Extreme and compound ocean events are key drivers of projected low pelagic fish biomass

Le Grix, Natacha; Cheung, William L.; Reygondeau, Gabriel; Zscheischler, Jakob; Frölicher, Thomas L.

doi:10.1111/gcb.16968

Cited by 4 publications

(2 citation statements)

References 90 publications

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“…As the isochemical sensitivity of [H + ] is well known, we can compute the fractional contribution of the temperature changes to the changes in [H + ] (Text S4 in Supporting Information ) (Orr & Epitalon, 2015). We do not have sufficient information stored during the simulation to determine all the processes that drive the changes in DIC and Alk underlying the non‐thermal changes in [H + ] (Burger & Frölicher, 2023), but we use anomalies in the export and sinking of particulate organic carbon (POC) and a logistic regression (Filho et al., 2013; Le Grix et al., 2023; Mahlstein et al., 2012) to infer the potential contribution of changes in the biological pump to the OAX (Text S5 in Supporting Information ).…”

Section: Results and Analysismentioning

confidence: 99%

“…However, this does not mean that the MHW‐induced high [H + ] is irrelevant, as organisms may still be affected. In such scenarios, it is better to rely on species‐specific thresholds as the basis for extreme detection (Le Grix et al., 2023). This limitation on biological impacts also extends to the definition of CCX, where a vertical extent of at least 50 m of each extreme type is required.…”

Section: Discussionmentioning

confidence: 99%

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Column‐Compound Extremes in the Global Ocean

Wong,

Münnich,

Gruber

2024

AGU Advances

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Marine extreme events such as marine heatwaves, ocean acidity extremes and low oxygen extremes can pose a substantial threat to marine organisms and ecosystems. Such extremes might be particularly detrimental (a) when they are compounded in more than one stressor, and (b) when the extremes extend substantially across the water column, restricting the habitable space for marine organisms. Here, we use daily output of a hindcast simulation (1961–2020) from the ocean component of the Community Earth System Model to characterize such column‐compound extreme events (CCX), employing a relative threshold approach to identify extremes and requiring them to extend vertically over at least 50 m. The diagnosed CCX are prevalent, occupying worldwide in the 1960s about 1% of the volume contained within the top 300 m. Over the duration of our simulation, CCX become more intense, last longer, and occupy more volume, driven by the trends in ocean warming and ocean acidification. For example, the triple CCX expanded 39‐fold, now last 3‐times longer, and became 6‐times more intense since the early 1960s. Removing this effect with a moving baseline permits us to better understand the key characteristics of CCX, revealing a typical duration of 10–30 days and a predominant occurrence in the Tropics and high latitudes, regions of high potential biological vulnerability. Overall, the CCX fall into 16 clusters, reflecting different patterns and drivers. Triple CCX are largely confined to the tropics and the North Pacific and tend to be associated with the El Niño‐Southern Oscillation.

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Section: Results and Analysismentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Column‐Compound Extremes in the Global Ocean

Wong,

Münnich,

Gruber

2024

AGU Advances

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Identifying compound weather drivers of forest biomass loss with generative deep learning

Anand,

Bohn,

Camps-Valls

et al. 2024

Environ. Data Science

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Globally, forests are net carbon sinks that partly mitigates anthropogenic climate change. However, there is evidence of increasing weather-induced tree mortality, which needs to be better understood to improve forest management under future climate conditions. Disentangling drivers of tree mortality is challenging because of their interacting behavior over multiple temporal scales. In this study, we take a data-driven approach to the problem. We generate hourly temperate weather data using a stochastic weather generator to simulate 160,000 years of beech, pine, and spruce forest dynamics with a forest gap model. These data are used to train a generative deep learning model (a modified variational autoencoder) to learn representations of three-year-long monthly weather conditions (precipitation, temperature, and solar radiation) in an unsupervised way. We then associate these weather representations with years of high biomass loss in the forests and derive weather prototypes associated with such years. The identified prototype weather conditions are associated with 5–22% higher median biomass loss compared to the median of all samples, depending on the forest type and the prototype. When prototype weather conditions co-occur, these numbers increase to 10–25%. Our research illustrates how generative deep learning can discover compounding weather patterns associated with extreme impacts.

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