关的数值试验结果。和以往的求解方法相比，本方法的优点是:收敛速度快，不需要冗长的迭代计算，也不需要对初始高度场的某些记录作修改，并能节省大量的计算时间。文中利用北半球七层原始方程谱模式，使用了1982年的客观分析资料，进行中期数值天气预报试验。试验结果表明，用非线性平衡方程初值化方法制作中期数值预报比其他的如线性平衡方程初值化方程的更佳。后者因去掉了非线性项的作用，天气系统的强度预报结果偏弱且偏平滑。     

作用于台风系统的动力——热力因子分析

本文导出了台风运动,结构和强度变化的关系方程式,该式表明作用于台风系统的动力－热力因子同时影响台风运动,结构和强度的变化。本文还是导出了台风系统内凝结与降水的不平衡与台风运动的关系方程式,分析该方程所得结果与台风运动的一些实际情况和统计研究结果一致。     

A Homogeneous Langevin Equation Model, Part i: Simulation of Particle Trajectories in Turbulence with a Skewed Velocity Distribution

A Lagrangian stochastic model for the time evolution of the velocity of a fluid particle is presented. This model is based on a one-dimensional generalized Langevin equation, and assumes the velocity probability distribution of the turbulent fluid is skewed and spatially homogeneous. This has been shown to be an effective approach to simulating vertical dispersion in the convective boundary layer. We use a form of the Langevin equation that has a linear (in velocity) deterministic acceleration and a random acceleration that is a non-Gaussian, skewed process. For the case of homogeneous fluid velocity statistics, this 'linear-skewed' Langevin equation can be integrated explicitly, resulting in an efficient numerical simulation method. Model simulations were tested using cases for which exact, analytic statistical properties of particle velocity are known. Results of these tests show that, for homogeneous turbulence, a linear-skewed Langevin equation model can overcome the difficulties encountered in applying a Langevin equation with a skewed random acceleration. The linear-skewed Langevin equation model results are compared to results of a 'nonlinear-Gaussian' Langevin equation model, and show that the linear-skewed model is significantly more efficient.