Abstract is: Mark C. Urban is a biologist and associate professor in ecology and evolutionary biology at the University of Connecticut. His work focuses on the ecological and evolutionary mechanisms that shape natural communities across multiple spatial scales.
human | Q5 |
P2381 | Academic Tree ID | 113270 |
P2671 | Google Knowledge Graph ID | /g/11c0vxnb4m |
P856 | official website | http://hydrodictyon.eeb.uconn.edu/people/urban/ |
P496 | ORCID iD | 0000-0003-3962-4091 |
P1416 | affiliation | University of Connecticut College of Liberal Arts and Sciences | Q99392063 |
P69 | educated at | Muhlenberg College | Q1951942 |
Yale School of Forestry and Environmental Studies | Q8047424 | ||
P108 | employer | University of Connecticut | Q49206 |
P734 | family name | Urban | Q11878943 |
Urban | Q11878943 | ||
Urban | Q11878943 | ||
P735 | given name | Mark | Q13610143 |
Mark | Q13610143 | ||
P6104 | maintained by WikiProject | WikiProject Invasion Biology | Q56241615 |
P106 | occupation | scientist | Q901 |
P5008 | on focus list of Wikimedia project | WikiProject Climate change | Q15305047 |
WikiProject UConn | Q109854824 | ||
P21 | sex or gender | male | Q6581097 |
Q30883264 | A crucial step toward realism: responses to climate change from an evolving metacommunity perspective |
Q33555700 | A framework for community interactions under climate change |
Q92491491 | A global database for metacommunity ecology, integrating species, traits, environment and space |
Q113862418 | A global horizon scan for urban evolutionary ecology |
Q39834278 | A toad more traveled: the heterogeneous invasion dynamics of cane toads in Australia |
Q111319954 | Adaptation reduces competitive dominance and alters community assembly |
Q113083536 | An eco‐evolutionary perspective on the humpty‐dumpty effect and community restoration |
Q107746876 | Analysing eco‐evolutionary dynamics—The challenging complexity of the real world |
Q37008277 | Asymmetric selection and the evolution of extraordinary defences |
Q113918007 | Asynchrony, density dependence, and persistence in an amphibian |
Q129168125 | Author Correction: A global biodiversity observing system to unite monitoring and guide action |
Q89983335 | Author Correction: A global database for metacommunity ecology, integrating species, traits, environment and space |
Q40227037 | Bioavailable pyrrolo-benzo-1,4-diazines as Na(v)1.7 sodium channel blockers for the treatment of pain |
Q33580996 | Can mechanism inform species' distribution models? |
Q113900380 | Canopy closure and amphibian diversity in forested wetlands |
Q114164193 | Climate-tracking species are not invasive |
Q38636881 | Climates Past, Present, and Yet-to-Come Shape Climate Change Vulnerabilities |
Q36109896 | Coarse climate change projections for species living in a fine-scaled world |
Q109382171 | Coding for Life: Designing a Platform for Projecting and Protecting Global Biodiversity |
Q57191252 | Community assembly is a race between immigration and adaptation: eco-evolutionary interactions across spatial scales |
Q51650380 | Community monopolization: local adaptation enhances priority effects in an evolving metacommunity. |
Q114145717 | Cool microrefugia accumulate and conserve biodiversity under climate change |
Q110762480 | DISTURBANCE HETEROGENEITY DETERMINES FRESHWATER METACOMMUNITY STRUCTURE |
Q36196339 | Deconstructing the relationships between phylogenetic diversity and ecology: a case study on ecosystem functioning |
Q90252379 | Developmental temperature influences color polymorphism but not hatchling size in a woodland salamander |
Q104438678 | Eco-evolutionary responses of biodiversity to climate change |
Q34283457 | Ecology. Biotic multipliers of climate change |
Q95507372 | Erratum |
Q58612144 | Escalator to extinction |
Q115787465 | Estimating species relative abundances from museum records |
Q115384004 | Evolution and Community Assembly Across Spatial Scales |
Q51529230 | Evolution mediates the effects of apex predation on aquatic food webs. |
Q97531404 | Evolutionary origins for ecological patterns in space |
Q35896520 | Evolving Perspectives on Monopolization and Priority Effects |
Q36572477 | Evolving metacommunities: toward an evolutionary perspective on metacommunities |
Q33861987 | Heating up relations between cold fish: competition modifies responses to climate change |
Q113800202 | Integrating fundamental processes to understand eco‐evolutionary community dynamics and patterns |
Q89700816 | Life without ice |
Q33252121 | Maladaptation and mass effects in a metacommunity: consequences for species coexistence |
Q93146107 | Maladapted Prey Subsidize Predators and Facilitate Range Expansion |
Q95670374 | Microgeographic Adaptation of Wood Frog Tadpoles to an Apex Predator |
Q35100365 | Microgeographic adaptation and the spatial scale of evolution |
Q101559133 | Microgeographic divergence of functional responses among salamanders under antagonistic selection from apex predators |
Q113918086 | Microgeographic evolution of metabolic physiology in a salamander metapopulation |
Q30652719 | Moving forward: dispersal and species interactions determine biotic responses to climate change |
Q51575233 | On a collision course: competition and dispersal differences create no-analogue communities and cause extinctions during climate change. |
Q51371933 | On the evolution of dispersal via heterogeneity in spatial connectivity. |
Q35085991 | Plasticity and genetic adaptation mediate amphibian and reptile responses to climate change |
Q60232578 | Population of origin and environment interact to determine oomycete infections in spotted salamander populations |
Q39814737 | Predator size and phenology shape prey survival in temporary ponds |
Q122418197 | Projecting biological impacts from climate change like a climate scientist |
Q38611826 | Range position and climate sensitivity: The structure of among-population demographic responses to climatic variation |
Q36114698 | Reciprocal regulation controlling the expression of CPI-17, a specific inhibitor protein for the myosin light chain phosphatase in vascular smooth muscle cells |
Q91080030 | Regional neutrality evolves through local adaptive niche evolution |
Q107746898 | Regional neutrality evolves through local adaptive niche evolution |
Q35971586 | Risky prey behavior evolves in risky habitats |
Q113354695 | River drying influences genetic variation and population structure in an Arctic freshwater fish |
Q39766300 | Road facilitation of trematode infections in snails of northern Alaska |
Q115532241 | Salamander evolution across a latitudinal cline in gape-limited predation risk |
Q46310727 | Searching for Biotic Multipliers of Climate Change. |
Q95604405 | Seasonality and uncertainty in COVID-19 growth rates |
Q100533302 | Seasonality and uncertainty in global COVID-19 growth rates |
Q107746864 | Socio-eco-evolutionary dynamics in cities |
Q40115073 | Strong selection barriers explain microgeographic adaptation in wild salamander populations |
Q109589548 | The Complexity of Urban Eco-evolutionary Dynamics |
Q24685461 | The cane toad's (Chaunus [Bufo] marinus) increasing ability to invade Australia is revealed by a dynamically updated range model |
Q40290396 | The evolution of foraging rate across local and geographic gradients in predation risk and competition |
Q33310483 | The evolution of prey body size reaction norms in diverse communities |
Q39984642 | The evolution of species interactions across natural landscapes |
Q39844386 | The evolutionary ecology of metacommunities |
Q39822506 | The growth-predation risk trade-off under a growing gape-limited predation threat |
Q46269706 | The road to higher permanence and biodiversity in exurban wetlands |
Q33834957 | Why intraspecific trait variation matters in community ecology |
Mark C. Urban | wikipedia | |
Урбан, Марк (эколог) | wikipedia |
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