Abstract
Global ocean heat content (OHC) is generally estimated using gridded, model and reanalysis data; its change is crucial to understanding climate anomalies and ocean warming phenomena. However, Argo gridded data have short temporal coverage (from 2005 to the present), inhibiting understanding of long-term OHC variabilities at decadal to multidecadal scales. In this study, we utilized multisource remote sensing and Argo gridded data based on the long short-term memory (LSTM) neural network method, which considers long temporal dependence to reconstruct a new long time-series OHC dataset (1993–2020) and fill the pre-Argo data gaps. Moreover, we adopted a new machine learning method, i.e., the Light Gradient Boosting Machine (LightGBM), and applied the well-known Random Forests (RFs) method for comparison. The model performance was measured using determination coefficients (R2) and root-mean-square error (RMSE). The results showed that LSTM can effectively improve the OHC prediction accuracy compared with the LightGBM and RFs methods, especially in long-term and deep-sea predictions. The LSTM-estimated result also outperformed the Ocean Projection and Extension neural Network (OPEN) dataset, with an R2 of 0.9590 and an RMSE of 4.45 × 1019 in general in the upper 2000 m for 28 years (1993–2020). The new reconstructed dataset (named OPEN-LSTM) correlated reasonably well with other validated products, showing consistency with similar time-series trends and spatial patterns. The spatiotemporal error distribution between the OPEN-LSTM and IAP datasets was smaller on the global scale, especially in the Atlantic, Southern and Pacific Oceans. The relative error for OPEN-LSTM was the smallest for all ocean basins compared with Argo gridded data. The average global warming trends are 3.26 × 108 J/m2/decade for the pre-Argo (1993–2004) period and 2.67 × 108 J/m2/decade for the time-series (1993–2020) period. This study demonstrates the advantages of LSTM in the time-series reconstruction of OHC, and provides a new dataset for a deeper understanding of ocean and climate events.
Highlights
Atmospheric greenhouse gases (GHGs) have caused imbalances in the top layers of the atmosphere, giving rise to the Earth’s energy imbalance (EEI) which is driving the current warming trend [1,2,3]
We found that the accuracy of the two models decreased when complex ocean–atmosphere interactions were considered, which would interfere with the model training
This study aimed to establish a robust and efficient model to improve the inversion accuracy of ocean heat content (OHC) based on the Ocean Projection and Extension neural Network (OPEN) dataset
Summary
Atmospheric greenhouse gases (GHGs) have caused imbalances in the top layers of the atmosphere, giving rise to the Earth’s energy imbalance (EEI) which is driving the current warming trend [1,2,3]. Increasing global warming has led to the destabilization of the climate system and caused more frequent and severe extreme climate events. The strong El Niños during 2014–2016, 2017, 2018, and 2019 reached the highest warmth in the upper ocean in modern recorded history [5,6,7], and upper ocean temperatures hit a record high in 2020 [8]. Behind these anomalous incidents, the ocean plays an essential role in regulating the global climate system and redistributing regional and global-scale energy.
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