Testing alternative models of climate-mediated extirpations.
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Stress hormone concentration in Rocky Mountain populations of the American pika (Ochotona princeps)Relating sub-surface ice features to physiological stress in a climate sensitive mammal, the American pika (Ochotona princeps)Anthropogenic refugia ameliorate the severe climate-related decline of a montane mammal along its trailing edgeStream isotherm shifts from climate change and implications for distributions of ectothermic organisms.Climate-associated population declines reverse recovery and threaten future of an iconic high-elevation plant.Novel genomic resources for a climate change sensitive mammal: characterization of the American pika transcriptome.The idiosyncrasies of place: geographic variation in the climate-distribution relationships of the American pika.Understanding relationships among abundance, extirpation, and climate at ecoregional scales.Adaptive divergence along environmental gradients in a climate-change-sensitive mammalLandscape effects on gene flow for a climate-sensitive montane species, the American pika.Determinants of pika population density vs. occupancy in the Southern Rocky Mountains.Coming to terms with the concept of moving species threatened by climate change - a systematic review of the terminology and definitions.The importance of biologically relevant microclimates in habitat suitability assessmentsAssessing the components of adaptive capacity to improve conservation and management efforts under global change.From promise to practice: pairing non-invasive sampling with genomics in conservationClimate Tolerances and Habitat Requirements Jointly Shape the Elevational Distribution of the American Pika (Ochotona princeps), with Implications for Climate Change EffectsHabitat availability and gene flow influence diverging local population trajectories under scenarios of climate change: a place-based approach.Modeling behavioral thermoregulation in a climate change sentinel.The role of thermal physiology in recent declines of birds in a biodiversity hotspotMechanistic variables can enhance predictive models of endotherm distributions: the American pika under current, past, and future climates.Replicated landscape genetic and network analyses reveal wide variation in functional connectivity for American pikas.Predictors of Current and Longer-Term Patterns of Abundance of American Pikas (Ochotona princeps) across a Leading-Edge Protected AreaHabitat degradation affects the summer activity of polar bears.Variation in subsurface thermal characteristics of microrefuges used by range core and peripheral populations of the American pika (Ochotona princeps).Individual-based analysis of hair corticosterone reveals factors influencing chronic stress in the American pika.Elevated surface temperature depresses survival of banner-tailed kangaroo rats: will climate change cook a desert icon?On the generality of a climate-mediated shift in the distribution of the American pika (Ochotona princeps).The limit to the distribution of a rainforest marsupial folivore is consistent with the thermal intolerance hypothesis.Climate zone delineation: evaluating approaches for use in natural resource management.American pika in a low-elevation lava landscape: expanding the known distribution of a temperature-sensitive species.When can we measure stress noninvasively? Postdeposition effects on a fecal stress metric confound a multiregional assessmentApparent climate-mediated loss and fragmentation of core habitat of the American pika in the Northern Sierra Nevada, California, USAWhat to eat in a warming world: do increased temperatures necessitate hazardous duty pay?Projecting the future of an alpine ungulate under climate change scenarios.How does climate change cause extinction?Effects of water-level management on nesting success of common loonsObserved and projected changes in absolute temperature records across the contiguous United StatesPredicting microscale shifts in the distribution of the butterfly Plebejus argus at the northern edge of its rangeClimate Change and Species Range Dynamics in Protected AreasClimate change refugia and habitat connectivity promote species persistence
P2860
Q28602043-B65E96C9-2A7B-44B0-B6C0-1B6CA5358375Q28651685-8E646A41-B71A-4037-B09B-E95DBC5807D1Q28727839-A0C7384E-5FE9-4884-8FBA-DF9F700B7710Q30601456-A721D239-743E-4216-A895-D399D2F61445Q30601528-41343047-1892-40B4-BEBA-2EE1316568E5Q30624239-3398A055-40EB-44DD-936F-88EB14F81B4DQ30655869-B436A900-DEAB-48CE-A124-5D09467118EAQ30661859-C2450FDB-3C0A-4540-AA1D-7DEE9423987BQ30690018-3D6241BD-860D-4506-9E0A-DB4CFC3E265EQ30725115-1160491C-5588-46E2-8CC3-B6CA4FF5DAD4Q30822326-AF0A4A9E-7F5F-442D-B662-ABD94E656449Q30838147-C1A2A908-7446-4AB4-8D0E-0C9017335B5DQ30842252-535FB1ED-7A21-46ED-9A4F-79BC83F84255Q30940932-A4BBEB14-0D24-4029-8FC2-85AEDDAE5CC9Q30985287-C430AED0-6015-44C3-AE14-619D48576098Q30985315-AD0098F6-F52B-42D5-9642-F70F84E46489Q31032105-2464AFEB-610D-4719-ABF3-27892EE4F64EQ31039944-7445D2E3-612F-47E0-B4CA-BF9E2A360F6FQ31107683-A13CF4EF-D71A-474D-936B-8F8C52E81279Q31120189-F0871FC2-2930-4B35-9F26-80E88A095E2EQ31137494-08292ACB-1717-4B01-817E-2E99194C7832Q31146141-437DA38F-ABF3-4FE0-8D70-B180A1EACB2BQ31168292-328CABF0-1D08-4878-AA4A-63CE33557741Q31170943-29F1F6A8-E1B6-4EF8-991F-8AC602E53C87Q33817171-C4FF9FA9-7A00-4216-B8D6-212D0BA794E1Q33990481-83C67070-BF28-45E3-8543-6ECCE1DC6C62Q34027677-9C112966-3A87-466E-93FB-D8ABFE765A03Q34045966-63397C46-C08C-4585-A75C-A0EA8B585517Q34196529-29613BF7-5725-4F70-8A8F-9D4A8CD7C9A9Q36054135-9F91681A-3DCB-4D77-81F9-3D408A17D8F2Q36509128-C44EDCAB-2329-4EBD-91B9-8C5CAB519C36Q38602154-9E2EA95E-0DB1-4B35-8FD2-83C8B6B43607Q46263153-211B3239-0842-4B9F-8E7B-D6FC20851DB9Q46295847-3B9D88F6-9B5C-435A-B788-E8F33C963689Q51546847-F9AF9BCA-367E-4EBA-9C10-D0103AE43F50Q55969599-35384E8D-A994-42FF-A69F-3A274383CDD7Q57249105-47301B56-29AF-4216-83D0-C7C3DB83C46FQ57251257-6A366C27-7931-4320-BCAF-054BD5516F07Q57434707-244F1C64-3681-4D30-8FFA-AE8A2F0F9CCEQ59228386-FC28590E-A13E-4709-A434-2EFE04B7DDD7
P2860
Testing alternative models of climate-mediated extirpations.
description
2010 nî lūn-bûn
@nan
2010 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Testing alternative models of climate-mediated extirpations.
@ast
Testing alternative models of climate-mediated extirpations.
@en
Testing alternative models of climate-mediated extirpations.
@nl
type
label
Testing alternative models of climate-mediated extirpations.
@ast
Testing alternative models of climate-mediated extirpations.
@en
Testing alternative models of climate-mediated extirpations.
@nl
prefLabel
Testing alternative models of climate-mediated extirpations.
@ast
Testing alternative models of climate-mediated extirpations.
@en
Testing alternative models of climate-mediated extirpations.
@nl
P2093
P2860
P356
P1476
Testing alternative models of climate-mediated extirpations.
@en
P2093
Erik A Beever
Jennifer L Wilkening
Philip W Mote
P2860
P304
P356
10.1890/08-1011.1
P577
2010-01-01T00:00:00Z