J
Jonathan W. Moore
Researcher at Simon Fraser University
Publications - 124
Citations - 7303
Jonathan W. Moore is an academic researcher from Simon Fraser University. The author has contributed to research in topics: Population & Oncorhynchus. The author has an hindex of 33, co-authored 116 publications receiving 6019 citations. Previous affiliations of Jonathan W. Moore include National Marine Fisheries Service & University of California, Santa Cruz.
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Improving Bayesian isotope mixing models: a response to Jackson et al. (2009)
TL;DR: A Bayesian framework for stable isotope mixing models and a software tool for conducting such analyses, MixSIR, consistently and accurately estimated the proportional contribution of prey to a predator diet, and was surprisingly robust to additional unquantified error.
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Synchronisation and stability in river metapopulation networks
TL;DR: The results indicate that this dual stability - conferred by fluctuation and synchronisation dampening - emerges from interaction structure in rivers, and this may strongly influence the persistence of river metapopulations.
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Lake eutrophication at the urban fringe, Seattle region, USA.
TL;DR: It is suggested that septic systems contribute to the high levels of eutrophication in lakes at the urban-rural fringe, which represent an opportunity for proactive management of urban expansion to minimize lake eutrophic levels.
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Cooperation and individuality among man-eating lions
Justin D. Yeakel,Bruce D. Patterson,Kena Fox-Dobbs,Mercedes Okumura,Thure E. Cerling,Jonathan W. Moore,Paul L. Koch,Nathaniel J. Dominy +7 more
TL;DR: Stable isotope ratios are used to quantify increasing dietary specialization on novel prey during a time of food limitation and demonstrate that sustained dietary individuality can exist within a cooperative framework.
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Portfolio conservation of metapopulations under climate change
TL;DR: The findings suggest the importance of conserving the processes that promote thermal-tolerance diversity, such as genetic diversity, habitat heterogeneity, and natural disturbance regimes, and demonstrate that diverse natural portfolios may be critical for metapopulation conservation in the face of increasing climate variability and change.