Your search keyword '"du Pontavice, Hubert"' showing total 2 results

1. Trophic amplification: A model intercomparison of climate driven changes in marine food webs.

Author

Guibourd de Luzinais, Vianney, du Pontavice, Hubert, Reygondeau, Gabriel, Barrier, Nicolas, Blanchard, Julia L., Bornarel, Virginie, Büchner, Matthias, Cheung, William W. L., Eddy, Tyler D., Everett, Jason D., Guiet, Jerome, Harrison, Cheryl S., Maury, Olivier, Novaglio, Camilla, Petrik, Colleen M., Steenbeek, Jeroen, Tittensor, Derek P., and Gascuel, Didier

Subjects

*FOOD chains, *CLIMATE change, *GREENHOUSE gases, *TOP predators, *FISHERIES, *MARINE biomass

Abstract

Marine animal biomass is expected to decrease in the 21st century due to climate driven changes in ocean environmental conditions. Previous studies suggest that the magnitude of the decline in primary production on apex predators could be amplified through the trophodynamics of marine food webs, leading to larger decreases in the biomass of predators relative to the decrease in primary production, a mechanism called trophic amplification. We compared relative changes in producer and consumer biomass or production in the global ocean to assess the extent of trophic amplification. We used simulations from nine marine ecosystem models (MEMs) from the Fisheries and Marine Ecosystem Models Intercomparison Project forced by two Earth System Models under the high greenhouse gas emissions Shared Socioeconomic Pathways (SSP5-8.5) and a scenario of no fishing. Globally, total consumer biomass is projected to decrease by 16.7 ± 9.5% more than net primary production (NPP) by 2090–2099 relative to 1995–2014, with substantial variations among MEMs and regions. Total consumer biomass is projected to decrease almost everywhere in the ocean (80% of the world's oceans) in the model ensemble. In 40% of the world's oceans, consumer biomass was projected to decrease more than NPP. Additionally, in another 36% of the world's oceans consumer biomass is expected to decrease even as projected NPP increases. By analysing the biomass response within food webs in available MEMs, we found that model parameters and structures contributed to more complex responses than a consistent amplification of climate impacts of higher trophic levels. Our study provides additional insights into the ecological mechanisms that will impact marine ecosystems, thereby informing model and scenario development. [ABSTRACT FROM AUTHOR]

Published

2023

2. Global change in the trophic functioning of marine food webs.

Author

Maureaud, Aurore, Gascuel, Didier, Colléter, Mathieu, Palomares, Maria L. D., Du Pontavice, Hubert, Pauly, Daniel, and Cheung, William W. L.

Subjects

FOOD chains, MARINE ecology, GLOBAL warming, MARINE biomass, MARINE species diversity

Abstract

The development of fisheries in the oceans, and other human drivers such as climate warming, have led to changes in species abundance, assemblages, trophic interactions, and ultimately in the functioning of marine food webs. Here, using a trophodynamic approach and global databases of catches and life history traits of marine species, we tested the hypothesis that anthropogenic ecological impacts may have led to changes in the global parameters defining the transfers of biomass within the food web. First, we developed two indicators to assess such changes: the Time Cumulated Indicator (TCI) measuring the residence time of biomass within the food web, and the Efficiency Cumulated Indicator (ECI) quantifying the fraction of secondary production reaching the top of the trophic chain. Then, we assessed, at the large marine ecosystem scale, the worldwide change of these two indicators over the 1950–2010 time-periods. Global trends were identified and cluster analyses were used to characterize the variability of trends between ecosystems. Results showed that the most common pattern over the study period is a global decrease in TCI, while the ECI indicator tends to increase. Thus, changes in species assemblages would induce faster and apparently more efficient biomass transfers in marine food webs. Results also suggested that the main driver of change over that period had been the large increase in fishing pressure. The largest changes occurred in ecosystems where ‘fishing down the marine food web’ are most intensive. [ABSTRACT FROM AUTHOR]

Published

2017