Spatiotemporal heterogeneity in the increase in ocean acidity extremes in the northeastern Pacific

Abstract

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The acidification of the ocean (OA) increases the frequency and intensity of ocean acidity extreme events (OAXs), but this increase is not occurring homogeneously in time and space. Here we use daily output from a hindcast simulation with a high-resolution regional ocean model coupled to a biogeochemical ecosystem model (ROMS-BEC) to investigate this heterogeneity in the progression of OAX in the upper 250 m of the northeastern Pacific from 1984 to 2019. OAXs are defined using a relative threshold approach and using a fixed baseline. Concretely, conditions are considered extreme when the hydrogen ion concentration ([H+]) exceeds the 99th percentile of its distribution in the baseline simulation where atmospheric CO2 was held at its 1979 level. Within the 36 years of our hindcast simulation, the increase in atmospheric CO2 causes a strong increase in OAX volume, duration, and intensity throughout the upper 250 m. The increases are most accentuated near the surface, with 88 % of the surface area experiencing near-permanent extreme conditions in 2019. At the same time, a larger fraction of the OAXs become undersaturated with respect to aragonite (ΩA < 1), with some regions experiencing increases up to nearly 50 % in their subsurface. There is substantial regional heterogeneity in the progression of OAX, with the fraction of OAX volume across the top 250 m increasing in the central northeastern Pacific up to 160 times, while the deeper layers of the nearshore regions experience “only” a 4-fold increase. Throughout the upper 50 m of the northeastern Pacific, OAXs increase relatively linearly with time, but sudden rapid increases in yearly extreme days are simulated to occur in the thermocline of the far offshore regions of the central northeastern Pacific. These differences largely emerge from the spatial heterogeneity in the local [H+] variability. The limited offshore reach of offshore-propagating mesoscale eddies, which are an important driver of subsurface OAX in the northeastern Pacific, causes a sharp transition in the increase in OAX between the rather variable thermocline waters of nearshore regions and the very invariant waters of the central northeastern Pacific. The spatially and temporal heterogeneous increases in OAX, including the abrupt appearance of near-permanent extremes, likely have negative effects on the ability of marine organisms to adapt to the progression of OA and its associated extremes.