Natural History Museum of Geneva
Genève, GE, CH
Ciência habilitada
McGowan, N. E., N. Roche, T. Aughney, J. Flanagan, P. Nolan, F. Marnell, and N. Reid. 2021. Testing consistency of modelled predictions of the impact of climate change on bats. Climate Change Ecology 2: 100011. https://doi.org/10.1016/j.ecochg.2021.100011
Species Distribution Models (SDMs) are a cornerstone of climate change conservation research but temporal extrapolations into future climate scenarios cannot be verified until later this century. One way of assessing the robustness of projections is to compare their consistency between different mod…
Salinas-Ramos, V. B., L. Ancillotto, L. Cistrone, C. Nastasi, L. Bosso, S. Smeraldo, V. Sánchez Cordero, and D. Russo. 2021. Artificial illumination influences niche segregation in bats. Environmental Pollution 284: 117187. https://doi.org/10.1016/j.envpol.2021.117187
Artificial light at night (ALAN) is a pervasive form of pollution largely affecting wildlife, from individual behaviour to community structure and dynamics. As nocturnal mammals, bats are often adversely affected by ALAN, yet some “light-opportunistic” species exploit it by hunting insects swarming …
Wieringa, J. G., B. C. Carstens, and H. L. Gibbs. 2021. Predicting migration routes for three species of migratory bats using species distribution models. PeerJ 9: e11177. https://doi.org/10.7717/peerj.11177
Understanding seasonal variation in the distribution and movement patterns of migratory species is essential to monitoring and conservation efforts. While there are many species of migratory bats in North America, little is known about their seasonal movements. In terms of conservation, this is impo…
Dibán, M. J., L. F. Hinojosa, V. Salazar-Vidal, and G. Palfner. 2020. Ripartites tricholoma (Alb. & Schwein.) P. Karst. (Basidiomycota, Agaricales) un nuevo registro de género y especie para Chile. Gayana. Botánica 77: 186–190. https://doi.org/10.4067/s0717-66432020000200186
Ripartites tricholoma collected in the Nature Reserve Altos de Cantillana, near Santiago is described as a first record of this fungal genus and species for Chile. This is a contribution to the knowledge of fungal diversity in Nothofagus macrocarpa dominated forest close to its northern limit of dis…
Smeraldo, S., L. Bosso, V. B. Salinas‐Ramos, L. Ancillotto, V. Sánchez‐Cordero, S. Gazaryan, and D. Russo. 2021. Generalists yet different: distributional responses to climate change may vary in opportunistic bat species sharing similar ecological traits. Mammal Review 51: 571–584. https://doi.org/10.1111/mam.12247
Climate change is among the key anthropogenic factors affecting species’ distribution, with important consequences for conservation. However, little is known concerning the consequences of distributional changes on community‐level interactions, and responses by generalist species might have many eco…
Cruz, J. A., J. L. Prado, and J. Arroyo-Cabrales. 2021. The mutual ecogeographical range and paleoclimatic reconstruction during the Late Pleistocene-Holocene in the Pampas (Argentina) using meso and microvertebrate fossils. The Holocene 31: 983–992. https://doi.org/10.1177/0959683621994652
The Pampas of Argentina is a large grassland ecosystem located in the oriental region southern of South America. As a study case, we present the results of the paleoclimatic analysis of the Tixi Cave site. This is a paleontological and archeological locality that shows a long chronologic sequence, w…
Ellestad, P., F. Forest, M. Serpe, S. J. Novak, and S. Buerki. 2021. Harnessing large-scale biodiversity data to infer the current distribution of Vanilla planifolia (Orchidaceae). Botanical Journal of the Linnean Society 196: 407–422. https://doi.org/10.1093/botlinnean/boab005
Although vanilla is one of the most popular flavours in the world, there is still uncertainty concerning the native distribution of the species that produces it, Vanilla planifolia. To circumscribe the native geographical extent of this economically important species more precisely, we propose a new…
Farooq, H., J. A. R. Azevedo, A. Soares, A. Antonelli, and S. Faurby. 2020. Mapping Africa’s Biodiversity: More of the Same Is Just Not Good Enough S. Ruane [ed.],. Systematic Biology 70: 623–633. https://doi.org/10.1093/sysbio/syaa090
Species distribution data are fundamental to the understanding of biodiversity patterns and processes. Yet, such data are strongly affected by sampling biases, mostly related to site accessibility. The understanding of these biases is therefore crucial in systematics, biogeography and conservation. …
Ortiz, A. M. D., and J. N. V. Torres. 2020. Assessing the Impacts of Agriculture and Its Trade on Philippine Biodiversity. Land 9: 403. https://doi.org/10.3390/land9110403
Many Philippine species are at risk of extinction because of habitat loss and degradation driven by agricultural land use and land-use change. The Philippines is one of the world’s primary banana and pineapple producers. The input-intensive style of plantation agriculture for these typically exporte…
Del Rio, C., J. Huang, P. Liu, W. Deng, T. E. V. Spicer, F. Wu, Z. Zhou, and T. Su. 2021. New Eocene fossil fruits and leaves of Menispermaceae from the central Tibetan Plateau and their biogeographic implications. Journal of Systematics and Evolution 59: 1287–1306. https://doi.org/10.1111/jse.12701
Menispermaceae are a pantropical and temperate family with an extensive fossil record during the Paleogene, especially in North America and Europe, but with much less evidence from Asia. The latest fossil evidence indicates a succession of tropical to sub‐tropical flora on the central Tibetan Platea…