Characterizing the Variability of Boundary Currents and Ocean Heat Content Around New Zealand Using a Multi-Decadal High-Resolution Regional Ocean Model

New Zealand is located in the southwest Pacific Ocean and is surrounded by a complex system of boundary currents that vary on a variety of time scales, with important impacts on weather, primary productivity, and fisheries. While various observational and modeling studies have shed light on many of the characteristics of New Zealand's ocean circulation, this study provides a comprehensive, quantitative, seamless, 3-dimensional characterization of the region's boundary current circulation and ocean heat content. We use a 28 yr long hydrodynamic model simulation that accurately represents the mean and variability of the ocean circulation to characterize and quantify the temporal and spatial variability across the region. We show that low-frequency variability in boundary current transport and upper ocean heat content are correlated over the entire New Zealand oceanic region. Oceanic eddies dominate heat content variability at intra-annual scales in the northeast of the region, while on the west and southeast coasts heat content varies predominantly at interannual scales controlled by large-scale changes in the subtropical and sub-Antarctic fronts. The model shows a significant downstream strengthening and deepening of the boundary currents off northeast New Zealand which, if confirmed by observations, could suggest a significant new understanding of this Western Boundary Current system. This study presents a region-wide characterization of the temporal and spatial variability of ocean currents and heat content, and their interconnections, providing a vital basis for understanding climate change impacts and the increasing occurrence of marine heatwaves.

Automated summary

This study provides a comprehensive and quantitative characterization of New Zealand's ocean circulation and heat content, demonstrating the correlations between boundary current transport and ocean heat content variability. The findings have important implications for understanding climate change impacts and the increasing occurrence of marine heatwaves.