Dynamic wildlife habitat models: Seasonal foods and mortality risk predict occupancy-abundance and habitat selection in grizzly bears
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Prioritizing Sites for Protection and Restoration for Grizzly Bears (Ursus arctos) in Southwestern Alberta, CanadaSampling designs matching species biology produce accurate and affordable abundance indicesUsing a data-constrained model of home range establishment to predict abundance in spatially heterogeneous habitatsIdiosyncratic responses of grizzly bear habitat to climate change based on projected food resource changes.Staying cool in a changing landscape: the influence of maximum daily ambient temperature on grizzly bear habitat selection.Macronutrient optimization and seasonal diet mixing in a large omnivore, the grizzly bear: a geometric analysis.Using digital time-lapse cameras to monitor species-specific understorey and overstorey phenology in support of wildlife habitat assessment.Determinants of habitat selection by hatchling Australian freshwater crocodiles.Does learning or instinct shape habitat selection?The impact of roads on the demography of grizzly bears in Alberta.Perception of human-derived risk influences choice at top of the food chain.Spatial analysis of factors influencing long-term stress in the grizzly bear (Ursus arctos) population of Alberta, CanadaDetermination of foraging thresholds and effects of application on energetic carrying capacity for waterfowlAssessing Nutritional Parameters of Brown Bear Diets among Ecosystems Gives Insight into Differences among PopulationsDetermining habitat quality for species that demonstrate dynamic habitat selection.Linking genotype, ecotype, and phenotype in an intensively managed large carnivore.Forbidden fruit: human settlement and abundant fruit create an ecological trap for an apex omnivore.Staying cool or staying safe in a human-dominated landscape: which is more relevant for brown bears?Stoichiometric distribution models: ecological stoichiometry at the landscape extent.Space-time clusters for early detection of grizzly bear predation.Combining threat and occurrence models to predict potential ecological traps for Andean bears in the Cordillera de Mérida, VenezuelaSeasonal and temporal changes in species use of the landscape: how do they impact the inferences from multi-scale habitat modeling?Linking landscape characteristics to local grizzly bear abundance using multiple detection methods in a hierarchical modelEstimating Understory Temperatures Using MODIS LST in Mixed Cordilleran ForestsQuantifying grizzly bear selection of natural and anthropogenic edgesVegetation phenology can be captured with digital repeat photography and linked to variability of root nutrition inHedysarum alpinumLinking ground-based to satellite-derived phenological metrics in support of habitat assessmentA history of habitat dynamics: Characterizing 35 years of stand replacing disturbanceGrizzly bear connectivity mapping in the Canada-United States trans-border regionSpatial and Temporal Heterogeneity Creates a “Brown Tide” in Root Phenology and Nutrition
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Dynamic wildlife habitat models: Seasonal foods and mortality risk predict occupancy-abundance and habitat selection in grizzly bears
description
article
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im Juli 2010 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в липні 2010
@uk
name
Dynamic wildlife habitat model ...... tat selection in grizzly bears
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Dynamic wildlife habitat model ...... tat selection in grizzly bears
@nl
type
label
Dynamic wildlife habitat model ...... tat selection in grizzly bears
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Dynamic wildlife habitat model ...... tat selection in grizzly bears
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prefLabel
Dynamic wildlife habitat model ...... tat selection in grizzly bears
@en
Dynamic wildlife habitat model ...... tat selection in grizzly bears
@nl
P2093
P1476
Dynamic wildlife habitat model ...... tat selection in grizzly bears
@en
P2093
Gordon B. Stenhouse
Greg McDermid
Scott E. Nielsen
P304
P356
10.1016/J.BIOCON.2010.04.007
P50
P577
2010-07-01T00:00:00Z