用计算机模拟太平洋[视频]

Media+Environment Pub Date : 2021-05-19 DOI:10.1525/001C.22191

E. Meiburg

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引用次数: 0

摘要

在流体动力学中，模拟海洋表面上和表面下的运动，如表面和内部(水下)波，或沿着海底的运动。在我们能够在计算机上模拟海洋之前，必须用数学方法将其划分为单独的“控制体积”，我们对其施加经典的物理守恒原理，如质量、动量、能量或盐度。有时，数十亿个这样的离散盒子被耦合到一个模型中。计算机模型与卫星或实地研究数据以及一些实验室实验一起帮助我们了解水下雪崩等大规模事件如何损害电信电缆或管道等水下基础设施，海底下天然气和石油储层是如何形成的，或者热量、盐和CO~2~的海洋运输如何影响全球气候、海洋温度和酸化。可扩展性对于这种类型的建模很重要，因为海洋流动的计算研究通常从小系统开始，然后扩大到更大规模的现象。视频可在:https://vimeo.com/527398493

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Modeling the Pacific Ocean on the Computer [Video]

In fluid dynamics, motions on and below the ocean surface, such as surface and internal (underwater) waves, or along the ocean floor are modeled. Before we can simulate the ocean on a computer, it has to be mathematically divided into separate "control volumes" for which we impose the classic physical conservation principles for mass, momentum, energy, or salinity. Sometimes, billions of these discrete boxes are coupled in a single model. Computer models alongside satellite or field study data, as well as some laboratory experiments help us understand how large-scale events such as underwater avalanches can impair underwater infrastructure such as telecommunication cables or pipelines, how gas and oil reservoirs form below the ocean floor, or how ocean transport of heat, salt, and CO~2~ affects global climate, ocean temperature, and acidification. Scalability is important for this type of modeling, since computational investigations of ocean flows often start with small systems that are then upscaled into much larger-scale phenomena. Video available at: https://vimeo.com/527398493

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Media+Environment

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