Deep learning subgrid-scale parametrisations for short-term forecasting of sea-ice dynamics with a Maxwell elasto-brittle rheology

IF 4.4 2区 地球科学 Q1 GEOGRAPHY, PHYSICAL
Cryosphere Pub Date : 2023-07-21 DOI:10.5194/tc-17-2965-2023
T. Finn, Charlotte Durand, A. Farchi, M. Bocquet, Yumeng Chen, A. Carrassi, V. Dansereau
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引用次数: 4

Abstract

Abstract. We introduce a proof of concept to parametrise the unresolved subgrid scale of sea-ice dynamics with deep learning techniques. Instead of parametrising single processes, a single neural network is trained to correct all model variables at the same time. This data-driven approach is applied to a regional sea-ice model that accounts exclusively for dynamical processes with a Maxwell elasto-brittle rheology. Driven by an external wind forcing in a 40 km×200 km domain, the model generates examples of sharp transitions between unfractured and fully fractured sea ice. To correct such examples, we propose a convolutional U-Net architecture which extracts features at multiple scales. We test this approach in twin experiments: the neural network learns to correct forecasts from low-resolution simulations towards high-resolution simulations for a lead time of about 10 min. At this lead time, our approach reduces the forecast errors by more than 75 %, averaged over all model variables. As the most important predictors, we identify the dynamics of the model variables. Furthermore, the neural network extracts localised and directional-dependent features, which point towards the shortcomings of the low-resolution simulations. Applied to correct the forecasts every 10 min, the neural network is run together with the sea-ice model. This improves the short-term forecasts up to an hour. These results consequently show that neural networks can correct model errors from the subgrid scale for sea-ice dynamics. We therefore see this study as an important first step towards hybrid modelling to forecast sea-ice dynamics on an hourly to daily timescale.
基于Maxwell弹脆性流变学的海冰动力学短期预测的深度学习子网格尺度参数化
摘要我们引入了一种概念证明,用深度学习技术对海冰动力学的未解决子网格尺度进行参数化。训练单个神经网络来同时校正所有模型变量,而不是对单个过程进行参数化。这种数据驱动的方法被应用于一个区域海冰模型,该模型专门考虑了Maxwell弹脆性流变的动力学过程。在40 km×200 km域,该模型生成了未破裂和完全破裂海冰之间急剧转变的例子。为了纠正这些例子,我们提出了一种卷积U-Net架构,它可以在多个尺度上提取特征。我们在两个实验中测试了这种方法:神经网络学习在大约10分钟的准备时间内从低分辨率模拟向高分辨率模拟校正预测 min.在这个交付周期内,我们的方法将预测误差减少了75以上 %, 对所有模型变量进行平均。作为最重要的预测因素,我们确定了模型变量的动态性。此外,神经网络提取了局部和方向相关的特征,指出了低分辨率模拟的缺点。应用于每10次更正预测 min,神经网络与海冰模型一起运行。这将短期预测提高到一个小时。因此,这些结果表明,神经网络可以从海冰动力学的子网格尺度校正模型误差。因此,我们认为这项研究是朝着混合建模迈出的重要第一步,该建模可以在每小时到每天的时间尺度上预测海冰动力学。
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来源期刊
Cryosphere
Cryosphere GEOGRAPHY, PHYSICAL-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
8.70
自引率
17.30%
发文量
240
审稿时长
4-8 weeks
期刊介绍: The Cryosphere (TC) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of frozen water and ground on Earth and on other planetary bodies. The main subject areas are the following: ice sheets and glaciers; planetary ice bodies; permafrost and seasonally frozen ground; seasonal snow cover; sea ice; river and lake ice; remote sensing, numerical modelling, in situ and laboratory studies of the above and including studies of the interaction of the cryosphere with the rest of the climate system.
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