Your search keyword '"Godley, B. J."' showing total 3 results

1. Microplastics in the Arctic: a transect through the Barents Sea

Author

Emberson-Marl, H., primary, Coppock, R. L., additional, Cole, M., additional, Godley, B. J., additional, Mimpriss, N., additional, Nelms, S. E., additional, and Lindeque, P. K., additional

Published

2023

2. Green Turtles Highlight Connectivity Across a Regional Marine Protected Area Network in West Africa

Author

Patrício, A. R., Beal, M., Barbosa, C., Diouck, D., Godley, B. J., Miguel Madeira, Fernando, Regalla, A., Traoré, M. S., Senhoury, C., Sidina, E., Catry, P., and Repositório da Universidade de Lisboa

Subjects

Connectivity, MPA, Satellite tracking, Global and Planetary Change, Chelonia mydas, GPS, West Africa, Protected area network, Ocean Engineering, Sea turtle, Aquatic Science, Oceanography, Water Science and Technology

Abstract

Networks of marine protected areas (MPAs) are invaluable for the protection of species with high dispersal capacity, yet connectivity within networks is poorly understood. We demonstrate the connectivity within the regional MPA network in West Africa (RAMPAO), mediated by the largest green turtle population in the eastern Atlantic Ocean. We equipped with satellite tags 45 female green turtles nesting in the Bijagó s Archipelago, Guinea-Bissau, and tracked them during internesting, migration, and foraging to quantify the degree of coverage the RAMPAO network provides during each of these critical periods. During the internesting period, turtles were largely concentrated around the nesting islands, with a mean of 94.8% (SD 0.1%, range: 46% - 100%, n = 40 turtles) of tracking positions falling within MPA limits. Among the 35 turtles successfully tracked into the foraging period, we identified variable migratory strategies, with 12 turtles remaining near-resident at distances of 40-90 km from breeding sites, 10 turtles migrating 300-400 km to The Gambia and Senegal, and 13 turtles traveling >1000 km to northern Mauritania. Of the 35 foraging turtles, 26 used MPAs, with a mean of 78.0% (SD 34.8%, range: 3.7% - 100%) of their tracking positions falling within the limits of RAMPAO MPAs, across Guinea-Bissau, Senegal and Mauritania. Migration corridors with high concentrations of passing turtles were mostly located nearshore, and 21% of these high passage areas fell within the MPA network. Overall, we found that this population connects five RAMPAO MPAs, yet some foraging sites (e.g., in the Bijagó s) and important migration areas (e.g., Cap-Vert peninsula) described here are currently unprotected. These results are relevant to any considerations of MPA extension or establishment within the regional network, which would contribute towards meeting the Convention on Biological Diversity targets for national marine protected area estate coverage. By documenting biological connectivity across RAMPAO, this study represents an important example of the relevance of international protected area networks for green turtle conservation and for wider conservation action at a regional scale. Fundação para a Ciência e Tecnologia - FCT info:eu-repo/semantics/publishedVersion

Published

2022

3. Using systems mapping to understand the constraints and enablers of solutions to plastic pollution.

Author

Morasae EK, Botterell ZLR, Andrews SHV, Beaumont N, Boisseaux P, Chadwick H, Cherrington R, Cole M, Coppock RL, Deakin K, Duncan EM, Flor D, Galloway TS, Garrard SL, Godley BJ, Harley-Nyang D, Lewis C, Lindeque PK, McCutchion P, Nolan R, Osorio Baquero A, Pinheiro LM, Savage G, Storer L, Thrift E, Wilson DR, Woodhouse C, Xavier M, Yan X, and Nelms SE

Subjects

Waste Management methods, Humans, Plastics, Environmental Pollution

Abstract

Plastic pollution is now considered globally ubiquitous, irreversible, and a planetary boundary threat. Solutions are urgently needed but their development and application are hampered by the complexity and scale of the issue. System dynamics is a technique used to understand complex behaviours of systems through model building and is useful for conceptualising the relationships between various interacting, dynamic factors, and identifying potential intervention points within the system where specific policies or innovations might have the greatest impact or meet with the greatest resistance. Here, twenty-five participants (all scientific researchers of various career stages, disciplines and nationalities working on plastic pollution) completed a series of exercises through an interactive, iterative group model building exercise during a one-day workshop. The process culminated in the generation of a causal loop diagram, based on participants' perspectives, illustrating the dynamic factors relating to the constraints and enablers of solutions to plastic pollution. A total of 18 factors and seven feedback loops were identified. Key factors influencing the system were Effective legislation, Funding, Public education and awareness, Behaviour change, Innovation, and Effective waste management. Our findings highlight that there is no single driver, or 'silver bullet', for resolving this complex issue and that a holistic approach should be adopted to create effective and systemic change., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024