Interaction strength and stability in stage-structured food web modules. Nilsson, K. A., McCann, K. S., & Caskenette, A. L. Oikos, 127(10):1494–1505, April, 2018. 00000
Interaction strength and stability in stage-structured food web modules [link]Paper  doi  abstract   bibtex   
There has been a long-standing debate on what creates stability in food webs. One major finding is that weak interactions can mute the destabilizing potential of strong interactions. Considering that stage structure is common in nature, that existing studies on stability that include population stage structure point in different directions, and the recent theoretical developments in the area of stage structure, there is a need to address the effects of population stage structure in this context. Using simple food web modules, with stage structure in an intermediate consumer, we here begin to theoretically investigate the effects of stage structure on food web stability. We found a general correspondence to previous results such that strong interactions had destabilizing effects and weak interactions that result in decreased energy flux had stabilizing effects. However, we also found a number of novel results connected to stage structure. Interestingly, weak interactions can be destabilizing when they excite other interactions. We also found that cohort cycles and predator–prey cycles did not respond in the same way to increasing interactions strength. We found that the combined effects of two predators feeding on the same prey can strongly destabilize a system. Consistent with previous studies, we also found that stage-specific feeding can create a refuge effect that leads to a lack of strong destabilization at high interaction strength. Overall, stage structure had both stabilizing and destabilizing aspects. Some effects could be explained by our current understanding of energetic processes; others need additional consideration. Additional aspects such as shunting of energy between stages, control of biomass fluxes, and interactions between lags and energy flux, should be considered.
@article{nilsson_interaction_2018,
	title = {Interaction strength and stability in stage-structured food web modules},
	volume = {127},
	copyright = {© 2018 The Authors},
	issn = {1600-0706},
	url = {https://onlinelibrary.wiley.com/doi/abs/10.1111/oik.05029},
	doi = {10.1111/oik.05029},
	abstract = {There has been a long-standing debate on what creates stability in food webs. One major finding is that weak interactions can mute the destabilizing potential of strong interactions. Considering that stage structure is common in nature, that existing studies on stability that include population stage structure point in different directions, and the recent theoretical developments in the area of stage structure, there is a need to address the effects of population stage structure in this context. Using simple food web modules, with stage structure in an intermediate consumer, we here begin to theoretically investigate the effects of stage structure on food web stability. We found a general correspondence to previous results such that strong interactions had destabilizing effects and weak interactions that result in decreased energy flux had stabilizing effects. However, we also found a number of novel results connected to stage structure. Interestingly, weak interactions can be destabilizing when they excite other interactions. We also found that cohort cycles and predator–prey cycles did not respond in the same way to increasing interactions strength. We found that the combined effects of two predators feeding on the same prey can strongly destabilize a system. Consistent with previous studies, we also found that stage-specific feeding can create a refuge effect that leads to a lack of strong destabilization at high interaction strength. Overall, stage structure had both stabilizing and destabilizing aspects. Some effects could be explained by our current understanding of energetic processes; others need additional consideration. Additional aspects such as shunting of energy between stages, control of biomass fluxes, and interactions between lags and energy flux, should be considered.},
	language = {en},
	number = {10},
	urldate = {2018-07-05},
	journal = {Oikos},
	author = {Nilsson, Karin A. and McCann, Kevin S. and Caskenette, Amanda L.},
	month = apr,
	year = {2018},
	note = {00000},
	keywords = {\#nosource, interaction strength, stability, stage structure},
	pages = {1494--1505},
}

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