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1. High predictability of terrestrial carbon fluxes from an initialized decadal prediction system

   https://doi.org/10.1088/1748-9326/ab5c55  

   Lovenduski, Nicole S.; Bonan, Gordon B.; Yeager, Stephen G.; Lindsay, Keith; Lombardozzi, Danica L. (December 2019, Environmental Research Letters)

   Abstract Interannual variations in the flux of carbon dioxide (CO₂) between the land surface and the atmosphere are the dominant component of interannual variations in the atmospheric CO₂growth rate. Here, we investigate the potential to predict variations in these terrestrial carbon fluxes 1–10 years in advance using a novel set of retrospective decadal forecasts of an Earth system model. We demonstrate that globally-integrated net ecosystem production (NEP) exhibits high potential predictability for 2 years following forecast initialization. This predictability exceeds that from a persistence or uninitialized forecast conducted with the same Earth system model. The potential predictability in NEP derives mainly from high predictability in ecosystem respiration, which itself is driven by vegetation carbon and soil moisture initialization. Our findings unlock the potential to forecast the terrestrial ecosystem in a changing environment. 

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2. Predicting near-term variability in ocean carbon uptake

   https://doi.org/10.5194/esd-10-45-2019  

   Lovenduski, Nicole S.; Yeager, Stephen G.; Lindsay, Keith; Long, Matthew C. (January 2019, Earth System Dynamics)

   Abstract. Interannual variations in air–sea fluxes of carbon dioxide (CO₂) impactthe global carbon cycle and climate system, and previous studies suggest thatthese variations may be predictable in the near term (from a year to a decadein advance). Here, we quantify and understand the sources of near-termpredictability and predictive skill in air–sea CO₂ flux on global andregional scales by analyzing output from a novel set of retrospective decadalforecasts of an Earth system model. These forecasts exhibit the potential topredict year-to-year variations in the globally integrated air–sea CO₂flux several years in advance, as indicated by the high correlation of theforecasts with a model reconstruction of past CO₂ flux evolution. Thispotential predictability exceeds that obtained solely from foreknowledge ofvariations in external forcing or a simple persistence forecast, with thelongest-lasting forecast enhancement in the subantarctic Southern Ocean andthe northern North Atlantic. Potential predictability in CO₂ fluxvariations is largely driven by predictability in the surface ocean partialpressure of CO₂, which itself is a function of predictability in surfaceocean dissolved inorganic carbon and alkalinity. The potentialpredictability, however, is not realized as predictive skill, as indicated bythe moderate to low correlation of the forecasts with anobservationally based CO₂ flux product. Nevertheless, our results suggestthat year-to-year variations in ocean carbon uptake have the potential to bepredicted well in advance and establish a precedent for forecasting air–seaCO₂ flux in the near future. 

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3. Skillful Multi‐Month Predictions of Ecosystem Stressors in the Surface and Subsurface Ocean

   https://doi.org/10.1029/2023EF003605  

   Mogen, Samuel_C; Lovenduski, Nicole_S; Yeager, Stephen; Keppler, Lydia; Sharp, Jonathan; Bograd, Steven_J; Quiros, Nathali_Cordero; Di_Lorenzo, Emanuele; Hazen, Elliott_L; Jacox, Michael_G; et al (November 2023, Earth's Future)

   Abstract Anthropogenic carbon emissions and associated climate change are driving rapid warming, acidification, and deoxygenation in the ocean, which increasingly stress marine ecosystems. On top of long‐term trends, short term variability of marine stressors can have major implications for marine ecosystems and their management. As such, there is a growing need for predictions of marine ecosystem stressors on monthly, seasonal, and multi‐month timescales. Previous studies have demonstrated the ability to make reliable predictions of the surface ocean physical and biogeochemical state months to years in advance, but few studies have investigated forecast skill of multiple stressors simultaneously or assessed the forecast skill below the surface. Here, we use the Community Earth System Model (CESM) Seasonal to Multiyear Large Ensemble (SMYLE) along with novel observation‐based biogeochemical and physical products to quantify the predictive skill of dissolved inorganic carbon (DIC), dissolved oxygen, and temperature in the surface and subsurface ocean. CESM SMYLE demonstrates high physical and biogeochemical predictive skill multiple months in advance in key oceanic regions and frequently outperforms persistence forecasts. We find up to 10 months of skillful forecasts, with particularly high skill in the Northeast Pacific (Gulf of Alaska and California Current Large Marine Ecosystems) for temperature, surface DIC, and subsurface oxygen. Our findings suggest that dynamical marine ecosystem prediction could support actionable advice for decision making. 

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4. Quantifying the Potential Predictability of Arctic Marine Primary Production

   https://doi.org/10.1029/2024JC021668  

   Payne, Courtney_M; Lovenduski, Nicole_S; Holland, Marika_M; Krumhardt, Kristen_M; DuVivier, Alice_K (March 2025, Journal of Geophysical Research: Oceans)

   Abstract Phytoplankton in the Arctic Ocean and sub‐Arctic seas support a rich marine food web that sustains Indigenous communities as well as some of the world's largest fisheries. As sea ice retreat leads to further expansion of these fisheries, there is growing need for predictions of phytoplankton net primary production (NPP), which will likely allow better management of food resources in the region. Here, we use perfect model simulations of the Community Earth System Model version 2 (CESM2) to quantify short‐term (month to 2 years) predictability of Arctic Ocean NPP. Our results indicate that NPP is potentially predictable during the most productive summer months for at least 2 years, largely due to the highly predictable Arctic shelves where fisheries in the Arctic are projected to expand. Sea surface temperatures, which are an important limitation on phytoplankton growth and also are predictable for multiple years, are the most important physical driver of this predictability. Finally, we find that the predictability of NPP in the 2030s is enhanced relative to the 2010s, indicating that the utility of these predictions may increase in the near future. This work indicates that operational forecasts using Earth system models may provide moderately skillful predictions of NPP in the Arctic, possibly aiding in the management of Arctic marine resources. 

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5. Skillful multiyear predictions of ocean acidification in the California Current System

   https://doi.org/10.1038/s41467-020-15722-x  

   Brady, Riley X.; Lovenduski, Nicole S.; Yeager, Stephen G.; Long, Matthew C.; Lindsay, Keith (December 2020, Nature Communications)

   null (Ed.)

   Abstract The California Current System (CCS) sustains economically valuable fisheries and is particularly vulnerable to ocean acidification, due to its natural upwelling of carbon-enriched waters that generate corrosive conditions for local ecosystems. Here we use a novel suite of retrospective, initialized ensemble forecasts with an Earth system model (ESM) to predict the evolution of surface pH anomalies in the CCS. We show that the forecast system skillfully predicts observed surface pH variations a year in advance over a naive forecasting method, with the potential for skillful prediction up to five years in advance. Skillful predictions of surface pH are mainly derived from the initialization of dissolved inorganic carbon anomalies that are subsequently transported into the CCS. Our results demonstrate the potential for ESMs to provide skillful predictions of ocean acidification on large scales in the CCS. Initialized ESMs could also provide boundary conditions to improve high-resolution regional forecasting systems. 

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