贵州山区山谷地形大气边界层夏季风温廓线结构特征分析

利用2006年夏季在贵州省绥阳县进行的系留气艇高空探测及超声脉动风速仪监测试验资料,分析了贵州山区边界层风温垂直廓线的结构特征,结果显示：（1）绥阳县500m以下空间平均温度基本上随高度递减,500～1000m之间等温层和逆温层出现频率较高;（2）山区边界层内风向随高度变化复杂,风速廓线一般遵循随高度递增的规律,1000m至边界层顶风速有逐渐减小的趋势;（3）该地区山谷风环流明显,并随气层不稳定程度的增加而递增,在夜间达到最大。     

地形上空边界层流中低层锋面结构的理论研究Ⅰ:冷锋、均匀地转流

文中利用一个包含地形、边界层摩擦作用的二层锋面简化模型,讨论了地形、边界层对冷锋锋面结构、环流的动力学影响作用问题.冷锋的倾斜主要与冷锋暖区的地转流分布、锋面移动速度、锋面与地形的相对位置有关.当冷锋位于迎风坡时,其坡度减小,位于背风坡时,其坡度增大.在静止冷锋存在两类不同的环流系,即位于大气低层、地面锋附近的反时针环流系和远离地面锋的顺时针环流系.静止冷锋位于背风坡,其冷域中的这支闭合环流增强,范围增大,而位于冷锋界面上的环流转向点沿锋面上移,暖域中沿锋面的暖空气运动范围变大.当静止冷锋位于迎风坡时,结果相反.冷锋移动较慢时,其冷域远离地面锋的这支顺时针环流主体可被地形完全阻塞在迎风坡.当静止冷锋移离地形时,由于地形作用可在锋面暖域、地形下游形成一个背风槽.地形对锋区的垂直运动影响主要通过地形与边界层共同作用,改变锋区流场辐合辐散的分布及地形强迫抬升两条途径实现.由于边界层摩擦的辐合作用,在地面冷锋的前缘可形成一支范围较窄、强度较大的上升运动带,当冷锋位于迎风坡时,其强度增强,当冷锋位于背风坡时,其强度减弱.当冷锋位于背风坡时,在暖区沿锋面上升的暖空气运动范围增大,可以出现沿锋面相间隔的多个上升区.     

地形上空边界层流中低层锋面结构的理论研究 I：冷锋、均匀地转流

文中利用一个包含地形、边界层摩擦作用的二层锋面简化模型 ,讨论了地形、边界层对冷锋锋面结构、环流的动力学影响作用问题。冷锋的倾斜主要与冷锋暖区的地转流分布、锋面移动速度、锋面与地形的相对位置有关。当冷锋位于迎风坡时 ,其坡度减小 ,位于背风坡时 ,其坡度增大。在静止冷锋存在两类不同的环流系 ,即位于大气低层、地面锋附近的反时针环流系和远离地面锋的顺时针环流系。静止冷锋位于背风坡 ,其冷域中的这支闭合环流增强 ,范围增大 ,而位于冷锋界面上的环流转向点沿锋面上移 ,暖域中沿锋面的暖空气运动范围变大。当静止冷锋位于迎风坡时 ,结果相反。冷锋移动较慢时 ,其冷域远离地面锋的这支顺时针环流主体可被地形完全阻塞在迎风坡。当静止冷锋移离地形时 ,由于地形作用可在锋面暖域、地形下游形成一个背风槽。地形对锋区的垂直运动影响主要通过地形与边界层共同作用 ,改变锋区流场辐合辐散的分布及地形强迫抬升两条途径实现。由于边界层摩擦的辐合作用 ,在地面冷锋的前缘可形成一支范围较窄、强度较大的上升运动带 ,当冷锋位于迎风坡时 ,其强度增强 ,当冷锋位于背风坡时 ,其强度减弱。当冷锋位于背风坡时 ,在暖区沿锋面上升的暖空气运动范围增大 ,可以出现沿锋面相间隔的多个上升区     

地形上空边界层流中低层锋面结构的理论研究Ⅱ:暖锋、均匀地转流

利用一个有地形、边界层摩擦作用、简化的二层浅水锋面模型,在理论上研究了地形上空边界层流动中地面暖锋的结构及环流分布特征问题。暖锋的坡度主要取决于其暖域地转流、锋面移速,它随锋面移速增大而减小,这与冷锋特征相反。地形对暖锋坡度的影响作用较小。与无地形作用时相比,静止性暖锋冷域中,位于锋面界面附近的闭合正环流系,当暖锋位于地形上游,其伸展范围增大;当暖锋位于迎风坡时,其伸展范围缩小,中心位置上抬;锋面移至背风坡时,其伸展范围重新增大。对于冷域中远离地面暖锋的另一支正环流系来说,当暖锋位于地形上游或迎风坡时,它可被地形完全阻塞于背风侧,地形高度越高,地形阻塞作用越大。在暖锋锋区附近主要存在三支垂直上升运动带：（a）由于边界层摩擦辐合作用,导致在地面暖锋后缘暖区中形成一支水平尺度较小、强度较大的垂直运动带,它随着暖锋移速增大而减弱。该垂直运动带,当暖锋位于地形迎风侧,强度增加;暖锋位于地形背风侧,其强度减弱。（b）在锋区暖域沿锋面存在均匀的上升运动,（c）在冷域远离地面暖锋处,存在一支水平范围较宽,其中心位于边界层顶部附近的垂直运动带,当暖锋位于迎风坡时,这支垂直运动带可被地形阻塞于地形背风侧。     

地形上空边界层流中低层锋面结构的理论研究II:暖锋、均匀地转流

利用一个有地形、边界层摩擦作用、简化的二层浅水锋面模型,在理论上研究了地形上空边界层流动中地面暖锋的结构及环流分布特征问题.暖锋的坡度主要取决于其暖域地转流、锋面移速,它随锋面移速增大而减小,这与冷锋特征相反.地形对暖锋坡度的影响作用较小.与无地形作用时相比,静止性暖锋冷域中,位于锋面界面附近的闭合正环流系,当暖锋位于地形上游,其伸展范围增大;当暖锋位于迎风坡时,其伸展范围缩小,中心位置上抬;锋面移至背风坡时,其伸展范围重新增大.对于冷域中远离地面暖锋的另一支正环流系来说,当暖锋位于地形上游或迎风坡时,它可被地形完全阻塞于背风侧,地形高度越高,地形阻塞作用越大.在暖锋锋区附近主要存在三支垂直上升运动带:(a)由于边界层摩擦辐合作用,导致在地面暖锋后缘暖区中形成一支水平尺度较小、强度较大的垂直运动带,它随着暖锋移速增大而减弱.该垂直运动带,当暖锋位于地形迎风侧,强度增加;暖锋位于地形背风侧,其强度减弱.(b)在锋区暖域沿锋面存在均匀的上升运动,(c)在冷域远离地面暖锋处,存在一支水平范围较宽,其中心位于边界层顶部附近的垂直运动带,当暖锋位于迎风坡时,这支垂直运动带可被地形阻塞于地形背风侧.     

北京局地降水中地形和边界层辐合线的作用

利用常规气象资料、雷达、风廓线和地面自动站资料,分析2007年7月两次局地对流天气过程发现,7月13日的局地短时暴雨是由低层东南风遇山脉抬升后产生的;7月10日的局地对流是由边界层辐合线触发形成的。利用风廓线可以判断天气形势和本站气象条件的变化。利用雷达回波图和地面自动站可以识别边界层辐合线。在考虑北京地形的同时,利用雷达严密监视天气,有望提高这类局地对流天气的预报、预警能力。     

小尺度深凹地形边界层影响因子的数值试验研究

建立了一个针对小尺度深凹地形的、高分辨的、三维非静力的边界层试验模式,通过求解非定常的方程组获得边界层的定常解。有选择地对影响深凹地形边界层结构的不同因子进行了数值试验研究。结果表明,深凹地形的深度Ｈ、坡度α以及初始地面风速ｕ０的大小和初始风速的垂直切变（Ｐ）等因子对边界层的结构有较大的影响,且模式具有较好的稳定性。     

地形与斜压边界层的动力分析

利用摄动方法,解析求解了含有地形的非线性斜压行星边界层的风场及其顶部的垂直速度。将所得结果与其它工作比较,说明了斜压性、地形和非线性平流对边界层中风场分布和顶部垂直速度的影响。     

Boundary layer evolution over a large and broad mountain basin

Summary In this study observations of the vertical structure of the Atmospheric Boundary Layer (ABL), recorded at a broad mountainous valley are presented. The vertical profiles of temperature, wind speed and direction up to a height of about 800 meters over the valley bottom have been measured and the temporal evolution of ABL structure of the area has been studied. Specifically, the mechanism of nocturnal inversion destruction during morning hours has been studied, which is of major importance in the study of the dispersion of air pollutants over the area. These observations suggest that the break up of nocturnal inversion during morning hours is mainly caused by a combined mechanism, the build up of the Convective Boundary Layer (CBL) and the presence of upslope winds, resulting to a continuous descent of the top of the nocturnal inversion.With 5 Figures     

On gravity wave-mean flow interactions in a three dimensional stratified atmosphere

By using multiple scale analysis method, two coupled models of gravity wave-mean flow interactions m a three-dimensional stratified atmosphere are derived. One model can be applied to the inertio-gravity wave-mean flow interactions in a global scale. The other one treats the meso-scale gravity wave forcing in a local region.     

分层气流条件下地形降水的二维理想数值试验

利用WRF v3.5中尺度数值模式,在条件不稳定层结下,针对分层气流(基本气流风速和大气湿浮力频率呈二层均匀分布)过山时,地形对降水的影响进行了多组二维理想数值试验,以研究不同高度、尺度山脉和不同方向基本气流对降水形态和分布的影响。模拟结果表明,地形重力波触发对流是地形降水的主要机制之一,地形波的特征(波长、振幅)和传播均受到地形和基本气流的影响,其中,强基本气流流经高而陡峭的山脉时,更容易在其背风坡捕捉到重力波,地形降水呈现多种模态,反之亦然;当改变基本气流与山脉交角时,主要通过影响地形强迫抬升速度、基流对波动稳定性发展来进一步影响地形降水的强度和分布。     

条件不稳定湿大气中三维理想地形上空对流的动力学特征

条件不稳定湿大气情况下,气流经过三维地形可以形成不同性质的对流系统以及不同特征的地形流结构,其对流系统、地形流的性质主要取决于地形上空的对流触发、对流-地形流-重力波三者之间的相互作用,同样这些过程对于地形降水的性质、分布起重要的作用.根据不同湿Fr数(Froude number),湿条件不稳定大气经过三维小尺度山地上空时其对流和地形流动存在4种不同的流域(flow regirnes):(1)下游传播对流模态;(2)上游传播和下游传播共存对流模态;(3)山峰附近准静止和下游传播共存对流模态;(4)下坡稳定和下游传播对流共存模态.地形上空对流系统主要可以通过两种不同机制形成:(1)地形直接的抬升或减速作用;(2)在地形流形成后,由于地形流本身特性(如上游分离、背风涡旋和下坡重力波破碎)触发.在较大的Fr数情况下,地形上空对流生成后反过来可以破坏上、下游的地形流结构,但对背风坡的重力波破碎影响较小.不同初始对流有效位能(CAPE)不仅可以影响对流系统的传播、发展,而且可以影响整体地形流性质.较低的初始CAPE有利于地形流的形成,此时对流对地形流结构特征的影响相对较小,其流场性质与低Fr数流域性质相似.     

Stably stratified flow in a marine atmospheric surface layer

Data from the marine atmospheric surface layer have been analysed. The data set consists of about two weeks with tower measurements up to 31 m of mean profiles of wind, temperature, and humidity, together with 20 Hz turbulence data. Mean wind, temperature, and humidity profiles up to 2000 m are also available from pibal trackings and radio soundings. Wave height was measured at 2 Hz, using an inverted echo-sounder.It was found from pibal wind profiles that low level jets were present during 2/3 of the measurements, having their maxima in the height interval 40 to 300 m. Here only data from the remaining 1/3 of the measurements, without low level jets, have been analysed.Non-dimensional wind and temperature gradients agree with results over homogeneous land surfaces as regards stability dependence during stable conditions that prevailed during this experiment. Linear regression gave _m = 1 + 6.8z/L and _m = 1 + 8.3z/L. No significant sea wave influence was found. The same was vrue for me dimensionless standard deviations of the three wind components, except for the vertical component. The expected wind speed dependence was found for the neutral drag coefficient, givingC _dN = 0.109U + 0.33 at 10 m, and a dependence on the wave parameter,C/u _*, was confirmed. Note, however, that the data set was restricted to low and moderate wind speeds and that stratification was mainly stable.Power spectra, non-dimensionalized according to suface-layer theories, do not follow the expected stability dependence. It was shown that this may be a consequence of the presence of gravity waves in the stable marine boundary layer. Indicators of gravity waves were found in most runs. The TKE budget agrees with findings over homogeneous land areas. The pressure transport term was found to be a source of energy also for near neutral conditions.     

Airflow over a mountain and the convective boundary layer

In this paper, the analytical model coupling the convective boundary layer (CBL) with the free atmosphere developed by Qi and Fu (1992) is improved. And by this improved model, the interaction between airflow over a mountain and the CBL is further discussed. The conclusions demonstrate: (1) The perturbation potential temperatures in the free atmosphere can counteract the effect of orographic thermal forcing through entraining and mixing in the CBL. If _M > _F , the feedback of the perturbation potential temperatures in the free atmosphere is more important than orographic thermal forcing, which promotes the effect of interfacial waves. If _M < _F , orographic thermal forcing is more important, which makes the interfacial height and the topographic height identical in phase, and the horizontal speeds are a maximum at the top of the mountain. (2) The internal gravity waves propagating vertically in the free atmosphere cause a strong downslope wind to become established above the lee slope in the CBL and result in the hydraulic jump at the top of the CBL. (3) With the CBL deepening, the interfacial gravity waves induced by the potential temperature jump at the top of the CBL cause the airflow in the CBL to be subcritical.     

The structure of the stably stratified internal boundary layer in offshore flow over the sea

Observations obtained mainly from a research aircraft are presented of the mean and turbulent structure of the stably stratified internal boundary layer (IBL) over the sea formed by warm air advection from land to sea. The potential temperature and humidity fields reveal the vertical extent of the IBL, for fetches out to several hundred of kilometres, geostrophic winds of 20–25 m s^–1, and potential temperature differences between undisturbed continental air and the sea surface of 7 to 17 K. The dependence of IBL depth on these external parameters is discussed in the context of the numerical results of Garratt (1987), and some discrepancies are noted.Wind observations show the development of a low-level wind maximum (wind component normal to the coast) and rotation of the wind to smaller cross-isobar flow angles. Potential temperature () profiles within the IBL reveal quite a different structure to that found in the nocturnal boundary layer (NBL) over land. Over the sea, profiles have large positive curvature with vertical gradients increasing monotonically with height; this reflects the dominance of turbulent cooling within the layer. The behaviour is consistent with known behaviour in the NBL over land where curvature becomes negative (vertical gradients of decreasing with height) as radiative cooling becomes dominant.Turbulent properties are discussed in terms of non-dimensional quantities, normalised by the surface friction velocity, as functions of normalised height using the IBL depth. Vertical profiles of these and the normalised wavelength of the spectral maximum agree well with known results for the stable boundary layer over land (Caughey et al., 1979).     

The stably stratified boundary layer over the great plains

Airplane measurements of the stably stratified boundary layer obtained during the Severe Environmental Storms and Mesoscale Experiment (SESAME) over rolling terrain in south-central Oklahoma indicate that considerable horizontal variability exists in the flow on scales of several kilometers. Much of this wave-like structure appears to be tied to the terrain. The criteria for existence of stationary gravity waves indicate that these waves can exist under the observed conditions. The spectrum of terrain variations also supports the existence of these waves. Observed spectra of the vertical velocity have two peaks: one at wavelengths of several kilometers, which is due to waves and the other at wavelengths of about 100 m, which is due to turbulence. The variance at several kilometers wavelength increases somewhat with height at least up to about 800 m, but the variance contributed by turbulence decreases rapidly with height.The National Center for Atmospheric Research is sponsored by the National Science Foundation.     

Quasi-geostrophic stratified flow over isolated finite amplitude topography

The quasi-geostrophic response of a stratified stream incident upon isolated finite amplitude topography on a f-plane is examined in the limit of a Boussinesq, incompressible, inviscid fluid. Compact solutions are derived subject to the following stipulations: uniform upstream velocity and stratification, a circular obstacle and an entirely isentropic/isopycnic lower surface.It is shown that for a semi-infinite flow domain the criterion for Taylor cap formation (i.e., a region of closed streamlines) is . However, for the isentropic lower boundary condition the solutions exist (i.e., have physical validity) only if R₀F⁻¹ < 0.5. (Here R₀ and F refer to the Rossby and Froude numbers defined respectively in terms of the mountain half-width and height.) Also considered are the modifications both to the flow response and to the foregoing existence criterion that are induced by the introduction of an upstream profile comprising two layers of uniform but different stratification. In addition, the relationship of the derived solutions to the results obtained in previous studies is explored, and in particular an outline is given of the impact of adopting the ‘traditional’ simplified lower boundary condition.     

On an instability mechanism in a stably stratified atmospheric layer over a moistened surface

In air stratified by a specific humidity gradient, the vertical motions result in variations in specific humidity (mixing ratio) near the underlying surface. This, in turn, causes a variation of evaporation from the surface, resulting in horizontal thermal inhomogeneities on the surface, which under certain conditions can strengthen the initial vertical motions. The linear problem of the stability of the system under consideration is solved in this paper, boundaries of the unstable region are defined, and specific values of growth rates of disturbances are investigated. The estimates show that even in a density-stratified atmospheric layer over a moist surface, rapid development of disturbances with horizontal scales of several hundred metres is possible. The horizontal sizes of the most rapidly growing modes, as a rule, are an order of magnitude larger than the vertical sizes. The possibility of observing this instability under natural conditions is discussed.