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Climate change Interest1 #703967
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+Verweise (3) - VerweiseHinzufĂŒgenList by: CiterankMapLink[1] When host populations move north, but disease moves south: counter-intuitive impacts of climate warming on disease spread
Zitieren: E. Joe Moran, Maria Martignoni, Nicolas Lecomte, Patrick Leighton, Amy Hurford Publication date: 9 January 2023 Publication info: Theor Ecol 16, 13â19 (2023) Zitiert von: David Price 11:16 PM 22 November 2023 GMT Citerank: (5) 679752Amy HurfordAmy Hurford is an Associate Professor jointly appointed in the Department of Biology and the Department of Mathematics and Statistics at Memorial University of Newfoundland and Labrador. 10019D3ABAB, 679859Patrick LeightonPatrick Leighton is a Professor of Epidemiology and Public Health at the Faculty of Veterinary Medicine, University of Montreal, and an active member of the Epidemiology of Zoonoses and Public Health Research Group (GREZOSP) and the Centre for Public Health Research (CReSP). 10019D3ABAB, 701037MfPH â Publications144B5ACA0, 701222OMNI â Publications144B5ACA0, 703962Ecology859FDEF6 URL: DOI: https://doi.org/10.1007/s12080-022-00551-z
| Auszug - Empirical observations and mathematical models show that climate warming can lead to the northern (or, more generally, poleward) spread of host species ranges and their corresponding diseases. Here, we consider an unexpected possibility whereby climate warming facilitates disease spread in the opposite direction to the directional shift in the host species range. To explore this possibility, we consider two host species, both susceptible to a disease, but spatially isolated due to distinct thermal niches, and where prior to climate warming the disease is endemic in the northern species only. Previous theoretical results show that species distributions can lag behind species thermal niches when climate warming occurs. As such, we hypothesize that climate warming may increase the overlap between northern and southern host species ranges, due to the northern species lagging behind its thermal tolerance limit. To test our hypothesis, we simulate climate warming as a reaction-diffusion equation model with a Susceptible-Infected (SI) epidemiological structure, for two competing species with distinct temperature-dependent niches. We show that climate warming, by shifting both species niches northwards, can facilitate the southward spread of disease, due to increased range overlap between the two populations. As our model is general, our findings may apply to viral, bacterial, and prion diseases that do not have thermal tolerance limits and are inextricably linked to their hosts distributions, such as the spread of rabies from arctic to red foxes. |
Link[2] Climate tracking by freshwater fishes suggests that fish diversity in temperate lakes may be increasingly threatened by climate warming
Zitieren: Thomas Wu, Mohammad Arshad Imrit, Zahra Movahedinia, Jude Kong, R. Iestyn Woolway, Sapna Sharma Publication date: 19 December 2022 Publication info: Diversity and Distributions, Volume 29, Issue 2 p. 300-315 Zitiert von: David Price 1:22 AM 6 December 2023 GMT Citerank: (3) 679815Jude KongDr. Jude Dzevela Kong is an Assistant Professor in the Department of Mathematics and Statistics at York University and the founding Director of the Africa-Canada Artificial Intelligence and Data Innovation Consortium (ACADIC). 10019D3ABAB, 701037MfPH â Publications144B5ACA0, 703962Ecology859FDEF6 URL: DOI: https://doi.org/10.1111/ddi.13664
| Auszug - [Diversity and Distributions, 19 December 2022]
Aim: Many freshwater fishes are migrating poleward to more thermally suitable habitats in response to warming climates. In this study, we aimed to identify which freshwater fishes are most sensitive to climatic changes and asked: (i) how fast are lakes warming? (ii) how fast are fishes moving? and (iii) are freshwater fishes tracking climate?
Location: Ontario, Canada.
Methods: We assembled a database containing time series data on climate and species occurrence data from 10,732 lakes between 1986 and 2017. We calculated the rate of lake warming and climate velocity for these lakes. Climate velocities were compared with biotic velocities, specifically the rate at which the northernmost extent of each species shifted north.
Results: Lakes in Ontario warmed by 0.2°C decadeâ1 on average, at a climate velocity of 9.4 km decadeâ1 between 1986 and 2017. In response, some freshwater fishes have shifted their northern range boundaries with considerable interspecific variation ranging from species moving southwards at a rate of â58.9 km decadeâ1 to species ranges moving northwards at a rate of 83.6 km decadeâ1 over the same time period. More freshwater fish species are moving into northern lakes in Ontario than those being lost. Generally, predators are moving their range edges northwards, whereas prey fishes are being lost from northern lakes.
Main Conclusions: The concurrent loss of cooler refugia, combined with antagonistic competitive and predatory interactions with the range expanding species, has resulted in many commercially important predators moving their range edges northwards, whereas prey species have contracted their northern range edge boundaries. Trophic partitioning of range shifts highlights a previously undocumented observation of the loss of freshwater fishes from lower trophic levels in response to climate-driven migrations. |
Link[3] Coupling Mountain Pine Beetle and Forest Population Dynamics Predicts Transient Outbreaks that are Likely to Increase in Number with Climate Change
Zitieren: Micah Brush, Mark A. Lewis Publication date: 29 September 2023 Publication info: Bulletin of Mathematical Biology, 29 September 2023, 85, 108 (2023) Zitiert von: David Price 1:53 PM 11 December 2023 GMT Citerank: (3) 679842Mark LewisProfessor Mark Lewis, Kennedy Chair in Mathematical Biology at the University of Victoria and Emeritus Professor at the University of Alberta.10019D3ABAB, 701020CANMOD â PublicationsPublications by CANMOD Members144B5ACA0, 708748Arthropods859FDEF6 URL: DOI: https://doi.org/10.1007/s11538-023-01215-7
| Auszug - [Bulletin of Mathematical Biology, 29 September 2023]
Mountain pine beetle (MPB) in Canada have spread well beyond their historical range. Accurate modelling of the long-term dynamics of MPB is critical for assessing the risk of further expansion and informing management strategies, particularly in the context of climate change and variable forest resilience. Most previous models have focused on capturing a single outbreak without tree replacement. While these models are useful for understanding MPB biology and outbreak dynamics, they cannot accurately model long-term forest dynamics. Past models that incorporate forest growth tend to simplify beetle dynamics. We present a new model that couples forest growth to MPB population dynamics and accurately captures key aspects of MPB biology, including a threshold for the number of beetles needed to overcome tree defenses and beetle aggregation that facilitates mass attacks. These mechanisms lead to a demographic Allee effect, which is known to be important in beetle population dynamics. We show that as forest resilience decreases, a fold bifurcation emerges and there is a stable fixed point with a non-zero MPB population. We derive conditions for the existence of this equilibrium. We then simulate biologically relevant scenarios and show that the beetle population approaches this equilibrium with transient boom and bust cycles with period related to the time of forest recovery. As forest resilience decreases, the Allee threshold also decreases. Thus, if host resilience decreases under climate change, for example under increased stress from drought, then the lower Allee threshold makes transient outbreaks more likely to occur in the future. |
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