A Feasibility Study of Three-Dimensional Empirical Orthogonal Functions From the NASA JPL Ocean General Circulation Model: Computing, Visualization and Interpretation
Danielle Lafarga, T. Bui, Y. Song, Thomas M. Smith, S. Shen
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引用次数: 0
Abstract
Existing oceanic studies on either data reconstruction or dynamics often used 2-dimensional empirical orthogonal functions (EOF) for sea surface temperature (SST) and for deep layers. However, large-scale oceanic dynamics, such as equatorial ocean upwelling and arctic ocean ventilation, imply the existence of strong covariance among the temperatures and other parameters between different layers. These ocean dynamics are not best represented in the isolated 2-dimensional layer-by-layer calculations, while the 3-dimensional EOFs have a clear advantage. The purpose of this paper is to demonstrate 3D EOF calculations based on the NASA Jet Propulsion Laboratory (JPL) ocean general circulation model (OGCM) from surface to 5,500 meters depth, with 33 depth layers, 1-degree latitude and longitude spatial resolution, and monthly temporal resolution. We also present visualizations of the 3D EOFs and make physical interpretations of the first two EOFs. Our 3D EOF results demonstrate that (i) the 3D spatial pattern of equatorial ocean upwelling is mainly reflected in the first EOF mode and has its most variabilities within the depth layer between 100 and 400 meters, (ii) the 3D El Niño Southern Oscillation (ENSO) dynamic pattern is mainly reflected in the second EOF mode and is mostly confined from surface to the depth of 150 meters, and (iii) the lead eigenvalue from the 3D EOF calculation appears to contain some signal of oceanic warming. Additionally, our method of weighted 3D EOF computation and our 3D visualization Python code may be useful tools for both climate professionals and students.
现有的海洋数据重建或动力学研究通常使用二维经验正交函数(EOF)来计算海表温度和深海温度。而赤道洋上升流和北冰洋通气等大尺度海洋动力则暗示了不同层间温度等参数之间存在较强的协方差。这些海洋动力学在孤立的二维逐层计算中并不能最好地表示,而三维EOFs具有明显的优势。本文的目的是演示基于NASA喷气推进实验室(JPL)海洋环流模型(OGCM)的三维EOF计算,从地表到5500米深度,具有33层深度,1度经纬度空间分辨率和月时间分辨率。我们还展示了3D EOFs的可视化,并对前两个EOFs进行了物理解释。我们的3 d EOF结果证明(i)赤道太平洋上升流的3 d空间模式主要体现在第一个EOF模式和在深度层最可变性100至400米,(ii) 3 d厄尔尼诺南方涛动(ENSO)动态模式主要是反映在第二个EOF模式和主要局限于表面的深度150米,和(3)计算特征值从3 d EOF似乎包含了一些海洋变暖的信号。此外,我们的加权3D EOF计算方法和我们的3D可视化Python代码可能是气候专业人员和学生的有用工具。
期刊介绍:
Tellus A: Dynamic Meteorology and Oceanography along with its sister journal Tellus B: Chemical and Physical Meteorology, are the international, peer-reviewed journals of the International Meteorological Institute in Stockholm, an independent non-for-profit body integrated into the Department of Meteorology at the Faculty of Sciences of Stockholm University, Sweden. Aiming to promote the exchange of knowledge about meteorology from across a range of scientific sub-disciplines, the two journals serve an international community of researchers, policy makers, managers, media and the general public.
Original research papers comprise the mainstay of Tellus A. Review articles, brief research notes, and letters to the editor are also welcome. Special issues and conference proceedings are published from time to time.
The scope of Tellus A spans dynamic meteorology, physical oceanography, data assimilation techniques, numerical weather prediction, climate dynamics and climate modelling.
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