Optimized Vertical Layers for the Hybrid Terrain-Following Coordinate Minimizing Numerical Errors in a 2D Rising Bubble Experiment near Steep Terrain

IF 2.8 3区 地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES
Hao Yang, Yiyuan Li, Bin Wang
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Abstract

The basic terrain-following (BTF) coordinate simplifies the lower boundary conditions of a numerical model but leads to numerical error and instability on steep terrain. Hybrid terrain-following (HTF) coordinates with smooth slopes of vertical layers (slopeVL) generally overcome this difficulty. Therefore, the HTF coordinate becomes very desirable for atmospheric and oceanic numerical models. However, improper vertical layering in HTF coordinates may also increase the incidence of error. Except for the slopeVL of an HTF coordinate, this study further optimizes the HTF coordinate focusing on the thickness of vertical layers (thickVL). Four HTF coordinates (HTF1–HTF4) with similar slopeVL but different vertical transition methods of thickVL are designed, and the relationship between thickVL and numerical errors in each coordinate is compared in the classic idealized thermal convection [two-dimensional (2D) rising bubble] experiment over steep terrain. The errors of potential temperature θ and vertical velocity w are reduced most, by approximately 70% and 40%, respectively, in the HTF1 coordinate, with a monotonic increase in thickVL according to the increasing height; however, the errors of θ increased in all the other HTF coordinates, with nonmonotonic thickVLs. Furthermore, analyses of the errors of vertical pressure gradient force (VPGF) show that due to the interpolation errors of thickVL, the inflection points in the vertical transition of thickVL induce the initial VPGF errors; therefore, the HTF1 coordinate with a monotonic increase in thickVL has the smallest errors among all the coordinates. More importantly, the temporal evolution of VPGF errors manifests top-type VPGF errors that propagate upward gradually during the time integration. Only the HTF1 and HTF4 coordinates with a monotonic increase in thickVL near the top of the terrain can suppress this propagation. This optimized HTF coordinate (i.e., HTF1) can be a reference for designing a vertical thickVL in a numerical model.

在陡峭地形附近的二维上升气泡实验中优化混合地形跟随坐标的垂直层,使数值误差最小化
基本地形随动(BTF)坐标简化了数值模型的下边界条件,但在陡峭地形上会导致数值误差和不稳定性。具有平滑垂直层坡度(slopeVL)的混合地形随动(HTF)坐标通常可以克服这一困难。因此,混合地形随动坐标在大气和海洋数值模式中变得非常理想。然而,HTF 坐标中不适当的垂直分层也会增加误差的发生率。除了 HTF 坐标的斜率 VL 外,本研究还进一步优化了 HTF 坐标,重点是垂直层厚度(thickVL)。在陡峭地形上的经典理想化热对流[二维(2D)上升气泡]实验中,设计了四个具有相似斜率 VL 但厚度 VL 垂直过渡方式不同的 HTF 坐标(HTF1-HTF4),并比较了每个坐标的厚度 VL 与数值误差之间的关系。在 HTF1 坐标上,势温 θ 和垂直速度 w 的误差减少最多,分别减少了约 70% 和 40%,且随着高度的增加,厚 VL 呈单调增加;然而,在 HTF 其他坐标上,θ 的误差都增加了,且厚 VL 呈非单调增加。此外,对垂直压力梯度力(VPGF)误差的分析表明,由于厚VL的插值误差,厚VL垂直过渡的拐点会引起初始VPGF误差;因此,在所有坐标中,厚VL单调增加的HTF1坐标的误差最小。更重要的是,VPGF 误差的时间演化表现为在时间积分过程中逐渐向上传播的顶部型 VPGF 误差。只有 HTF1 和 HTF4 坐标在地形顶部附近的 thickVL 单调增加,才能抑制这种传播。这种优化的 HTF 坐标(即 HTF1)可作为数值模型中设计垂直厚 VL 的参考。
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来源期刊
Journal of Meteorological Research
Journal of Meteorological Research METEOROLOGY & ATMOSPHERIC SCIENCES-
CiteScore
6.20
自引率
6.20%
发文量
54
期刊介绍: Journal of Meteorological Research (previously known as Acta Meteorologica Sinica) publishes the latest achievements and developments in the field of atmospheric sciences. Coverage is broad, including topics such as pure and applied meteorology; climatology and climate change; marine meteorology; atmospheric physics and chemistry; cloud physics and weather modification; numerical weather prediction; data assimilation; atmospheric sounding and remote sensing; atmospheric environment and air pollution; radar and satellite meteorology; agricultural and forest meteorology and more.
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