Effect of resource subsidies on predator-prey population dynamics: a mathematical model

The influence of a resource subsidy on predator-prey interactions is examined using a mathematical model. The model arises from the study of a biological system involving arctic foxes (predator), lemmings (prey), and seal carcasses (subsidy). In one version of the model, the predator, prey and subsi...

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Format: Text
Language:English
Published: STARS 2012
Subjects:
predator-prey
resource subsidy
population dynamics
patch model
stable equilibrium
arctic fox
FOOD-WEB STABILITY
WESTERN HUDSON-BAY
APPARENT COMPETITION
TROPHIC
CASCADES
MEDIATED COEXISTENCE
2-PATCH ENVIRONMENTS
ECOLOGICAL TIME
SEA-ICE
COMMUNITIES
SYSTEMS
Ecology
Mathematical & Computational Biology
Arctic
Hudson
Hudson Bay
Arctic Fox
Sea ice
Online Access:https://stars.library.ucf.edu/facultybib2010/3079
id ftunicentralflor:oai:stars.library.ucf.edu:facultybib2010-4078
record_format openpolar
spelling ftunicentralflor:oai:stars.library.ucf.edu:facultybib2010-4078 2023-05-15T14:31:10+02:00 Effect of resource subsidies on predator-prey population dynamics: a mathematical model 2012-01-01T08:00:00Z https://stars.library.ucf.edu/facultybib2010/3079 English eng STARS https://stars.library.ucf.edu/facultybib2010/3079 Faculty Bibliography 2010s predator-prey resource subsidy population dynamics patch model stable equilibrium arctic fox FOOD-WEB STABILITY WESTERN HUDSON-BAY APPARENT COMPETITION TROPHIC CASCADES MEDIATED COEXISTENCE 2-PATCH ENVIRONMENTS ECOLOGICAL TIME SEA-ICE COMMUNITIES SYSTEMS Ecology Mathematical & Computational Biology text 2012 ftunicentralflor 2021-12-21T08:53:58Z The influence of a resource subsidy on predator-prey interactions is examined using a mathematical model. The model arises from the study of a biological system involving arctic foxes (predator), lemmings (prey), and seal carcasses (subsidy). In one version of the model, the predator, prey and subsidy all occur in the same location; in a second version, the predator moves between two patches, one containing only the prey and the other containing only the subsidy. Criteria for feasibility and stability of the different equilibrium states are studied both analytically and numerically. At small subsidy input rates, there is a minimum prey carrying capacity needed to support both predator and prey. At intermediate subsidy input rates, the predator and prey can always coexist. At high subsidy input rates, the prey cannot persist even at high carrying capacities. As predator movement increases, the dynamic stability of the predator-prey-subsidy interactions also increases. Text Arctic Fox Arctic Hudson Bay Sea ice University of Central Florida (UCF): STARS (Showcase of Text, Archives, Research & Scholarship) Arctic Hudson Hudson Bay
institution Open Polar
collection University of Central Florida (UCF): STARS (Showcase of Text, Archives, Research & Scholarship)
op_collection_id ftunicentralflor
language English
topic predator-prey
resource subsidy
population dynamics
patch model
stable equilibrium
arctic fox
FOOD-WEB STABILITY
WESTERN HUDSON-BAY
APPARENT COMPETITION
TROPHIC
CASCADES
MEDIATED COEXISTENCE
2-PATCH ENVIRONMENTS
ECOLOGICAL TIME
SEA-ICE
COMMUNITIES
SYSTEMS
Ecology
Mathematical & Computational Biology
spellingShingle predator-prey
resource subsidy
population dynamics
patch model
stable equilibrium
arctic fox
FOOD-WEB STABILITY
WESTERN HUDSON-BAY
APPARENT COMPETITION
TROPHIC
CASCADES
MEDIATED COEXISTENCE
2-PATCH ENVIRONMENTS
ECOLOGICAL TIME
SEA-ICE
COMMUNITIES
SYSTEMS
Ecology
Mathematical & Computational Biology
Effect of resource subsidies on predator-prey population dynamics: a mathematical model
topic_facet predator-prey
resource subsidy
population dynamics
patch model
stable equilibrium
arctic fox
FOOD-WEB STABILITY
WESTERN HUDSON-BAY
APPARENT COMPETITION
TROPHIC
CASCADES
MEDIATED COEXISTENCE
2-PATCH ENVIRONMENTS
ECOLOGICAL TIME
SEA-ICE
COMMUNITIES
SYSTEMS
Ecology
Mathematical & Computational Biology
description The influence of a resource subsidy on predator-prey interactions is examined using a mathematical model. The model arises from the study of a biological system involving arctic foxes (predator), lemmings (prey), and seal carcasses (subsidy). In one version of the model, the predator, prey and subsidy all occur in the same location; in a second version, the predator moves between two patches, one containing only the prey and the other containing only the subsidy. Criteria for feasibility and stability of the different equilibrium states are studied both analytically and numerically. At small subsidy input rates, there is a minimum prey carrying capacity needed to support both predator and prey. At intermediate subsidy input rates, the predator and prey can always coexist. At high subsidy input rates, the prey cannot persist even at high carrying capacities. As predator movement increases, the dynamic stability of the predator-prey-subsidy interactions also increases.
format Text
title Effect of resource subsidies on predator-prey population dynamics: a mathematical model
title_short Effect of resource subsidies on predator-prey population dynamics: a mathematical model
title_full Effect of resource subsidies on predator-prey population dynamics: a mathematical model
title_fullStr Effect of resource subsidies on predator-prey population dynamics: a mathematical model
title_full_unstemmed Effect of resource subsidies on predator-prey population dynamics: a mathematical model
title_sort effect of resource subsidies on predator-prey population dynamics: a mathematical model
publisher STARS
publishDate 2012
url https://stars.library.ucf.edu/facultybib2010/3079
geographic Arctic
Hudson
Hudson Bay
geographic_facet Arctic
Hudson
Hudson Bay
genre Arctic Fox
Arctic
Hudson Bay
Sea ice
genre_facet Arctic Fox
Arctic
Hudson Bay
Sea ice
op_source Faculty Bibliography 2010s
op_relation https://stars.library.ucf.edu/facultybib2010/3079
_version_ 1766304872870707200

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