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Advancing global ecological modeling capabilities to simulate future trajectories of change in marine ecosystems

Citation

Coll, M and Steenbeek, J and Pennino, MG and Buszowski, J and Kaschner, K and Lotze, HK and Rousseau, Y and Tittensor, DP and Walters, C and Watson, RA and Christensen, V, Advancing global ecological modeling capabilities to simulate future trajectories of change in marine ecosystems, Frontiers in Marine Science, 7, (OCT) Article 567877. ISSN 2296-7745 (2020) [Refereed Article]

Copyright Statement

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DOI: doi:10.3389/fmars.2020.567877

Abstract

Considerable effort is being deployed to predict the impacts of climate change and anthropogenic activities on the ocean's biophysical environment, biodiversity, and natural resources to better understand how marine ecosystems and provided services to humans are likely to change and explore alternative pathways and options. We present an updated version of EcoOcean (v2), a spatial-temporal ecosystem modeling complex of the global ocean that spans food-web dynamics from primary producers to top predators. Advancements include an enhanced ability to reproduce spatial-temporal ecosystem dynamics by linking species productivity, distributions, and trophic interactions to the impacts of climate change and worldwide fisheries. The updated modeling platform is used to simulate past and future scenarios of change, where we quantify the impacts of alternative configurations of the ecological model, responses to climate-change scenarios, and the additional impacts of fishing. Climate-change scenarios are obtained from two Earth-System Models (ESMs, GFDL-ESM2M, and IPSL-CMA5-LR) and two contrasting emission pathways (RCPs 2.6 and 8.5) for historical (19502005) and future (20062100) periods. Standardized ecological indicators and biomasses of selected species groups are used to compare simulations. Results show how future ecological trajectories are sensitive to alternative configurations of EcoOcean, and yield moderate differences when looking at ecological indicators and larger differences for biomasses of species groups. Ecological trajectories are also sensitive to environmental drivers from alternative ESM outputs and RCPs, and show spatial variability and more severe changes when IPSL and RCP 8.5 are used. Under a non-fishing configuration, larger organisms show decreasing trends, while smaller organisms show mixed or increasing results. Fishing intensifies the negative effects predicted by climate change, again stronger under IPSL and RCP 8.5, which results in stronger biomass declines for species already losing under climate change, or dampened positive impacts for those increasing. Several species groups that win under climate change become losers under combined impacts, while only a few (small benthopelagic fish and cephalopods) species are projected to show positive biomass changes under cumulative impacts. EcoOcean v2 can contribute to the quantification of cumulative impact assessments of multiple stressors and of plausible ocean-based solutions to prevent, mitigate and adapt to global change.

Item Details

Item Type:Refereed Article
Keywords:ecosystem modelling, global, simulation, fisheries, marine ecosystems, climate change, fishing, future trajectories, projections, foodweb spatial-temporal model, model uncertainty
Research Division:Agricultural, Veterinary and Food Sciences
Research Group:Fisheries sciences
Research Field:Fisheries sciences not elsewhere classified
Objective Division:Animal Production and Animal Primary Products
Objective Group:Environmentally sustainable animal production
Objective Field:Environmentally sustainable animal production not elsewhere classified
UTAS Author:Rousseau, Y (Mr Yannick Rousseau)
UTAS Author:Watson, RA (Professor Reginald Watson)
ID Code:141924
Year Published:2020
Web of Science® Times Cited:1
Deposited By:Fisheries and Aquaculture
Deposited On:2020-12-03
Last Modified:2021-02-22
Downloads:0

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