Opportunities for behavioral rescue under rapid environmental change
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Rebecca L. Selden | Samuel B. Fey | Mary I. O'Connor | Susana Clusella‐Trullas | John P. DeLong | S. Peacor | J. Delong | M. O’Connor | A. Sih | K. Kroeker | V. Rudolf | S. Clusella‐Trullas | Kristy J. Kroeker | David A. Vasseur | Karla Alujević | Michael L. Logan | Volker H. W. Rudolf | Scott Peacor | Andy Sih | Karla Alujević
[1] S. Pincebourde,et al. The roles of microclimatic diversity and of behavior in mediating the responses of ectotherms to climate change. , 2015, Journal of thermal biology.
[2] M. Kearney,et al. Size, shape, and the thermal niche of endotherms , 2009, Proceedings of the National Academy of Sciences.
[3] M. Angilletta,et al. Costs and Benefits of Thermoregulation Revisited: Both the Heterogeneity and Spatial Structure of Temperature Drive Energetic Costs , 2015, The American Naturalist.
[4] S. Adolph,et al. Temperature, Activity, and Lizard Life Histories , 1993, The American Naturalist.
[5] O. Dangles,et al. Does heterogeneity in crop canopy microclimates matter for pests? Evidence from aerial high-resolution thermography , 2017 .
[6] Gary Langham,et al. Towards an Integrated Framework for Assessing the Vulnerability of Species to Climate Change , 2008, PLoS biology.
[7] M. Massot,et al. Erosion of Lizard Diversity by Climate Change and Altered Thermal Niches , 2010, Science.
[8] D. M. Gates,et al. THERMODYNAMIC EQUILIBRIA OF ANIMALS WITH ENVIRONMENT , 1969 .
[9] T. Rusch,et al. Competition during thermoregulation altered the body temperatures and hormone levels of lizards , 2017 .
[10] R. Huey. Behavioral Thermoregulation in Lizards: Importance of Associated Costs , 1974, Science.
[11] W. Porter,et al. Modeling global macroclimatic constraints on ectotherm energy budgets , 1992 .
[12] V. Savage,et al. The thermal dependence of biological traits , 2013 .
[13] David A. Fournier,et al. Physiological and behavioural thermoregulation in bigeye tuna (Thunnus obesus) , 1992, Nature.
[14] Elena Litchman,et al. A Global Pattern of Thermal Adaptation in Marine Phytoplankton , 2012, Science.
[15] Matthew S. Schuler,et al. Configuration of the thermal landscape determines thermoregulatory performance of ectotherms , 2016, Proceedings of the National Academy of Sciences.
[16] M. Angilletta. Thermal Adaptation: A Theoretical and Empirical Synthesis , 2009 .
[17] Paul R. Martin,et al. Impacts of climate warming on terrestrial ectotherms across latitude , 2008, Proceedings of the National Academy of Sciences.
[18] M. Angilletta. Estimating and comparing thermal performance curves , 2006 .
[19] M. Kearney,et al. Mechanistic niche modelling: combining physiological and spatial data to predict species' ranges. , 2009, Ecology letters.
[20] Michael J Angilletta,et al. The world is not flat: defining relevant thermal landscapes in the context of climate change. , 2011, Integrative and comparative biology.
[21] Michael J. Angilletta,et al. Lizards paid a greater opportunity cost to thermoregulate in a less heterogeneous environment , 2017 .
[22] Brett R. Scheffers,et al. Microhabitats reduce animal's exposure to climate extremes , 2014, Global change biology.
[23] M. Kearney,et al. Field studies of reptile thermoregulation: how well do physical models predict operative temperatures? , 2001 .
[24] R. Huey,et al. Cost and Benefits of Lizard Thermoregulation , 1976, The Quarterly Review of Biology.
[25] M. Heithaus,et al. Can animal habitat use patterns influence their vulnerability to extreme climate events? An estuarine sportfish case study , 2017, Global change biology.
[26] A. Dunham,et al. Thermally Imposed Time Constraints on the Activity of the Desert Lizard Sceloporus Merriami , 1988 .
[27] R. Huey,et al. Why “Suboptimal” Is Optimal: Jensen’s Inequality and Ectotherm Thermal Preferences , 2008, The American Naturalist.
[28] Michael Kearney,et al. The potential for behavioral thermoregulation to buffer “cold-blooded” animals against climate warming , 2009, Proceedings of the National Academy of Sciences.
[29] W. Porter,et al. The Effect of Body Temperature and Feeding Regime on Activity, Passage Time, and Digestive Coefficient in the Lizard Uta stansburiana , 1986, Physiological Zoology.
[30] W. Beckman,et al. Behavioral implications of mechanistic ecology , 1973, Oecologia.
[31] J. Delong,et al. Predation changes the shape of thermal performance curves for population growth rate , 2016, Current zoology.
[32] Robert K. Colwell,et al. Thermal-safety margins and the necessity of thermoregulatory behavior across latitude and elevation , 2014, Proceedings of the National Academy of Sciences.
[33] Lauren B. Buckley,et al. Thermoregulatory behaviour limits local adaptation of thermal niches and confers sensitivity to climate change , 2015 .
[34] Brett R. Scheffers,et al. Microhabitats in the tropics buffer temperature in a globally coherent manner , 2014, Biology Letters.
[35] W. Porter,et al. Forest cover reduces thermally suitable habitats and affects responses to a warmer climate predicted in a high-elevation lizard , 2014, Oecologia.
[36] V. Savage,et al. Increased temperature variation poses a greater risk to species than climate warming , 2014, Proceedings of the Royal Society B: Biological Sciences.
[37] S. G. Fernandez,et al. Abiotic constraints on the activity of tropical lizards , 2015 .
[38] Elena Litchman,et al. Trait-Based Community Ecology of Phytoplankton , 2008 .
[39] C. Murdock,et al. Fine-Scale Microclimatic Variation Can Shape the Responses of Organisms to Global Change in Both Natural and Urban Environments. , 2016, Integrative and comparative biology.
[40] F. Hartig,et al. Intraspecific trait variation across scales: implications for understanding global change responses , 2016, Global change biology.
[41] R. Huey,et al. Predicting organismal vulnerability to climate warming: roles of behaviour, physiology and adaptation , 2012, Philosophical Transactions of the Royal Society B: Biological Sciences.
[42] Samuel B. Fey,et al. Thermal variability alters the impact of climate warming on consumer-resource systems. , 2016, Ecology.
[43] Jérôme Casas,et al. Warming decreases thermal heterogeneity of leaf surfaces: implications for behavioural thermoregulation by arthropods , 2014 .
[44] Mridul K. Thomas,et al. Temperature–nutrient interactions exacerbate sensitivity to warming in phytoplankton , 2017, Global change biology.
[45] Raymond B Huey,et al. Behavioral Drive versus Behavioral Inertia in Evolution: A Null Model Approach , 2003, The American Naturalist.
[46] R. Calsbeek,et al. The impact of climate change measured at relevant spatial scales: new hope for tropical lizards , 2013, Global change biology.
[47] W. Porter,et al. Behavior and nutritional condition buffer a large‐bodied endotherm against direct and indirect effects of climate , 2014 .