about
Confronting the physiological bottleneck: A challenge from ecomechanicsLong-term, high frequency in situ measurements of intertidal mussel bed temperatures using biomimetic sensorsThermal tolerance and climate warming sensitivity in tropical snailsEffects of temperature change on mussel, Mytilus.Moving forward in global-change ecology: capitalizing on natural variabilitySurvival and arm abscission are linked to regional heterothermy in an intertidal sea star.Climate change, species distribution models, and physiological performance metrics: predicting when biogeographic models are likely to fail.Climate change and latitudinal patterns of intertidal thermal stress.Biophysics, physiological ecology, and climate change: does mechanism matter?Variation in the sensitivity of organismal body temperature to climate change over local and geographic scales.Physiologically grounded metrics of model skill: a case study estimating heat stress in intertidal populationsClimate and recruitment of rocky shore intertidal invertebrates in the eastern North Atlantic.From cells to coastlines: how can we use physiology to forecast the impacts of climate change?Organismal climatology: analyzing environmental variability at scales relevant to physiological stress.Physiological mechanisms in coping with climate change.Tipping points, thresholds and the keystone role of physiology in marine climate change research.A Dynamic Energy Budget (DEB) model for the keystone predator Pisaster ochraceusBiomechanics meets the ecological niche: the importance of temporal data resolution.Temporal coincidence of environmental stress events modulates predation rates.Modelling the ecological niche from functional traits.An intertidal sea star adjusts thermal inertia to avoid extreme body temperatures.Nutrients influence the thermal ecophysiology of an intertidal macroalga: multiple stressors or multiple drivers?Conceptualizing ecosystem tipping points within a physiological framework.The combination of selection and dispersal helps explain genetic structure in intertidal mussels.Interacting environmental mosaics drive geographic variation in mussel performance and predation vulnerability.Microhabitats, thermal heterogeneity, and patterns of physiological stress in the rocky intertidal zone.Morphological and ecological determinants of body temperature of Geukensia demissa, the Atlantic ribbed mussel, and their effects on mussel mortality.How do we Measure the Environment? Linking Intertidal Thermal Physiology and Ecology Through Biophysics.Physiological ecology of rocky intertidal organisms: a synergy of concepts.Untangling the roles of microclimate, behaviour and physiological polymorphism in governing vulnerability of intertidal snails to heat stress.Pido: Predictive Delay Optimization for Intertidal Wireless Sensor Networks.Variation beneath the surface: Quantifying complex thermal environments on coral reefs in the Caribbean, Bahamas and FloridaBody temperature during low tide alters the feeding performance of a top intertidal predatorAn Intertidal Sea Star Adjusts Thermal Inertia to Avoid Extreme Body TemperaturesThe impact of climate change on mediterranean intertidal communities: losses in coastal ecosystem integrity and servicesBiologists ignore ocean weather at their perilMOSAIC PATTERNS OF THERMAL STRESS IN THE ROCKY INTERTIDAL ZONE: IMPLICATIONS FOR CLIMATE CHANGEThe duality of ocean acidification as a resource and a stressorRemote Sensing for BiodiversityThermal sensitivity and the role of behavior in driving an intertidal predator-prey interaction
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researcher
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wetenschapper
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հետազոտող
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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Brian Helmuth
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P1153
6603776423
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P31
P496
0000-0003-0180-3414