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Showing 1–5 of 5 results
Advanced filters: Author: Laure Resplandy Clear advanced filters

  • Computer simulations show that areas of the ocean that have low levels of dissolved oxygen will expand, but then shrink, in response to global warming — adding to an emerging picture of the finely balanced processes involved.

    • Laure Resplandy
    News & Views
    Nature
    Volume: 557, P: 314-315

  • An assessment of the land-to-ocean cycling of carbon through inland waters, estuaries, tidal wetlands and continental shelf waters provides a perspective on the global carbon cycle and identifies key knowledge gaps.

    • Pierre Regnier
    • Laure Resplandy
    • Philippe Ciais
    Reviews
    Nature
    Volume: 603, P: 401-410

  • To facilitate more accurate long-term projections of primary production and export over oceanic low latitudes (LLs), we identified the first-order importance of the temperature dependence of remineralization of the LL nutrient reservoir, with this serving to enhance LL mesopelagic retention under warming.

    • Keith B. Rodgers
    • Olivier Aumont
    • Ryohei Yamaguchi
    Research
    Nature
    Volume: 632, P: 802-807

  • The ocean stores about 30% of the carbon emitted by human activities, regulating atmospheric CO2 levels and the Earth’s climate. Research suggests that this uptake of CO2 has strengthened much faster in coastal ocean waters than in the open ocean due to enhanced biological activity.

    • Laure Resplandy
    News & Views
    Nature Climate Change
    Volume: 14, P: 312-313

  • Oxygen loss has been observed in the world’s oceans, due mainly to warming temperatures that reduce oxygen solubility and increase stratification. This study shows climate-induced salinity changes also impact oxygen patterns with effects either accelerating or counteracting warming-driven changes.

    • Allison Hogikyan
    • Laure Resplandy
    • Gabriel Vecchi
    Research
    Nature Climate Change
    Volume: 14, P: 82-90