Investigation of Hydrostatic Imbalance with Field Observations

IF 2.6 3区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES
Jielun Sun, Volker Wulfmeyer, Florian Späth, Holger Vömel, William Brown, Steve Oncley
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引用次数: 0

Abstract

The hydrostatic equilibrium addresses the approximate balance between the positive force of the vertical pressure gradient and the negative gravity force and has been widely assumed for atmospheric applications. The hydrostatic imbalance of the mean atmospheric state for the acceleration of vertical motions in the vertical momentum balance is investigated using tower, the global positioning system radiosonde, and Doppler lidar and radar observations throughout the diurnally varying atmospheric boundary layer (ABL) under clear-sky conditions. Because of the negligibly small mean vertical velocity, the acceleration of vertical motions is dominated by vertical variations of vertical turbulent velocity variances. The imbalance is found to be mainly due to the vertical turbulent transport of changing air density as a result of thermal expansion/contraction in response to air temperature changes following surface temperature changes. In contrast, any pressure change associated with air temperature changes is small, and the positive vertical pressure-gradient force is strongly influenced by its background value. The vertical variation of the turbulent velocity variance from its vertical increase in the lower convective boundary layer (CBL) to its vertical decrease in the upper CBL is observed to be associated with the sign change of the imbalance from positive to negative due to the vertical decrease of the positive vertical pressure-gradient force and the relative increase of the negative gravity force as a result of the decreasing upward transport of the low-density air. The imbalance is reduced significantly at night but does not steadily approach zero. Understanding the development of hydrostatic imbalance has important implications for understanding large-scale atmosphere, especially for cloud development. It is well known that the hydrostatic imbalance between the positive pressure-gradient force due to the vertical decrease of atmospheric pressure and the negative gravity forces in the vertical momentum balance equation has important impacts on the vertical acceleration of atmospheric vertical motions. Vertical motions for mass, momentum, and energy transfers contribute significantly to changing atmospheric dynamics and thermodynamics. This study investigates the often-assumed hydrostatic equilibrium and investigate how the hydrostatic imbalance is developed using field observations in the atmospheric boundary layer under clear-sky conditions. The results reveal that hydrostatic imbalance can develop from the large-eddy turbulent transfer of changing air density in response to the surface diabatic heating/cooling. The overwhelming turbulence in response to large-scale thermal forcing and mechanical work of the vast Earth surface contributes to the hydrostatic imbalance on large spatial and temporal scales in numerical weather forecast and climate models.
通过实地观测调查静水失衡问题
流体静力学平衡是指垂直压力梯度的正向力和负向重力之间的近似平衡,在大气应用中被广泛假定。在晴空条件下,利用塔、全球定位系统无线电探空仪、多普勒激光雷达和雷达对整个昼夜变化的大气边界层(ABL)进行观测,研究了垂直动量平衡中垂直运动加速度的平均大气状态的流体静力学不平衡。由于平均垂直速度非常小,可以忽略不计,因此垂直运动的加速度主要受垂直湍流速度方差的垂直变化影响。研究发现,这种不平衡主要是由于在地表温度变化后,空气密度因热膨胀/收缩而发生变化的垂直湍流输送造成的。相反,与气温变化相关的任何压力变化都很小,正的垂直压力梯度力受其背景值的影响很大。湍流速度方差从对流边界层下部的垂直上升到对流边界层上部的垂直下降的垂直变化,与正垂直压力梯度力的垂直下降和低密度空气向上输送减少导致的负重力的相对增加造成的不平衡从正向到负向的符号变化有关。不平衡在夜间会明显减小,但不会稳定趋近于零。了解流体静力学失衡的发展对了解大尺度大气,尤其是云的发展具有重要意义。 众所周知,在垂直动量平衡方程中,由于大气压力垂直下降而产生的正压力梯度力与负重力之间的静压不平衡对大气垂直运动的垂直加速度有重要影响。质量、动量和能量传递的垂直运动对大气动力学和热力学的变化有重要影响。本研究利用晴空条件下对大气边界层的实地观测,对通常假定的流体静力学平衡进行了研究,并探讨了流体静力学失衡是如何形成的。研究结果表明,静水失衡可能是由空气密度变化的大涡度湍流传输对表面二重加热/冷却的响应而形成的。在数值天气预报和气候模型中,响应大尺度热强迫和广阔地球表面机械功的压倒性湍流导致了大时空尺度的静水失衡。
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来源期刊
Journal of Applied Meteorology and Climatology
Journal of Applied Meteorology and Climatology 地学-气象与大气科学
CiteScore
5.10
自引率
6.70%
发文量
97
审稿时长
3 months
期刊介绍: The Journal of Applied Meteorology and Climatology (JAMC) (ISSN: 1558-8424; eISSN: 1558-8432) publishes applied research on meteorology and climatology. Examples of meteorological research include topics such as weather modification, satellite meteorology, radar meteorology, boundary layer processes, physical meteorology, air pollution meteorology (including dispersion and chemical processes), agricultural and forest meteorology, mountain meteorology, and applied meteorological numerical models. Examples of climatological research include the use of climate information in impact assessments, dynamical and statistical downscaling, seasonal climate forecast applications and verification, climate risk and vulnerability, development of climate monitoring tools, and urban and local climates.
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