SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2072268544> ?p ?o ?g. }

Showing items 1 to 100 of ±124 with 100 items per page.

W2072268544 endingPage "835" @default.
W2072268544 startingPage "822" @default.
W2072268544 abstract "The design of a protected areas network that contains or represents as many species as possible (maximum complementarity of areas) is a first step toward in situ conservation of species biodiversity. In the absence of complete species inventories, however, area selection must employ surrogate data such as the distribution of plant or vertebrate species. The degree to which the use of these taxa results in a network of sites with maximum complementarity for others depends on levels of assemblage fidelity among taxa. Assemblage fidelity is defined here as the degree to which assemblages from different phylogenic groups co-occur in space and time. We examined the spatial fidelity of ground-active invertebrate (ants and several beetle families: Carabidae, Scarabaeidae, Pselaphidae), vascular plant, and vertebrate assemblages (birds, small mammals, frogs, and reptiles) at 56 sites in a range of eastern Australian forest types. We used unlogged (n = 32) and logged (n = 24) forest sites. Assemblage fidelity was assessed by ordination and Mantel correlation, and patterns of species richness and species turnover that helped explain the findings were analyzed by simple correlation, cluster analysis, and two indices of β diversity. Our analyses revealed general assemblage fidelity among plant, vertebrate, and invertebrate assemblages, and results were consistent in both unlogged and logged forest. In several forest types, however, fidelity among invertebrates and plants was low due to high invertebrate turnover. Overall levels of species turnover were much higher for vascular plants and invertebrates than for vertebrates. Species richness patterns at individual sites were generally uncorrelated among taxa. Our findings suggest that (1) the exclusion of invertebrates from biodiversity surveys cannot be justified on the assumption that plant and vertebrate assemblages act as surrogates for invertebrate species-level biodiversity or on the basis of cost-efficiency; (2) both spatial fidelity and species turnover are useful for evaluating the role of selected taxa as surrogates for the species-level biodiversity of others; (3) the selection of sites for in situ biodiversity conservation should consider taxa that exhibit high levels of species turnover; and (4) the inclusion of invertebrates in biodiversity surveys may offer considerable cost savings and be more representative of species biodiversity than conventional plant and vertebrate surveys. Fidelidad Espacial de Ensamblajes de Plantas, Vertebrados e Invertebrados en Bosques de usos Múltiples en Australia Oriental El diseño de redes de áreas protegidas que contengan o representen tantas expecies como sea posible (complementaridad máxima de áreas) es un primer paso hacia la conservación in situ de la biodiversidad de especies. Sin embargo, en ausencia de inventarios de especies completos, la selección del área deberá emplear datos alternativos como son la distribución de especies de plantas o vertebrados. El grado de resultado del empleo de estos datos en una red de sitios con máxima complementaridad para con otros dependerá del nivel de fidelidad del ensamblaje entre datos. La fidelidad del ensamblaje se define aquí como el grado con el cual los ensamblajes de diferentes grupos filogenéticos co-ocurren en espacio y tiempo. Examinamos la fidelidad espacial de invetebrados activos del suelo (hormigas y varias familias de escarabajos: Carabidae, Scarabaeidae, Pselaphidae), plantas vasculares y ensamblajes de vertebrados (aves, mamiferos pequeños, ranas y reptiles) en 56 sitios de un rango de bosques de Australia oriental. Utilizamos sitios con bosques no talados (n = 32) y talados (n = 24). La fidelidad del ensamblaje se evaluó por medio de ordenación y correlación de Mantel, los patrones de riqueza y renovación de especies que ayudaron a explicar los resultados fueron analizados mediante correlación simple, análisis de conglomerados (clusters) y dos indices de diversidad β. Nuestros análisis revelan una fidelidad general entre esamblajes de plantas, vertebrados e invetebrados y que los resultados son consistentes tanto en areas taladas como en no taladas. Sin embargo, en diversos tipos de bosques, la fidelidad entre invertebrados y plantas fue baja debido a una elevada tasa de renovación de invertebrados. En general, los patrones de riqueza de especies en sitios individuales no estuvieron correlacionados entre taxas. Nuestros resultados sugieren que: (1) la exclusion de invertebrados de los estudios de biodiversidad no puede ser justificada bajo la aserveración de que los ensamblajes de plantas y vertebrados actúan como indicadores alternativos de biodiversidad para el nivel de especies de invertebrados, ni en base a costo-eficiencia; (2) tanto la fidelidad espacial como la tasa de renovación son valiosos para la evaluación del papel de los taxas seleccionados como alternativos para la biodiversidad a nivel de especie de otros taxas; (3) la selección de sitios para la conservación de la biodiversidad in situ, deberá considerar taxas que exhiban niveles altos de renovación de especies y (4) la inclusión de invertebrados en estudios de biodiversidad podría ofrecer ahorros considerables en costos a la vez de ser mas representativos de la biodiversidad de especies que los estudios convencionales de plantas y vertebrados." @default.
W2072268544 created "2016-06-24" @default.
W2072268544 creator A5009372195 @default.
W2072268544 creator A5041575927 @default.
W2072268544 creator A5080909787 @default.
W2072268544 date "2008-07-07" @default.
W2072268544 modified "2023-10-16" @default.
W2072268544 title "Spatial Fidelity of Plant, Vertebrate, and Invertebrate Assemblages in Multiple-Use Forest in Eastern Australia" @default.
W2072268544 cites W1971962482 @default.
W2072268544 cites W1976245576 @default.
W2072268544 cites W1978723196 @default.
W2072268544 cites W1981497980 @default.
W2072268544 cites W1982668628 @default.
W2072268544 cites W1983445940 @default.
W2072268544 cites W1984034153 @default.
W2072268544 cites W1986652617 @default.
W2072268544 cites W1993706177 @default.
W2072268544 cites W1995029297 @default.
W2072268544 cites W1999203249 @default.
W2072268544 cites W2003996537 @default.
W2072268544 cites W2013082331 @default.
W2072268544 cites W2018378539 @default.
W2072268544 cites W2018510844 @default.
W2072268544 cites W2022271276 @default.
W2072268544 cites W2024738983 @default.
W2072268544 cites W2039765569 @default.
W2072268544 cites W2046589629 @default.
W2072268544 cites W2050907725 @default.
W2072268544 cites W2052655283 @default.
W2072268544 cites W2053762795 @default.
W2072268544 cites W205471692 @default.
W2072268544 cites W2055305434 @default.
W2072268544 cites W2056379348 @default.
W2072268544 cites W2061583694 @default.
W2072268544 cites W2069264677 @default.
W2072268544 cites W2080030631 @default.
W2072268544 cites W2084639724 @default.
W2072268544 cites W2085315835 @default.
W2072268544 cites W2086051504 @default.
W2072268544 cites W2090811801 @default.
W2072268544 cites W2090994388 @default.
W2072268544 cites W2094745735 @default.
W2072268544 cites W2120108422 @default.
W2072268544 cites W2121685929 @default.
W2072268544 cites W2151984535 @default.
W2072268544 cites W2152138353 @default.
W2072268544 cites W2279888815 @default.
W2072268544 cites W2317930875 @default.
W2072268544 cites W2322645255 @default.
W2072268544 cites W2324613907 @default.
W2072268544 cites W2326220906 @default.
W2072268544 cites W2326289858 @default.
W2072268544 cites W2332344960 @default.
W2072268544 cites W2399096431 @default.
W2072268544 cites W2409125466 @default.
W2072268544 cites W4235887661 @default.
W2072268544 cites W4253883125 @default.
W2072268544 doi "https://doi.org/10.1111/j.1523-1739.1998.97075.x" @default.
W2072268544 hasPublicationYear "2008" @default.
W2072268544 type Work @default.
W2072268544 sameAs 2072268544 @default.
W2072268544 citedByCount "43" @default.
W2072268544 countsByYear W20722685442012 @default.
W2072268544 countsByYear W20722685442013 @default.
W2072268544 countsByYear W20722685442014 @default.
W2072268544 countsByYear W20722685442015 @default.
W2072268544 countsByYear W20722685442018 @default.
W2072268544 countsByYear W20722685442019 @default.
W2072268544 countsByYear W20722685442021 @default.
W2072268544 crossrefType "journal-article" @default.
W2072268544 hasAuthorship W2072268544A5009372195 @default.
W2072268544 hasAuthorship W2072268544A5041575927 @default.
W2072268544 hasAuthorship W2072268544A5080909787 @default.
W2072268544 hasConcept C104317684 @default.
W2072268544 hasConcept C130217890 @default.
W2072268544 hasConcept C13474642 @default.
W2072268544 hasConcept C175570560 @default.
W2072268544 hasConcept C18903297 @default.
W2072268544 hasConcept C189592816 @default.
W2072268544 hasConcept C205649164 @default.
W2072268544 hasConcept C25147867 @default.
W2072268544 hasConcept C2778961482 @default.
W2072268544 hasConcept C2780267512 @default.
W2072268544 hasConcept C53565203 @default.
W2072268544 hasConcept C55493867 @default.
W2072268544 hasConcept C62648534 @default.
W2072268544 hasConcept C71640776 @default.
W2072268544 hasConcept C86803240 @default.
W2072268544 hasConceptScore W2072268544C104317684 @default.
W2072268544 hasConceptScore W2072268544C130217890 @default.
W2072268544 hasConceptScore W2072268544C13474642 @default.
W2072268544 hasConceptScore W2072268544C175570560 @default.
W2072268544 hasConceptScore W2072268544C18903297 @default.
W2072268544 hasConceptScore W2072268544C189592816 @default.
W2072268544 hasConceptScore W2072268544C205649164 @default.
W2072268544 hasConceptScore W2072268544C25147867 @default.
W2072268544 hasConceptScore W2072268544C2778961482 @default.
W2072268544 hasConceptScore W2072268544C2780267512 @default.