@misc{arnold1972species1, author = "Arnold, S. J", title = "Species densities of predators and their prey", year = "1972", howpublished = "American Naturalist, v. 106, p. 220-236", note = "talkorigins\_source = {true}; raw\_reference = {Arnold, S. J., 1972, Species densities of predators and their prey: American Naturalist, v. 106, p. 220-236.}" } @misc{paulson1973predator3, author = "Paulson, D. R", title = "Predator polymorphism and stochastic selection", year = "1973", howpublished = "Evolution, v. 27, p. 269-277", note = "talkorigins\_source = {true}; raw\_reference = {Paulson, D. R., 1973, Predator polymorphism and stochastic selection: Evolution, v. 27, p. 269-277.}" } @misc{beland1980dinosaur2, author = "Beland, P. and Russell, D. A", title = "Dinosaur Metabolism and Predator/Prey Ratios in the Fossil Record, in Thomas, D. K., and Olson, E. C., eds., A Cold Look at the Warm Blooded Dinosaurs", year = "1980", howpublished = "Washington, D.C., American Association for the Advancement of Science, p. 82-105", note = "talkorigins\_source = {true}; raw\_reference = {Beland, P., and Russell, D. A., 1980, Dinosaur Metabolism and Predator/Prey Ratios in the Fossil Record, in Thomas, D. K., and Olson, E. C., eds., A Cold Look at the Warm Blooded Dinosaurs: Washington, D.C., American Association for the Advancement of Science, p. 82-105.}" } @misc{hillenius2006dinosaur, author = "Hillenius, Willem J", title = "Dinosaur Physiology: Were Dinosaurs Warm‐blooded?", year = "2006", booktitle = "Encyclopedia of Life Sciences", url = "https://doi.org/10.1038/npg.els.0003323", doi = "10.1038/npg.els.0003323" } @article{crossref2009palaeontology, title = "Palaeontology: Hot-blooded dinosaurs", year = "2009", journal = "Nature", url = "https://doi.org/10.1038/462254f", doi = "10.1038/462254f", number = "7271", pages = "254-255", volume = "462" } @misc{quick2013dinosaur, author = "Quick, Devon E and Hillenius, Willem J", title = "Dinosaur Physiology: Were Dinosaurs Warm‐Blooded?", year = "2013", booktitle = "Encyclopedia of Life Sciences", abstract = "To evaluate the possible physiology of dinosaurs, comparisons must be made with their closest living relatives: birds and crocodilians. Although crocodilians maintain ectothermic metabolic rates and have anatomy reflective of this, modern birds achieve high, endothermic metabolic rates through specialised soft tissues supported by unique skeletal attributes. Finding similar shared characters in dinosaurs that are functionally linked to metabolic rates in birds or crocodilians allows plausible reconstruction of dinosaur physiology. Examinations of dinosaur remains reveal no structures with clear functional association with bird‐like respiratory or metabolic physiology, and in some cases indicate crocodilian‐like anatomy. Consequently, dinosaurs were most likely ectothermic, with resting and maximal metabolic rates that were lower than those of modern mammals or birds. However, given the favourable Mesozoic climatic conditions, most dinosaurs were probably able to maintain high, constant body temperatures through behavioural or inertial thermoregulation. Key Concepts: Reconstructing the biology of extinct forms relies on comparison with living taxa that share the same specialised features linked to specific function. Stable body temperature can be achieved through behavioural mechanisms or through virtue of large mass, and need not rely on a particular metabolic strategy. The closest living relatives of dinosaurs are birds and crocodilians, which have widely different metabolic rates supported by different respiratory and skeletal anatomy. Some dinosaur remains preserve evidence, such as postcranial pneumaticity, that may be superficially suggestive of modern bird‐like respiratory anatomy, but they lack other features critical for the ability to ventilate bird‐like lungs or achieve bird‐like aerobic capacity. No dinosaur remains show evidence of respiratory turbinates, a skeletal character functionally associated with modern endothermy. Endothermy was not likely achieved in dinosaurs, but was first present in mid‐Cretaceous birds. Some dinosaurs may have increased aerobic capacity using a crocodilian‐like ventilatory mechanism.", url = "https://doi.org/10.1002/9780470015902.a0003323.pub2", doi = "10.1002/9780470015902.a0003323.pub2" } @article{crossref2014dinosaurs, title = "Dinosaurs may have been neither warm- nor cold-blooded", year = "2014", journal = "Physics Today", url = "https://doi.org/10.1063/pt.5.028008", doi = "10.1063/pt.5.028008", number = "06", volume = "2014" } @article{witze2014dinosaurs, author = "Witze, Alexandra", title = "Dinosaurs neither warm-blooded nor cold-blooded", year = "2014", journal = "Nature", url = "https://doi.org/10.1038/nature.2014.15399", doi = "10.1038/nature.2014.15399" } @incollection{crossref201614, title = "14. HOT-BLOODED DINOSAURS?", year = "2016", booktitle = "Dinosaurs", url = "https://doi.org/10.7312/luca17310-016", doi = "10.7312/luca17310-016", pages = "255-276" } @incollection{schweitzer2020how, author = "Schweitzer, Mary Higby and Schroeter, Elena Rita and Czajka, Charles Doug", title = "How Do We Know if Dinosaurs Were Warm-Blooded, Cold-Blooded, or Something in Between?", year = "2020", booktitle = "Dinosaurs", url = "https://doi.org/10.1201/9780429466717-18", doi = "10.1201/9780429466717-18", pages = "439-468" } @article{carolynwilke2022fossil, author = "Carolyn Wilke, special to C\&EN", title = "Fossil biomolecules suggest which dinosaurs were warm or cold blooded", year = "2022", journal = "C\&EN Global Enterprise", url = "https://doi.org/10.1021/cen-10021-leadcon", doi = "10.1021/cen-10021-leadcon", number = "21", pages = "5-5", volume = "100" } @incollection{crossref202214, title = "14 HOT-BLOODED DINOSAURS?", year = "2022", booktitle = "Dinosaurs", url = "https://doi.org/10.7312/luca20600-018", doi = "10.7312/luca20600-018", pages = "255-276" }