FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3200936719> ?p ?o ?g. }

• W3200936719 endingPage "50" @default.
• W3200936719 startingPage "38" @default.
• W3200936719 abstract "Abstract The microsites that animals occupy during the rest phase of their circadian activity cycle influence their physiology and behaviour, but relatively few studies have examined correlations between interspecific variation in thermal physiology and roost microclimate. Among bats, there is some evidence that species exposed to high roost temperatures ( T roost ) possess greater heat tolerance and evaporative cooling capacity, but the small number of species for which both thermal physiology and roost microclimate data exist mean that the generality of this pattern remains unclear. Here, we test the hypothesis that bat heat tolerance and evaporative cooling capacity have co‐evolved with roost preferences. We predicted that species occupying roosts poorly buffered from high outside environmental temperature exhibit higher heat tolerance and evaporative cooling capacity compared to species inhabiting buffered roosts in which T roost remains well below outside conditions. We used flow‐through respirometry to investigate thermoregulation at air temperatures ( T a ) approaching and exceeding normothermic body temperature ( T b ) among six species with broadly similar body mass but differing in roost microclimate (hot vs. cool roosts). We combined these data with empirical measurements of T roost for each study population. Hot‐roosting species tolerated T a ~4°C higher than cool‐roosting bats before the onset of loss of coordinated locomotion and non‐regulated hyperthermia. The evaporative scope (i.e. ratio of maximum evaporative water loss [EWL] to minimum thermoneutral EWL) of hot‐roosting species (16.1 ± 2.4) was substantially higher than that of cool‐roosting species (5.9 ± 2.4). Maximum evaporative cooling capacities (i.e. evaporative heat loss/metabolic heat production) of hot‐roosting species were >2, while the corresponding values for cool‐roosting species were ≤1. The greater heat tolerance and higher evaporative cooling capacity of hot‐roosting species compared with those occupying cooler roosts reveal variation in bat evaporative cooling capacity correlated with roost microclimate, supporting the hypothesis that thermal physiology has co‐evolved with roost preference. A free Plain Language Summary can be found within the Supporting Information of this article." @default.
• W3200936719 created "2021-09-27" @default.
• W3200936719 creator A5004555674 @default.
• W3200936719 creator A5014269579 @default.
• W3200936719 creator A5016628966 @default.
• W3200936719 creator A5042005989 @default.
• W3200936719 creator A5063070728 @default.
• W3200936719 date "2021-11-03" @default.
• W3200936719 modified "2023-09-27" @default.
• W3200936719 title "Caves, crevices and cooling capacity: Roost microclimate predicts heat tolerance in bats" @default.
• W3200936719 cites W1550170046 @default.
• W3200936719 cites W1838660215 @default.
• W3200936719 cites W1880958846 @default.
• W3200936719 cites W1937050448 @default.
• W3200936719 cites W1964886326 @default.
• W3200936719 cites W1971177115 @default.
• W3200936719 cites W1983227991 @default.
• W3200936719 cites W1985903081 @default.
• W3200936719 cites W1998382670 @default.
• W3200936719 cites W2013410948 @default.
• W3200936719 cites W2015656428 @default.
• W3200936719 cites W2031960305 @default.
• W3200936719 cites W2034041146 @default.
• W3200936719 cites W2037035274 @default.
• W3200936719 cites W2037663175 @default.
• W3200936719 cites W2045562073 @default.
• W3200936719 cites W2048518476 @default.
• W3200936719 cites W2060996312 @default.
• W3200936719 cites W2064447172 @default.
• W3200936719 cites W2065784434 @default.
• W3200936719 cites W2100133623 @default.
• W3200936719 cites W2103288724 @default.
• W3200936719 cites W2116417654 @default.
• W3200936719 cites W2119922695 @default.
• W3200936719 cites W2123643859 @default.
• W3200936719 cites W2123886370 @default.
• W3200936719 cites W2125270554 @default.
• W3200936719 cites W2125601909 @default.
• W3200936719 cites W2133404672 @default.
• W3200936719 cites W2138677176 @default.
• W3200936719 cites W2139572386 @default.
• W3200936719 cites W2142457100 @default.
• W3200936719 cites W2150404014 @default.
• W3200936719 cites W2164418820 @default.
• W3200936719 cites W2313026067 @default.
• W3200936719 cites W2318102365 @default.
• W3200936719 cites W2324358617 @default.
• W3200936719 cites W2324655978 @default.
• W3200936719 cites W2327793195 @default.
• W3200936719 cites W2482881412 @default.
• W3200936719 cites W2497144466 @default.
• W3200936719 cites W2515551573 @default.
• W3200936719 cites W2764455565 @default.
• W3200936719 cites W2768551323 @default.
• W3200936719 cites W2883251903 @default.
• W3200936719 cites W2911298397 @default.
• W3200936719 cites W2950654325 @default.
• W3200936719 cites W2991998196 @default.
• W3200936719 cites W2995259463 @default.
• W3200936719 cites W3006095023 @default.
• W3200936719 cites W3119436914 @default.
• W3200936719 cites W3122601377 @default.
• W3200936719 cites W3129527676 @default.
• W3200936719 cites W3138165026 @default.
• W3200936719 cites W611823233 @default.
• W3200936719 doi "https://doi.org/10.1111/1365-2435.13918" @default.
• W3200936719 hasPublicationYear "2021" @default.
• W3200936719 type Work @default.
• W3200936719 sameAs 3200936719 @default.
• W3200936719 citedByCount "6" @default.
• W3200936719 countsByYear W32009367192022 @default.
• W3200936719 countsByYear W32009367192023 @default.
• W3200936719 crossrefType "journal-article" @default.
• W3200936719 hasAuthorship W3200936719A5004555674 @default.
• W3200936719 hasAuthorship W3200936719A5014269579 @default.
• W3200936719 hasAuthorship W3200936719A5016628966 @default.
• W3200936719 hasAuthorship W3200936719A5042005989 @default.
• W3200936719 hasAuthorship W3200936719A5063070728 @default.
• W3200936719 hasConcept C100564792 @default.
• W3200936719 hasConcept C121332964 @default.
• W3200936719 hasConcept C144024400 @default.
• W3200936719 hasConcept C149923435 @default.
• W3200936719 hasConcept C153294291 @default.
• W3200936719 hasConcept C173991790 @default.
• W3200936719 hasConcept C18903297 @default.
• W3200936719 hasConcept C2908647359 @default.
• W3200936719 hasConcept C32957820 @default.
• W3200936719 hasConcept C55493867 @default.
• W3200936719 hasConcept C68394932 @default.
• W3200936719 hasConcept C86803240 @default.
• W3200936719 hasConcept C90856448 @default.
• W3200936719 hasConceptScore W3200936719C100564792 @default.
• W3200936719 hasConceptScore W3200936719C121332964 @default.
• W3200936719 hasConceptScore W3200936719C144024400 @default.
• W3200936719 hasConceptScore W3200936719C149923435 @default.
• W3200936719 hasConceptScore W3200936719C153294291 @default.
• W3200936719 hasConceptScore W3200936719C173991790 @default.
• W3200936719 hasConceptScore W3200936719C18903297 @default.

• next