Your search keyword '"López Ricaurte, Lina"' showing total 14 results

1. Assessing exposure to wind turbines of a migratory raptor through its annual life cycle across continents

Author

Assandri, Giacomo, Bazzi, Gaia, Bermejo-Bermejo, Ana, Bounas, Anastasios, Calvario, Enrico, Catoni, Carlo, Catry, Inês, Catry, Teresa, Champagnon, Jocelyn, De Pascalis, Federico, de la Puente, Javier, del Moral, Juan Carlos, Duriez, Olivier, Evangelidis, Angelos, Gameiro, João, García-Silveira, Daniel, Garcés-Toledano, Fernando, Jiguet, Frédéric, Kordopatis, Panagiotis, Lopez-Ricaurte, Lina, Martínez, Juan, Mascara, Rosario, Mellone, Ugo, Molina, Blas, Morinay, Jennifer, Pilard, Philippe, Ramellini, Samuele, Rodríguez-Moreno, Beatriz, Romero, Marta, Sarà, Maurizio, Saulnier, Nicolas, Tsiopelas, Nikos, Urios, Vicente, Morganti, Michelangelo, Rubolini, Diego, and Cecere, Jacopo G.

Published

2024

2. Lesser kestrels of the same colony do not overwinter together.

Author

García-Macía, Jorge, Chaouni, Munir, Morollón, Sara, Bustamante, Javier, López-Ricaurte, Lina, Martínez-Dalmau, Juan, Rodríguez-Moreno, Beatriz, and Urios, Vicente

Subjects

GLOBAL Positioning System, COLONIES (Biology), COLONIAL birds, SPANISH colonies, SPATIAL ecology, MIGRATORY animals

Abstract

Migratory connectivity describes the linkage between breeding and nonbreeding sites, having major ecological implications in birds: 1 season influence the success of an individual or a population in the following season. Most studies on migratory connectivity have used large-scale approaches, often considering regional populations, but fine-scale studies are also necessary to understand colony connectivity. The lesser kestrel Falco naumanni , an insectivorous migratory raptor which form colonies during the breeding period, was considered to have strong connectivity based on regional populations. However, no small-scale studies on migratory connectivity have been conducted. Therefore, we GPS (Global Positioning System)-tracked 40 adult lesser kestrels from 15 different Spanish breeding colonies, estimating the overlap index between home ranges and the distance between their centroids. It was found that lesser kestrels from the same breeding colony placed their nonbreeding areas at 347 ± 281 km (mean ± standard deviation) away from each other (range = 23–990), and their home ranges overlapped by 38.4 ± 23.6%. No differences between intra-colony and inter-colony metrics were found, which suggests that lesser kestrels from the same breeding cluster do not overwinter together, but they spread out and mixed independently of the colony belonging throughout the nonbreeding range of the species. Ultimately, this study highlights the importance of performing connectivity studies using fine-scale approaches. [ABSTRACT FROM AUTHOR]

Published

2024

3. Broad-front migration leads to strong migratory connectivity in the lesser kestrel ( Falco naumanni )

Author

Sarà, Maurizio, Bondì, Salvatore, Bermejo, Ana, Bourgeois, Mathieu, Bouzin, Mathias, Bustamante, Javier, de la Puente, Javier, Evangelidis, Angelos, Frassanito, Annagrazia, Fulco, Egidio, Giglio, Giuseppe, Gradev, Gradimir, Griggio, Matteo, Lopez-Ricaurte, Lina, Kordopatis, Panagiotis, Marin, Simeon, Martínez, Juan, Mascara, Rosario, Mellone, Ugo, Pellegrino, Stefania C., Pilard, Philippe, Podofillini, Stefano, Romero, Marta, Gustin, Marco, Saulnier, Nicolas, Serra, Lorenzo, Sfougaris, Athanassios, Urios, Vicente, Visceglia, Matteo, Vlachopoulos, Konstantinos, Zanca, Laura, Cecere, Jacopo G., and Rubolini, Diego

Published

2019

4. Assessing exposure to wind turbines of a migratory raptor through its annual life cycle across continents

Author

Universidad de Alicante. Departamento de Ciencias Ambientales y Recursos Naturales, Assandri, Giacomo, Bazzi, Gaia, Bermejo, Ana, Bounas, Anastasios, Calvario, Enrico, Catoni, Carlo, Catry, Inês, Catry, Teresa, Champagnon, Jocelyn, De Pascalis, Federico, Puente, Javier de la, Moral, Juan Carlos del, Duriez, Olivier, Evangelidis, Angelos, Gameiro, João, García-Silveira, Daniel, Garcés-Toledano, Fernando, Jiguet, Frédéric, Kordopatis, Panagiotis, López-Ricaurte, Lina, Martínez, Juan, Mascara, Rosario, Mellone, Ugo, Molina, Blas, Morinay, Jennifer, Pilard, Philippe, Ramellini, Samuele, Rodríguez-Moreno, Beatriz, Romero, Marta, Sarà, Maurizio, Saulnier, Nicolas, Tsiopelas, Nikos, Urios, Vicente, Morganti, Michelangelo, Rubolini, Diego, Cecere, Jacopo G., Universidad de Alicante. Departamento de Ciencias Ambientales y Recursos Naturales, Assandri, Giacomo, Bazzi, Gaia, Bermejo, Ana, Bounas, Anastasios, Calvario, Enrico, Catoni, Carlo, Catry, Inês, Catry, Teresa, Champagnon, Jocelyn, De Pascalis, Federico, Puente, Javier de la, Moral, Juan Carlos del, Duriez, Olivier, Evangelidis, Angelos, Gameiro, João, García-Silveira, Daniel, Garcés-Toledano, Fernando, Jiguet, Frédéric, Kordopatis, Panagiotis, López-Ricaurte, Lina, Martínez, Juan, Mascara, Rosario, Mellone, Ugo, Molina, Blas, Morinay, Jennifer, Pilard, Philippe, Ramellini, Samuele, Rodríguez-Moreno, Beatriz, Romero, Marta, Sarà, Maurizio, Saulnier, Nicolas, Tsiopelas, Nikos, Urios, Vicente, Morganti, Michelangelo, Rubolini, Diego, and Cecere, Jacopo G.

Abstract

Unsustainable fossil fuel emissions have prompted a global shift towards renewable energy sources, such as wind. This has led to a strong expansion of wind power generation infrastructures, often conflicting with biodiversity conservation. Relatively large flying animals, such as birds and bats, have frequently been reported to collide with wind turbines, resulting in casualties that can depress population size and lead to local extinctions. Migratory species that move across continents through their year-round displacements may be especially at risk. We comprehensively assessed wind turbine exposure for a colonial migratory raptor of European conservation interest, the lesser kestrel Falco naumanni, based on the distribution and size of >1800 colonies and a large GPS-tracking dataset (>350 individuals) for three distinct biogeographical populations (from Iberian, Italian, and Balkan peninsulas). 26 % of the European population has at least one wind turbine within the foraging areas around colony sites, Italian colonies being most at risk. The main European network of protected areas, the Natura 2000 network, failed to mitigate the potential negative impact of wind turbines on breeding populations. GPS-tracking revealed that exposure was negligible in the African non-breeding areas (Sahel region), particularly high during migration, and lower during breeding for Iberian and Balkan individuals but not for Italian ones. Different countries should prioritize different measures to mitigate collision risk with wind power generation infrastructures. This case study can be leveraged by conservationists and renewable energy stakeholders to mitigate conflicts between biodiversity conservation and expected wind energy infrastructure development in the near future.

Published

2024

5. Impacts of oil palm expansion on avian biodiversity in a Neotropical natural savanna

Author

López-Ricaurte, Lina, Edwards, David P., Romero-Rodríguez, Nabhi, and Gilroy, James J.

Published

2017

6. Lesser kestrels of the same colony do not overwinter together

Author

García-Macía, Jorge, primary, Chaouni, Munir, additional, Morollón, Sara, additional, Bustamante, Javier, additional, López-Ricaurte, Lina, additional, Martínez-Dalmau, Juan, additional, Rodríguez-Moreno, Beatriz, additional, and Urios, Vicente, additional

Published

2023

7. Lesser kestrels of the same colony do not overwinter together

Author

García-Macía, Jorge, Chaouni, Munir, Morollón, Sara, Bustamante, Javier, López-Ricaurte, Lina, Martínez-Dalmau, Juan, Rodríguez-Moreno, Beatriz, Urios, Vicente, Universidad de Alicante. Departamento de Ciencias Ambientales y Recursos Naturales, and Zoología de Vertebrados

Subjects

Wintering, Migratory connectivity, Non-breeding, Falco naumanni, Spatial ecology, GPS telemetry, Raptor

Abstract

Migratory connectivity describes the linkage between breeding and non-breeding sites, having major ecological implications in birds: one season influence the success of an individual or a population in the following season. Most studies on migratory connectivity have used large-scale approaches, often considering regional populations, but fine-scale studies are also necessary to understand colony connectivity. The lesser kestrel Falco naumanni, an insectivorous migratory raptor which form colonies during the breeding period, was considered to have strong connectivity based on regional populations. However, no small scale studies on migratory connectivity have been conducted. Therefore, we GPS-tracked 40 adult lesser kestrels from 15 different Spanish breeding colonies, estimating the overlap index between home ranges and the distance between their centroids. It was found that lesser kestrels from the same breeding colony placed their non-breeding areas at 347 ± 281 km (mean ± standard deviation) away from each other (range = 23-990), and their home ranges overlapped by 38.4 ± 23.6%. No differences between intra-colony and inter-colony metrics were found, which suggests that lesser kestrels from the same breeding cluster do not overwinter together, but they spread out and mixed independently of the colony belonging throughout the non-breeding range of the species. Ultimately, this study highlights the importance of performing connectivity studies using fine-scale approaches. Funding for lesser kestrels tagging was provided by Iberdrola España Foundation (MIGRA program of SEO/BirdLife), GREFA (supported by Ministerio para la Transición Ecológica y Reto Demográfico, Junta de Castilla-La Mancha and SEITT, s.a.), Córdoba Zoo, Alcalá de Henares Municipality, and Global Nature Foundation within the LIFE Project “Steppe Farming” (LIFE15417NAT/ES/000734). Lina Lopez-Ricaurte has received financial support through the “La Caixa” INPhINIT Fellowship Grant for Doctoral studies at Spanish Research Centres of Excellence, “La Caixa” Banking Foundation, Barcelona, Spain. In Andalucia tags were funded by “KESTRELS MOVE” project (ref: CGL2016 79249 P) (AEI/FEDER, UE). At the time of analyses and writing, this study was supported by projects MERCURIO (ref: PID2020-421115793GB) (AEI/FEDER,UE) and SUMHAL (European Regional Development Fund4 (ref: LIFEWATCH-2019-09-CSIC-13) (MICINN, POPE 2014-2020). Logistic and technical support was provided by ICTS-RBD.

Published

2023

8. Lesser kestrels of the same colony do not overwinter together

Author

Universidad de Alicante. Departamento de Ciencias Ambientales y Recursos Naturales, García-Macía, Jorge, Chaouni, Munir, Morollón, Sara, Bustamante, Javier, López-Ricaurte, Lina, Martínez-Dalmau, Juan, Rodríguez-Moreno, Beatriz, Urios, Vicente, Universidad de Alicante. Departamento de Ciencias Ambientales y Recursos Naturales, García-Macía, Jorge, Chaouni, Munir, Morollón, Sara, Bustamante, Javier, López-Ricaurte, Lina, Martínez-Dalmau, Juan, Rodríguez-Moreno, Beatriz, and Urios, Vicente

Abstract

Migratory connectivity describes the linkage between breeding and non-breeding sites, having major ecological implications in birds: one season influence the success of an individual or a population in the following season. Most studies on migratory connectivity have used large-scale approaches, often considering regional populations, but fine-scale studies are also necessary to understand colony connectivity. The lesser kestrel Falco naumanni, an insectivorous migratory raptor which form colonies during the breeding period, was considered to have strong connectivity based on regional populations. However, no small scale studies on migratory connectivity have been conducted. Therefore, we GPS-tracked 40 adult lesser kestrels from 15 different Spanish breeding colonies, estimating the overlap index between home ranges and the distance between their centroids. It was found that lesser kestrels from the same breeding colony placed their non-breeding areas at 347 ± 281 km (mean ± standard deviation) away from each other (range = 23-990), and their home ranges overlapped by 38.4 ± 23.6%. No differences between intra-colony and inter-colony metrics were found, which suggests that lesser kestrels from the same breeding cluster do not overwinter together, but they spread out and mixed independently of the colony belonging throughout the non-breeding range of the species. Ultimately, this study highlights the importance of performing connectivity studies using fine-scale approaches.

Published

2023

9. Migratory behaviour and non-breeding movements of the lesser kestrel revealed through GPS technology

Author

López Ricaurte, Lina, Bustamante Díaz, Javier, and Hernández Pliego, Jesús

Subjects

Cernícalos, Seguimiento por GPS, Aves migratorias

Abstract

Programa de Doctorado en Medio Ambiente y Sociedad, Línea de Investigación: Biodiversidad y Biología de la Conservación, Clave Programa: DAM, Código Línea: 125, Multitud de especies de animales se ven obligadas a desplazarse miles de kilómetros cada año en respuesta a cambios en las condiciones ambientales, para así sobrevivir y reproducirse. De entre los distintos grupos que migran, las aves llevan a cabo los desplazamientos más complejos y sus rutas migratorias abarcan la práctica totalidad de la superficie terrestre. Este fenómeno está presente en miles de especies de aves y alrededor de 200 son aves rapaces. Hasta el momento, el 70% de los trabajos relacionados con aves se han enfocado en el periodo reproductor y menos del 15% se centra en el período no reproductor, que comprende la migración e invernada. Esta falta de conocimiento es especialmente importante, teniendo en cuenta que ciertas especies migradoras, por ejemplo, de larga distancia, pueden llegar a pasar hasta el 80% del ciclo anual en sus áreas de invernada. Los avances tecnológicos recientes en el seguimiento a distancia de animales, tales como la miniaturización de dispositivos de GPS (Global Positioning System), han permitido seguir en detalle a números representativos de aves de pequeño a mediano tamaño durante todo su ciclo anual. De este modo, se ha incrementado el conocimiento sobre el comportamiento de las aves y sus movimientos migratorios. Además, dichos avances tecnológicos, junto con la mayor disponibilidad de datos de teledetección, han permitido estudiar la ecología de especies migratorias que se desplazan hasta latitudes tropicales y los peligros potenciales a los que se enfrentan en estos lugares, a veces remotos y de difícil acceso En esta tesis hemos utilizado dispositivos GPS solares que descargan sus datos vía radio UHF (ultra alta frecuencia) y datos ambientales para profundizar en el conocimiento del período no reproductor de un halcón insectívoro de pequeño tamaño. Utilizamos un migrador Afro-Paleártico – el cernícalo primilla Falco naumanni – como especie modelo. Sus movimientos migratorios y de invernada han sido estudiados previamente mediante lecturas de anillas, el trabajo de campo in situ y el marcaje con geolocalizadores y emisores vía satélite (PTT). Dichos estudios han aportado información valiosa como la identificación de sus áreas de invernada en África y descrito sus rutas migratorias. Gracias a la colaboración entre distintos grupos de investigación de España e Italia, el presente estudio cuenta con información de 73 cernícalos primilla adultos marcados en distintas colonias entre 2014 y 2021. En el capítulo 1, analizamos los factores que modulan los itinerarios de viaje y las velocidades de migración de una especie de vuelo generalista. Utilizamos datos de GPS de 70 adultos provenientes de 33 colonias diferentes de cría de España e Italia. En primer lugar, corroboramos los resultados de trabajos anteriores en relación a una migración pos-nupcial más rápida que la pre-nupcial. En segundo lugar, y contrario a nuestras expectativas, los vientos de cola a lo largo de las rutas migratorias resultaron en mayores distancias diarias recorridas y mayores velocidades de viaje durante la migración post-nupcial respecto a la pre-nupcial. No encontramos evidencias para apoyar la hipótesis de que los cernícalos migren con más urgencia durante el viaje pre-nupcial. Además, los factores geográficos modularon los itinerarios de viaje y se observó una tendencia de los primillas a hacer sprints, tanto de día como de noche, mientras atravesaban barreras geográficas como el Desierto del Sahara y el Mar Mediterráneo. Por el resto de zonas migraron más despacio y particularmente de día. En conclusión, mostramos que los factores externos (los vientos y factores geográficos) son más importantes que los internos (sexo) y la motivación estacional a la hora de explicar la variación en el comportamiento migratorio de este pequeño halcón de vuelo generalista, a pesar de su capacidad para alternar entre distintos modos de vuelo. En el capítulo 2 analizamos los factores que influencian la secuencia temporal de la migración pre-nupcial en el cernícalo primilla de diferentes colonias de cría ubicadas en un gradiente de latitud y longitud. Nuestros resultados demuestran que existe una gran variación interindividual, con una ventana de migración que se extiende a lo largo de tres meses. La ubicación de la colonia de cría es la principal fuente de variación que afecta al momento de la migración pre-nupcial, y no existen diferencias significativas entre sexos. Los cernícalos primilla procedentes de colonias ubicadas más hacia el suroeste salen antes de sus áreas de invernada en África y llegan antes a sus colonias de cría en el Mediterráneo en comparación con los individuos que se reproducen en colonias más hacia el noreste. Así mismo, la temperatura de la colonia de cría en primavera es un factor determinante de la fecha de llegada, con los primillas llegando antes a las colonias en zonas más cálidas. También demostramos que la fecha de salida de los sitios de invernada en África es más importante que la velocidad de viaje o la duración de las paradas a la hora de explicar la variación interindividual en las fechas de llegada. Finalmente, los cernícalos primilla tienden a realizar un mayor número de paradas cuando los vientos en ruta son desfavorables o cruzan zonas con mayor productividad de vegetación, especialmente tras superar el Desierto del Sahara. En el capítulo 3 nos trasladamos al periodo de invernada en África Occidental para estudiar en detalle la estrategia de movimiento y las diferencias entre sexos. Además, investigamos el uso de hábitat a escala regional. Para ello, analizamos datos de movimiento de 61 cernícalos procedentes de España. Los resultados muestran que la mayoría de individuos, tanto machos como hembras, realizan movimientos itinerantes entre dos o tres áreas durante el período invernal. Observamos que los cernícalos llegan dispersos al interior de África Occidental –desde la frontera de Senegal hasta la parte más al este de la frontera entre Mauritania y Mali. Sin embargo, en contra de nuestra hipótesis de partida y de otras especies insectívoras, no se desplazan a lo largo de un eje norte-sur en el Sahel. Por el contrario, realizan movimientos longitudinales hacia el oeste o el este utilizando zonas intermedias para congregarse finalmente en áreas cercanas a humedales en las costas de Senegal o al este de Mauritania en la frontera con Mali. Aunque las causas de estos patrones espaciales están pendientes de estudiar, una posible hipótesis es que estas zonas húmedas tengan una mayor disponibilidad de alimento., Universidad Pablo de Olavide de Sevilla. Escuela de Doctorado

Published

2023

10. Kestrels of the same colony do not overwinter together

Author

García-Macía, Jorge, primary, Chaouni, Munir, additional, Morollón, Sara, additional, Bustamante, Javier, additional, López-Ricaurte, Lina, additional, Martínez-Dalmau, Juan, additional, Rodríguez-Moreno, Beatriz, additional, and Urios, Vicente, additional

Published

2022

11. Release of data added to the PREDICTS database (November 2022)

Author

Contu, Sara, De Palma, Adriana, Bates, Rachel, Borer, Jessica, Espinoza De Janon, Felipe, Gao, Di, Harvey, Lorna, Huang, Xiao, Jung, Martin, Maney, Calum, Needler, Gabrielle, Suryometaram, Sasha, Yao, Yujun, Zhang, Hanbin, Albercht, Harald, Almazán-Núñez, Roberto Carlos, Alvarez Alvarez, Edson A., Anitha, K., Barnes, Andrew D., Barzan, Flavia Romina, Baudron, Frederic, Becker, Rafael, Bogyó, David, Bone, James, Bos, Merijn M., Bouam, Idriss, Bravo-Monroy, Liliana, Brown, Keiron, Cabral, Hugo, Calcaterra, Luis, Carpenter, Dan, Carrascal, Luis M., Chiawo, David, Coetzee, Bernard, Connelly, Heather, Cusser, Sarah, da Silva, Luis, Dallimer, Martin, Davies, Stephen, De Smedt, Pallieter, Edwards, David, Eggleton, Paul, Farahat, Emad, Farrell, Mark, Flinn, Kathryn, Forrest, Jessica, Gardner, Charlie, Gardner, Toby, Geoffroy, Jean-Jacques, Gove, Aaron, Guillemot, Joannès, Hendrix, Stephen, Horváth, Roland, Hvenegaard, Glen, Irwin, Sandra, Jackson, Michelle, Jalilova, Gulnaz, Jha, Shalene, Jianghong, Ran, Jones, David T, Kajtoch, Lukasz, Kambach, Stephan, Kamp, Johannes, Karp, Daniel, Kazerani, Farzane, Kessler, Michael, Kitazawa, Munehiro, Knoll, Fátima do Rosário Naschenveng, Kone, Mouhamadou, Kosewska, Agnieszka, Kremen, Claire, Kutt, Alex S, Lacasella, Federica, Lange, Markus, Lees, David, Lei, Fumin, Leong, Misha, Leso, Peter, López Ricaurte, Lina, Magura, Tibor, Mandle, Lisa, Marinaro, Sofía, Martin, Dominic, Massawe, Apia, Minor, Maria, Mir, Aabid Hussain, Mohandass, D., Morgado, Rui, Mulder, Christian, Murvanidze, Maka, Nascimento, Marcelo, Nielsen, Martin Reinhardt, Özden, Özge, Pall, José Luis María, Palomino, David, Philippe, Vaast, Piovesan, Gianluca, Ponge, Jean-François, Sreekar, Rachakonda, Raman, T. R. Shankar, Rengaian, Ganesan, Rolim, Samir, Sahoo, Uttam Kumar, Salmon, Sandrin, Sambuichi, Regina Helena Rosa, Schmiedel, Ute, Schmitt, Christine B, Schmitt, Christine, Selwyn, Mark Arthur, Shahabuddin, Saleh, Sharma, Neeraj, Sofia, Silvia Helena, Soga, Masashi, Song, Gang, Suarez, Andrew V., Suarez-Rubio, Marcela, Sunil, Chikkahuchaiah, Taboada, Angela, Tanalgo, Krizler C., Tóthmérész, Béla, Van Bael, Sunshine, Vanbergen, Adam, Van Vu, Lien, Weideman, Eleanor, Williams, Neal, Wuyts, Karen, Xue, Chen, Yan, Xiaoli, Yongjie, Wu, Zhang, Taxing, Brummitt, Neil, Burton, Victoria, Hill, Samantha L.L., Hudson, Lawrence, Humphries, Josh, Newbold, Tim, Phillips, Helen, Sanchez-Ortiz, Katia, Tobias, Joseph, Vincent, Sarah, Walkden, Patrick, Weeks, Tom, Woodburn, Matt, and Purvis, Andy

Subjects

terrestrial biodiversity, land cover, predicts, land use, global biodiversity, global change, biodiversity

Abstract

This dataset comprises 1,040,752 measurements, collated from 9,544 sampling locations in 46 countries and representing 10,635 species. The data was collated from 115 existing spatial comparisons of local-scale biodiversity exposed to different intensities and types of anthropogenic pressures, from terrestrial sites around the world. The database was assembled as part of the PREDICTS project - Projecting Responses of Ecological Diversity In Changing Terrestrial Systems; https://www.nhm.ac.uk/our-science/our-work/biodiversity/predicts.html This release is an addition to the data presented with The 2016 release of the PREDICTS database (available on the NHM Data Portal: https://data.nhm.ac.uk/dataset/the-2016-release-of-the-predicts-database).

Published

2022

12. Barrier crossings and winds shape daily travel schedules and speeds of a flight generalist

Author

European Commission, López-Ricaurte, Lina, Vansteelant, Wouter M. G., Hernández-Pliego, Jesús, García-Silveira, Daniel, Bermejo-Bermejo, Ana, Casado, Susana, Cecere, Jacopo G., Puente, Javier de la, Garcés-Toledano, Fernando, Martínez-Dalmau, Juan, Ortega, Alfredo, Rodríguez-Moreno, Beatriz, Rubolini, Diego, Sará, Mauricio, Bustamante, Javier, European Commission, López-Ricaurte, Lina, Vansteelant, Wouter M. G., Hernández-Pliego, Jesús, García-Silveira, Daniel, Bermejo-Bermejo, Ana, Casado, Susana, Cecere, Jacopo G., Puente, Javier de la, Garcés-Toledano, Fernando, Martínez-Dalmau, Juan, Ortega, Alfredo, Rodríguez-Moreno, Beatriz, Rubolini, Diego, Sará, Mauricio, and Bustamante, Javier

Abstract

External factors such as geography and weather strongly affect bird migration influencing daily travel schedules and flight speeds. For strictly thermal-soaring migrants, weather explains most seasonal and regional differences in speed. Flight generalists, which alternate between soaring and flapping flight, are expected to be less dependent on weather, and daily travel schedules are likely to be strongly influenced by geography and internal factors such as sex. We GPS-tracked the migration of 70 lesser kestrels (Falco naumanni) to estimate the relative importance of external factors (wind, geography), internal factors (sex) and season, and the extent to which they explain variation in travel speed, distance, and duration. Our results show that geography and tailwind are important factors in explaining variation in daily travel schedules and speeds. We found that wind explained most of the seasonal differences in travel speed. In both seasons, lesser kestrels sprinted across ecological barriers and frequently migrated during the day and night. Conversely, they travelled at a slower pace and mainly during the day over non-barriers. Our results highlighted that external factors far outweighed internal factors and season in explaining variation in migratory behaviour of a flight generalist, despite its ability to switch between flight modes.

Published

2021

13. GPS migratory tracking data from 70 adults lesser kestrels from Spain and Italy

Author

López-Ricaurte, Lina, Vansteelant, Wouter M. G., Hernández-Pliego, Jesús, García-Silveira, Daniel, Bermejo-Bermejo, Ana, Casado, Susana, Cecere, Jacopo G., Puente, Javier de la, Garcés-Toledano, Fernando, Martínez-Dalmau, Juan, Ortega, Alfredo, Rodríguez-Moreno, Beatriz, Rubolini, Diego, Sará, Maurizio, Bustamante, Javier, López-Ricaurte, Lina, Vansteelant, Wouter M. G., Hernández-Pliego, Jesús, García-Silveira, Daniel, Bermejo-Bermejo, Ana, Casado, Susana, Cecere, Jacopo G., Puente, Javier de la, Garcés-Toledano, Fernando, Martínez-Dalmau, Juan, Ortega, Alfredo, Rodríguez-Moreno, Beatriz, Rubolini, Diego, Sará, Maurizio, and Bustamante, Javier

Abstract

External factors such as geography and weather strongly affect bird migration influencing daily travel schedules and flight speeds. For strictly thermal‑soaring migrants, weather explains most seasonal and regional differences in speed. Flight generalists, which alternate between soaring and flapping flight, are expected to be less dependent on weather, and daily travel schedules are likely to be strongly influenced by geography and internal factors such as sex. We GPS‑tracked the migration of 70 lesser kestrels (Falco naumanni) to estimate the relative importance of external factors (wind, geography), internal factors (sex) and season, and the extent to which they explain variation in travel speed, distance, and duration. Our results show that geography and tailwind are important factors in explaining variation in daily travel schedules and speeds. We found that wind explained most of the seasonal differences in travel speed. In both seasons, lesser kestrels sprinted across ecological barriers and frequently migrated during the day and night. Conversely, they travelled at a slower pace and mainly during the day over non‑barriers. Our results highlighted that external factors far outweighed internal factors and season in explaining variation in migratory behaviour of a flight generalist, despite its ability to switch between flight modes.

Published

2021

14. Broad‐front migration leads to strong migratory connectivity in the lesser kestrel (Falco naumanni)

Author

Universidad de Alicante. Departamento de Ciencias Ambientales y Recursos Naturales, Sarà, Maurizio, Bondì, Salvatore, Bermejo, Ana, Bourgeois, Mathieu, Bouzin, Mathias, Bustamante, Javier, Puente, Javier de la, Evangelidis, Angelos, Frassanito, Annagrazia, Fulco, Egidio, Giglio, Giuseppe, Gradev, Gradimir, Griggio, Matteo, López‐Ricaurte, Lina, Kordopatis, Panagiotis, Marin, Simeon, Martínez, Juan, Mascara, Rosario, Mellone, Ugo, Pellegrino, Stefania C., Pilard, Philippe, Podofillini, Stefano, Romero, Marta, Gustin, Marco, Saulnier, Nicolas, Serra, Lorenzo, Sfougaris, Athanassios, Urios, Vicente, Visceglia, Matteo, Vlachopoulos, Konstantinos, Zanca, Laura, Cecere, Jacopo G., Rubolini, Diego, Universidad de Alicante. Departamento de Ciencias Ambientales y Recursos Naturales, Sarà, Maurizio, Bondì, Salvatore, Bermejo, Ana, Bourgeois, Mathieu, Bouzin, Mathias, Bustamante, Javier, Puente, Javier de la, Evangelidis, Angelos, Frassanito, Annagrazia, Fulco, Egidio, Giglio, Giuseppe, Gradev, Gradimir, Griggio, Matteo, López‐Ricaurte, Lina, Kordopatis, Panagiotis, Marin, Simeon, Martínez, Juan, Mascara, Rosario, Mellone, Ugo, Pellegrino, Stefania C., Pilard, Philippe, Podofillini, Stefano, Romero, Marta, Gustin, Marco, Saulnier, Nicolas, Serra, Lorenzo, Sfougaris, Athanassios, Urios, Vicente, Visceglia, Matteo, Vlachopoulos, Konstantinos, Zanca, Laura, Cecere, Jacopo G., and Rubolini, Diego

Abstract

Aim: Migratory animals regularly move between often distant breeding and non‐breeding ranges. Knowledge about how these ranges are linked by movements of individuals from different populations is crucial for unravelling temporal variability in population spatial structuring and for identifying environmental drivers of population dynamics acting at different spatio‐temporal scales. We performed a large‐scale individual‐based migration tracking study of an Afro‐Palaearctic migratory raptor, to determine the patterns of migratory connectivity of European breeding populations. Location: Europe, Africa. Methods: Migration data were recorded using different devices (geolocators, satellite transmitters, Global Positioning System dataloggers) from 87 individuals breeding in the three core European populations, located in the Iberian, Italian and Balkan peninsulas. We estimated connectivity by the Mantel correlation coefficient (rM), and computed both the degree of separation between the non‐breeding areas of individuals from the same population (i.e. the population spread) and the relative size of the non‐breeding range (i.e. the non‐breeding range spread). Results: European lesser kestrels migrated on a broad front across the Mediterranean Sea and Sahara Desert, with different populations using different routes. Iberian birds migrated to western Sahel (Senegal, Mauritania, western Mali), Balkan birds migrated chiefly to central‐eastern Sahel (Niger, Nigeria, Chad), whereas Italian ones spread from eastern Mali to Nigeria. Spatial differentiation of non‐breeding areas led to a strong migratory connectivity (rM = .58), associated with a relatively high population (637 km) and non‐breeding range (1,149 km) spread. Main conclusions: Our comprehensive analysis of the non‐breeding distribution of European lesser kestrel populations revealed a strong migratory connectivity, a rare occurrence in long‐distance avian migrants. The geographical conformation of the species’ breeding a

Published

2019