Your search keyword '"Ćušterevska, Renata"' showing total 41 results

1. Diversity and distribution of Raunkiær's life forms in European vegetation

Author

Midolo, Gabriele, Axmanová, Irena, Divíšek, Jan, Dřevojan, Pavel, Lososová, Zdeňka, Večeřa, Martin, Karger, Dirk Nikolaus, Thuiller, Wilfried, Bruelheide, Helge, Aćić, Svetlana, Attorre, Fabio, Biurrun, Idoia, Boch, Steffen, Bonari, Gianmaria, Čarni, Andraž, Chiarucci, Alessandro, Ćušterevska, Renata, Dengler, Jürgen, Dziuba, Tetiana, Garbolino, Emmanuel, Jandt, Ute, Lenoir, Jonathan, Marcenò, Corrado, Rūsiņa, Solvita, Šibík, Jozef, Škvorc, Željko, Stančić, Zvjezdana, Stanišić‐Vujačić, Milica, Svenning, Jens‐Christian, Swacha, Grzegorz, Vassilev, Kiril, Chytrý, Milan, Midolo, Gabriele, Axmanová, Irena, Divíšek, Jan, Dřevojan, Pavel, Lososová, Zdeňka, Večeřa, Martin, Karger, Dirk Nikolaus, Thuiller, Wilfried, Bruelheide, Helge, Aćić, Svetlana, Attorre, Fabio, Biurrun, Idoia, Boch, Steffen, Bonari, Gianmaria, Čarni, Andraž, Chiarucci, Alessandro, Ćušterevska, Renata, Dengler, Jürgen, Dziuba, Tetiana, Garbolino, Emmanuel, Jandt, Ute, Lenoir, Jonathan, Marcenò, Corrado, Rūsiņa, Solvita, Šibík, Jozef, Škvorc, Željko, Stančić, Zvjezdana, Stanišić‐Vujačić, Milica, Svenning, Jens‐Christian, Swacha, Grzegorz, Vassilev, Kiril, and Chytrý, Milan

Abstract

Aims: The Raunkiær's system classifies vascular plants into life forms based on the position of renewal buds during periods unfavourable for plant growth. Despite the importance of Raunkiær's system for ecological research, a study exploring the diversity and distribution of life forms on a continental scale is missing. We aim to (i) map the diversity and distribution of life forms in European vegetation and (ii) test for effects of bioclimatic variables while controlling for habitat-specific responses. Location: Europe. Methods: We used data on life forms of 8883 species recorded in 546,501 vegetation plots of different habitats (forest, grassland, scrub and wetland). For each plot, we calculated: (i) the proportion of species of each life form and (ii) the richness and evenness of life forms. We mapped these plot-level metrics averaged across 50 km × 50 km grid cells and modelled their response to bioclimatic variables. Results: Hemicryptophytes were the most widespread life form, especially in the temperate zone of Central Europe. Conversely, therophyte and chamaephyte species were more common in the Mediterranean as well as in the dry temperate regions. Moreover, chamaephytes were also more common in the boreal and arctic zones. Higher proportions of phanerophytes were found in the Mediterranean. Overall, a higher richness of life forms was found at lower latitudes while evenness showed more spatially heterogeneous patterns. Habitat type was the main discriminator for most of the responses analysed, but several moisture-related predictors still showed a marked effect on the diversity of therophytes and chamaephytes. Conclusions: Our maps can be used as a tool for future biogeographic and macro-ecological research at a continental scale. Habitat type and bioclimatic conditions are key for regulating the diversity and distribution of plant life forms, with concomitant consequences for the response of functional diversity in European vegetation to global environmen

Published

2024

2. Structural, ecological and biogeographical attributes of European vegetation alliances

Author

Preislerová, Zdenka, Marcenò, Corrado, Loidi, Javier, Bonari, Gianmaria, Borovyk, Dariia, Gavilán, Rosario G., Golub, Valentin, Terzi, Massimo, Theurillat, Jean‐Paul, Argagnon, Olivier, Bioret, Frederic, Biurrun, Idoia, Campos, Juan Antonio, Capelo, Jorge, Čarni, Andraž, Çoban, Süleyman, Csiky, János, Ćuk, Mirjana, Ćušterevska, Renata, Dengler, Jürgen, Didukh, Yakiv, Dítě, Daniel, Fanelli, Giuliano, Fernández‐González, Federico, Guarino, Riccardo, Hájek, Ondřej, Iakushenko, Dmytro, Iemelianova, Svitlana, Jansen, Florian, Jašková, Anni, Jiroušek, Martin, Kalníková, Veronika, Kavgacı, Ali, Kuzemko, Anna, Landucci, Flavia, Lososová, Zdeňka, Milanović, Đorđije, Molina, José Antonio, Monteiro‐Henriques, Tiago, Mucina, Ladislav, Novák, Pavel, Nowak, Arkadiusz, Pätsch, Ricarda, Perrin, Gwenhael, Peterka, Tomáš, Rašomavičius, Valerijus, Reczyńska, Kamila, Rūsiņa, Solvita, Mata, Daniel Sánchez, Guerra, Arnoldo Santos, Šibík, Jozef, Škvorc, Željko, Stešević, Danijela, Stupar, Vladimir, Świerkosz, Krzysztof, Tzonev, Rossen, Vassilev, Kiril, Vynokurov, Denys, Willner, Wolfgang, Chytrý, Milan, Preislerová, Zdenka, Marcenò, Corrado, Loidi, Javier, Bonari, Gianmaria, Borovyk, Dariia, Gavilán, Rosario G., Golub, Valentin, Terzi, Massimo, Theurillat, Jean‐Paul, Argagnon, Olivier, Bioret, Frederic, Biurrun, Idoia, Campos, Juan Antonio, Capelo, Jorge, Čarni, Andraž, Çoban, Süleyman, Csiky, János, Ćuk, Mirjana, Ćušterevska, Renata, Dengler, Jürgen, Didukh, Yakiv, Dítě, Daniel, Fanelli, Giuliano, Fernández‐González, Federico, Guarino, Riccardo, Hájek, Ondřej, Iakushenko, Dmytro, Iemelianova, Svitlana, Jansen, Florian, Jašková, Anni, Jiroušek, Martin, Kalníková, Veronika, Kavgacı, Ali, Kuzemko, Anna, Landucci, Flavia, Lososová, Zdeňka, Milanović, Đorđije, Molina, José Antonio, Monteiro‐Henriques, Tiago, Mucina, Ladislav, Novák, Pavel, Nowak, Arkadiusz, Pätsch, Ricarda, Perrin, Gwenhael, Peterka, Tomáš, Rašomavičius, Valerijus, Reczyńska, Kamila, Rūsiņa, Solvita, Mata, Daniel Sánchez, Guerra, Arnoldo Santos, Šibík, Jozef, Škvorc, Željko, Stešević, Danijela, Stupar, Vladimir, Świerkosz, Krzysztof, Tzonev, Rossen, Vassilev, Kiril, Vynokurov, Denys, Willner, Wolfgang, and Chytrý, Milan

Abstract

The data set described in this article is published on the publisher's webpage as Appendix S1. Future versions of this data set will be available online in the Download section of the FloraVeg.EU database (https://floraveg.eu/download/) and in the Zenodo repository (https://doi.org/10.5281/zenodo.10563021)., The first comprehensive phytosociological classification of all vegetation types in Europe (EuroVegChecklist; Applied Vegetation Science, 2016, 19, 3–264) contained brief descriptions of each type. However, these descriptions were not standardized and mentioned only the most distinct features of each vegetation type. The practical application of the vegetation classification system could be enhanced if users had the option to select sets of vegetation types based on various combinations of structural, ecological, and biogeographical attributes. Based on a literature review and expert knowledge, we created a new database that assigns standardized categorical attributes of 12 variables to each of the 1106 alliances dominated by vascular plants defined in EuroVegChecklist. These variables include dominant life form, phenological optimum, substrate moisture, substrate reaction, salinity, nutrient status, soil organic matter, vegetation region, elevational vegetation belt, azonality, successional status and naturalness. The new database has the potential to enhance the usefulness of phytosociological classification for researchers and practitioners and to help understand this classification to non-specialists.

Published

2024

3. Structural, ecological and biogeographical attributes of European vegetation alliances

Author

Preislerová, Zdenka, primary, Marcenò, Corrado, additional, Loidi, Javier, additional, Bonari, Gianmaria, additional, Borovyk, Dariia, additional, Gavilán, Rosario G., additional, Golub, Valentin, additional, Terzi, Massimo, additional, Theurillat, Jean‐Paul, additional, Argagnon, Olivier, additional, Bioret, Frederic, additional, Biurrun, Idoia, additional, Campos, Juan Antonio, additional, Capelo, Jorge, additional, Čarni, Andraž, additional, Çoban, Süleyman, additional, Csiky, János, additional, Ćuk, Mirjana, additional, Ćušterevska, Renata, additional, Dengler, Jürgen, additional, Didukh, Yakiv, additional, Dítě, Daniel, additional, Fanelli, Giuliano, additional, Fernández‐González, Federico, additional, Guarino, Riccardo, additional, Hájek, Ondřej, additional, Iakushenko, Dmytro, additional, Iemelianova, Svitlana, additional, Jansen, Florian, additional, Jašková, Anni, additional, Jiroušek, Martin, additional, Kalníková, Veronika, additional, Kavgacı, Ali, additional, Kuzemko, Anna, additional, Landucci, Flavia, additional, Lososová, Zdeňka, additional, Milanović, Đorđije, additional, Molina, José Antonio, additional, Monteiro‐Henriques, Tiago, additional, Mucina, Ladislav, additional, Novák, Pavel, additional, Nowak, Arkadiusz, additional, Pätsch, Ricarda, additional, Perrin, Gwenhael, additional, Peterka, Tomáš, additional, Rašomavičius, Valerijus, additional, Reczyńska, Kamila, additional, Rūsiņa, Solvita, additional, Mata, Daniel Sánchez, additional, Guerra, Arnoldo Santos, additional, Šibík, Jozef, additional, Škvorc, Željko, additional, Stešević, Danijela, additional, Stupar, Vladimir, additional, Świerkosz, Krzysztof, additional, Tzonev, Rossen, additional, Vassilev, Kiril, additional, Vynokurov, Denys, additional, Willner, Wolfgang, additional, and Chytrý, Milan, additional

Published

2024

4. Diversity and distribution of Raunkiær's life forms in European vegetation

Author

Midolo, Gabriele, primary, Axmanová, Irena, additional, Divíšek, Jan, additional, Dřevojan, Pavel, additional, Lososová, Zdeňka, additional, Večeřa, Martin, additional, Karger, Dirk Nikolaus, additional, Thuiller, Wilfried, additional, Bruelheide, Helge, additional, Aćić, Svetlana, additional, Attorre, Fabio, additional, Biurrun, Idoia, additional, Boch, Steffen, additional, Bonari, Gianmaria, additional, Čarni, Andraž, additional, Chiarucci, Alessandro, additional, Ćušterevska, Renata, additional, Dengler, Jürgen, additional, Dziuba, Tetiana, additional, Garbolino, Emmanuel, additional, Jandt, Ute, additional, Lenoir, Jonathan, additional, Marcenò, Corrado, additional, Rūsiņa, Solvita, additional, Šibík, Jozef, additional, Škvorc, Željko, additional, Stančić, Zvjezdana, additional, Stanišić‐Vujačić, Milica, additional, Svenning, Jens‐Christian, additional, Swacha, Grzegorz, additional, Vassilev, Kiril, additional, and Chytrý, Milan, additional

Published

2024

5. Rooting depth and xylem vulnerability are independent woody plant traits jointly selected by aridity, seasonality, and water table depth

Author

Laughlin, Daniel C., Siefert, Andrew, Fleri, Jesse R., Tumber-Dávila, Shersingh Joseph, Hammond, William M., Sabatini, Francesco Maria, Damasceno, Gabriella, Aubin, Isabelle, Field, Richard, Hatim, Mohamed Z., Jansen, Steven, Lenoir, Jonathan, Lens, Frederic, McCarthy, James K., Niinemets, Ülo, Phillips, Oliver L., Attorre, Fabio, Bergeron, Yves, Bruun, Hans Henrik, Byun, Chaeho, Ćušterevska, Renata, Dengler, Jürgen, De Sanctis, Michele, Dolezal, Jiri, Jiménez-Alfaro, Borja, Hérault, Bruno, Homeier, Jürgen, Kattge, Jens, Meir, Patrick, Mencuccini, Maurizio, Noroozi, Jalil, Nowak, Arkadiusz, Peñuelas, Josep, Schmidt, Marco, Škvorc, Željko, Sultana, Fahmida, Ugarte, Rosina Magaña, Bruelheide, Helge, Laughlin, Daniel C., Siefert, Andrew, Fleri, Jesse R., Tumber-Dávila, Shersingh Joseph, Hammond, William M., Sabatini, Francesco Maria, Damasceno, Gabriella, Aubin, Isabelle, Field, Richard, Hatim, Mohamed Z., Jansen, Steven, Lenoir, Jonathan, Lens, Frederic, McCarthy, James K., Niinemets, Ülo, Phillips, Oliver L., Attorre, Fabio, Bergeron, Yves, Bruun, Hans Henrik, Byun, Chaeho, Ćušterevska, Renata, Dengler, Jürgen, De Sanctis, Michele, Dolezal, Jiri, Jiménez-Alfaro, Borja, Hérault, Bruno, Homeier, Jürgen, Kattge, Jens, Meir, Patrick, Mencuccini, Maurizio, Noroozi, Jalil, Nowak, Arkadiusz, Peñuelas, Josep, Schmidt, Marco, Škvorc, Željko, Sultana, Fahmida, Ugarte, Rosina Magaña, and Bruelheide, Helge

Abstract

Evolutionary radiations of woody taxa within arid environments were made possible by multiple trait innovations including deep roots and embolism-resistant xylem, but little is known about how these traits have coevolved across the phylogeny of woody plants or how they jointly influence the distribution of species. We synthesized global trait and vegetation plot datasets to examine how rooting depth and xylem vulnerability across 188 woody plant species interact with aridity, precipitation seasonality, and water table depth to influence species occurrence probabilities across all biomes. Xylem resistance to embolism and rooting depth are independent woody plant traits that do not exhibit an interspecific trade-off. Resistant xylem and deep roots increase occurrence probabilities in arid, seasonal climates over deep water tables. Resistant xylem and shallow roots increase occurrence probabilities in arid, nonseasonal climates over deep water tables. Vulnerable xylem and deep roots increase occurrence probabilities in arid, nonseasonal climates over shallow water tables. Lastly, vulnerable xylem and shallow roots increase occurrence probabilities in humid climates. Each combination of trait values optimizes occurrence probabilities in unique environmental conditions. Responses of deeply rooted vegetation may be buffered if evaporative demand changes faster than water table depth under climate change.

Published

2023

6. Ellenberg-type indicator values for European vascular plant species

Author

Biología vegetal y ecología, Landaren biologia eta ekologia, Tichý, Lubomír, Axmanova, Irena, Dengler, Jürgen, Guarino, Riccardo, Jansen, Florian, Midolo, Gabriele, Nobis, Michael P. P., Van Meerbeek, Koenraad, Acic, Svetlana, Attorre, Fabio, Bergmeier, Erwin, Biurrun Galarraga, Miren Idoia, Bonari, Gianmaria, Bruelheide, Helge, Campos Prieto, Juan Antonio, Čarni, Andraž, Chiarucci, Alessandro, Ćuk, Mirjana, Ćušterevska, Renata, Didukh, Yakiv, Dítě, Daniel, Dítě, Zuzana, Dziuba, Tetiana, Fanelli, Giuliano, Fernández Pascual, Eduardo, Garbolino, Emmanuel, Gavilán, Rosario G. G., Gégout, Jean-Claude, Graf, Ulrich, Güler, Behlül, Hájek, Michal, Hennekens, Stephan M., Jandt, Ute, Jašková, Anni, Jiménez Alfaro, Borja, Julve, Philippe, Kambach, Stephan, Karger, Dirk Nikolaus, Karrer, Gerhard, Kavgacı, Ali, Knollová, Ilona, Kuzemko, Anna, Küzmič, Filip, Landucci, Flavia, Lengyel, Attila, Lenoir, Jonathan, Marcenò, Corrado, Moeslund, Jesper Erenskjold, Novák, Pavel, Pérez Haase, Aaron, Peterka, Tomáš, Pielech, Remigiusz, Pignatti, Alessandro, Rašomavičius, Valerijus, Rūsiņa, Solvita, Saatkamp, Arne, Šilc, Urban, Škvorc, Željko, Theurillat, Jean-Paul, Wohlgemuth, Thomas, Chytrý, Milan, Biología vegetal y ecología, Landaren biologia eta ekologia, Tichý, Lubomír, Axmanova, Irena, Dengler, Jürgen, Guarino, Riccardo, Jansen, Florian, Midolo, Gabriele, Nobis, Michael P. P., Van Meerbeek, Koenraad, Acic, Svetlana, Attorre, Fabio, Bergmeier, Erwin, Biurrun Galarraga, Miren Idoia, Bonari, Gianmaria, Bruelheide, Helge, Campos Prieto, Juan Antonio, Čarni, Andraž, Chiarucci, Alessandro, Ćuk, Mirjana, Ćušterevska, Renata, Didukh, Yakiv, Dítě, Daniel, Dítě, Zuzana, Dziuba, Tetiana, Fanelli, Giuliano, Fernández Pascual, Eduardo, Garbolino, Emmanuel, Gavilán, Rosario G. G., Gégout, Jean-Claude, Graf, Ulrich, Güler, Behlül, Hájek, Michal, Hennekens, Stephan M., Jandt, Ute, Jašková, Anni, Jiménez Alfaro, Borja, Julve, Philippe, Kambach, Stephan, Karger, Dirk Nikolaus, Karrer, Gerhard, Kavgacı, Ali, Knollová, Ilona, Kuzemko, Anna, Küzmič, Filip, Landucci, Flavia, Lengyel, Attila, Lenoir, Jonathan, Marcenò, Corrado, Moeslund, Jesper Erenskjold, Novák, Pavel, Pérez Haase, Aaron, Peterka, Tomáš, Pielech, Remigiusz, Pignatti, Alessandro, Rašomavičius, Valerijus, Rūsiņa, Solvita, Saatkamp, Arne, Šilc, Urban, Škvorc, Željko, Theurillat, Jean-Paul, Wohlgemuth, Thomas, and Chytrý, Milan

Abstract

Aims: Ellenberg-type indicator values are expert-based rankings of plant species according to their ecological optima on main environmental gradients. Here we extend the indicator-value system proposed by Heinz Ellenberg and co-authors for Central Europe by incorporating other systems of Ellenberg-type indicator values (i.e., those using scales compatible with Ellenberg values) developed for other European regions. Our aim is to create a harmonized data set of Ellenberg-type indicator values applicable at the European scale.Methods: We collected European data sets of indicator values for vascular plants and selected 13 data sets that used the nine-, ten- or twelve-degree scales defined by Ellenberg for light, temperature, moisture, reaction, nutrients and salinity. We compared these values with the original Ellenberg values and used those that showed consistent trends in regression slope and coefficient of determination. We calculated the average value for each combination of species and indicator values from these data sets. Based on species' co-occurrences in European vegetation plots, we also calculated new values for species that were not assigned an indicator value.Results: We provide a new data set of Ellenberg-type indicator values for 8908 European vascular plant species (8168 for light, 7400 for temperature, 8030 for moisture, 7282 for reaction, 7193 for nutrients, and 7507 for salinity), of which 398 species have been newly assigned to at least one indicator value.Conclusions: The newly introduced indicator values are compatible with the original Ellenberg values. They can be used for large-scale studies of the European flora and vegetation or for gap-filling in regional data sets. The European indicator values and the original and taxonomically harmonized regional data sets of Ellenberg-type indicator values are available in the Supporting Information and the Zenodo repository.

Published

2023

7. Ellenberg‐type indicator values for European vascular plant species

Author

Tichý, Lubomír, Axmanová, Irena, Dengler, Jürgen, Guarino, Riccardo, Jansen, Florian, Midolo, Gabriele, Nobis, Michael P., Van Meerbeek, Koenraad, Aćić, Svetlana, Attorre, Fabio, Bergmeier, Erwin, Biurrun, Idoia, Bonari, Gianmaria, Bruelheide, Helge, Campos, Juan Antonio, Čarni, Andraž, Chiarucci, Alessandro, Ćuk, Mirjana, Ćušterevska, Renata, Didukh, Yakiv, Dítě, Daniel, Dítě, Zuzana, Dziuba, Tetiana, Fanelli, Giuliano, Fernández‐Pascual, Eduardo, Garbolino, Emmanuel, Gavilán, Rosario G., Gégout, Jean‐Claude, Graf, Ulrich, Güler, Behlül, Hájek, Michal, Hennekens, Stephan M., Jandt, Ute, Jašková, Anni, Jiménez‐Alfaro, Borja, Julve, Philippe, Kambach, Stephan, Karger, Dirk Nikolaus, Karrer, Gerhard, Kavgacı, Ali, Knollová, Ilona, Kuzemko, Anna, Küzmič, Filip, Landucci, Flavia, Lengyel, Attila, Lenoir, Jonathan, Marcenò, Corrado, Moeslund, Jesper Erenskjold, Novák, Pavel, Pérez‐Haase, Aaron, Peterka, Tomáš, Pielech, Remigiusz, Pignatti, Alessandro, Rašomavičius, Valerijus, Rūsiņa, Solvita, Saatkamp, Arne, Šilc, Urban, Škvorc, Željko, Theurillat, Jean‐Paul, Wohlgemuth, Thomas, Chytrý, Milan, Tichý, Lubomír, Axmanová, Irena, Dengler, Jürgen, Guarino, Riccardo, Jansen, Florian, Midolo, Gabriele, Nobis, Michael P., Van Meerbeek, Koenraad, Aćić, Svetlana, Attorre, Fabio, Bergmeier, Erwin, Biurrun, Idoia, Bonari, Gianmaria, Bruelheide, Helge, Campos, Juan Antonio, Čarni, Andraž, Chiarucci, Alessandro, Ćuk, Mirjana, Ćušterevska, Renata, Didukh, Yakiv, Dítě, Daniel, Dítě, Zuzana, Dziuba, Tetiana, Fanelli, Giuliano, Fernández‐Pascual, Eduardo, Garbolino, Emmanuel, Gavilán, Rosario G., Gégout, Jean‐Claude, Graf, Ulrich, Güler, Behlül, Hájek, Michal, Hennekens, Stephan M., Jandt, Ute, Jašková, Anni, Jiménez‐Alfaro, Borja, Julve, Philippe, Kambach, Stephan, Karger, Dirk Nikolaus, Karrer, Gerhard, Kavgacı, Ali, Knollová, Ilona, Kuzemko, Anna, Küzmič, Filip, Landucci, Flavia, Lengyel, Attila, Lenoir, Jonathan, Marcenò, Corrado, Moeslund, Jesper Erenskjold, Novák, Pavel, Pérez‐Haase, Aaron, Peterka, Tomáš, Pielech, Remigiusz, Pignatti, Alessandro, Rašomavičius, Valerijus, Rūsiņa, Solvita, Saatkamp, Arne, Šilc, Urban, Škvorc, Željko, Theurillat, Jean‐Paul, Wohlgemuth, Thomas, and Chytrý, Milan

Abstract

Aims: Ellenberg-type indicator values are expert-based rankings of plant species according to their ecological optima on main environmental gradients. Here we extend the indicator-value system proposed by Heinz Ellenberg and co-authors for Central Europe by incorporating other systems of Ellenberg-type indicator values (i.e., those using scales compatible with Ellenberg values) developed for other European regions. Our aim is to create a harmonized data set of Ellenberg-type indicator values applicable at the European scale. Methods: We collected European data sets of indicator values for vascular plants and selected 13 data sets that used the nine-, ten- or twelve-degree scales defined by Ellenberg for light, temperature, moisture, reaction, nutrients and salinity. We compared these values with the original Ellenberg values and used those that showed consistent trends in regression slope and coefficient of determination. We calculated the average value for each combination of species and indicator values from these data sets. Based on species’ co-occurrences in European vegetation plots, we also calculated new values for species that were not assigned an indicator value. Results: We provide a new data set of Ellenberg-type indicator values for 8908 European vascular plant species (8168 for light, 7400 for temperature, 8030 for moisture, 7282 for reaction, 7193 for nutrients, and 7507 for salinity), of which 398 species have been newly assigned to at least one indicator value. Conclusions: The newly introduced indicator values are compatible with the original Ellenberg values. They can be used for large-scale studies of the European flora and vegetation or for gap-filling in regional data sets. The European indicator values and the original and taxonomically harmonized regional data sets of Ellenberg-type indicator values are available in the Supporting Information and the Zenodo repository.

Published

2023

8. Ellenberg‐type indicator values for European vascular plant species

Author

Tichý, Lubomír, primary, Axmanová, Irena, additional, Dengler, Jürgen, additional, Guarino, Riccardo, additional, Jansen, Florian, additional, Midolo, Gabriele, additional, Nobis, Michael P., additional, Van Meerbeek, Koenraad, additional, Aćić, Svetlana, additional, Attorre, Fabio, additional, Bergmeier, Erwin, additional, Biurrun, Idoia, additional, Bonari, Gianmaria, additional, Bruelheide, Helge, additional, Campos, Juan Antonio, additional, Čarni, Andraž, additional, Chiarucci, Alessandro, additional, Ćuk, Mirjana, additional, Ćušterevska, Renata, additional, Didukh, Yakiv, additional, Dítě, Daniel, additional, Dítě, Zuzana, additional, Dziuba, Tetiana, additional, Fanelli, Giuliano, additional, Fernández‐Pascual, Eduardo, additional, Garbolino, Emmanuel, additional, Gavilán, Rosario G., additional, Gégout, Jean‐Claude, additional, Graf, Ulrich, additional, Güler, Behlül, additional, Hájek, Michal, additional, Hennekens, Stephan M., additional, Jandt, Ute, additional, Jašková, Anni, additional, Jiménez‐Alfaro, Borja, additional, Julve, Philippe, additional, Kambach, Stephan, additional, Karger, Dirk Nikolaus, additional, Karrer, Gerhard, additional, Kavgacı, Ali, additional, Knollová, Ilona, additional, Kuzemko, Anna, additional, Küzmič, Filip, additional, Landucci, Flavia, additional, Lengyel, Attila, additional, Lenoir, Jonathan, additional, Marcenò, Corrado, additional, Moeslund, Jesper Erenskjold, additional, Novák, Pavel, additional, Pérez‐Haase, Aaron, additional, Peterka, Tomáš, additional, Pielech, Remigiusz, additional, Pignatti, Alessandro, additional, Rašomavičius, Valerijus, additional, Rūsiņa, Solvita, additional, Saatkamp, Arne, additional, Šilc, Urban, additional, Škvorc, Željko, additional, Theurillat, Jean‐Paul, additional, Wohlgemuth, Thomas, additional, and Chytrý, Milan, additional

Published

2023

9. Bringing the margin to the focus: 10 challenges for riparian vegetation science and management

Author

Rodríguez‐González, Patricia M., primary, Abraham, Eleni, additional, Aguiar, Francisca, additional, Andreoli, Andrea, additional, Baležentienė, Ligita, additional, Berisha, Naim, additional, Bernez, Ivan, additional, Bruen, Michael, additional, Bruno, Daniel, additional, Camporeale, Carlo, additional, Čarni, Andraž, additional, Chilikova‐Lubomirova, Mila, additional, Corenblit, Dov, additional, Ćušterevska, Renata, additional, Doody, Tanya, additional, England, Judy, additional, Evette, André, additional, Francis, Robert, additional, Garófano‐Gómez, Virginia, additional, González del Tánago, Marta, additional, Gultekin, Yasar Selman, additional, Guyard, Florian, additional, Hellsten, Seppo, additional, Hinkov, Georgi, additional, Jakubínský, Jiří, additional, Janssen, Philippe, additional, Jansson, Roland, additional, Kail, Jochem, additional, Keles, Emine, additional, Kelly‐Quinn, Mary, additional, Kidová, Anna, additional, Kiss, Tímea, additional, Kulvik, Mart, additional, La Porta, Nicola, additional, Laslier, Marianne, additional, Latella, Melissa, additional, Lorenz, Stefan, additional, Mandžukovski, Dejan, additional, Manolaki, Paraskevi, additional, Martinez‐Fernández, Vanesa, additional, Merritt, David, additional, Michez, Adrien, additional, Milovanović, Jelena, additional, Okruszko, Tomasz, additional, Papastergiadou, Eva, additional, Penning, Ellis, additional, Pielech, Remigiusz, additional, Politti, Emilio, additional, Portela, Ana, additional, Riis, Tenna, additional, Škvorc, Željko, additional, Slezák, Michal, additional, Stammel, Barbara, additional, Stella, John, additional, Stesevic, Danijela, additional, Stupar, Vladimir, additional, Tammeorg, Olga, additional, Tammeorg, Priit, additional, Fosholt, Therese Moe, additional, Urbanič, Gorazd, additional, Villar, Marc, additional, Vogiatzakis, Ioannis, additional, Vrchovsky, Paul, additional, Yousefpour, Rasoul, additional, Zinke, Peggy, additional, Zlatanov, Tzvetan, additional, and Dufour, Simon, additional

Published

2022

10. Distribution maps of vegetation alliances in Europe

Author

Biología vegetal y ecología, Landaren biologia eta ekologia, Preislerová, Zdenka, Jiménez-Alfaro, Borja, Mucina, Ladislav, Berg, Christian, Bonari, Gianmaria, Kuzemko, Anna, Landucci, Flavia, Marcenò, Corrado, Monteiro-Henriques, Tiago, Novák, Pavel, Vynokurov, Denys, Bergmeier, Erwin, Dengler, Jürgen, Apostolova, Iva, Bioret, Frederic, Biurrun, Idoia, Biurrun Galarraga, Miren Idoia, Campos, Juan Antonio, Capelo, Jorge, Čarni, Andraž, Çoban, Süleyman, Csiky, János, Ćuk, Mirjana, Ćušterevska, Renata, Daniëls, Fred J.A., De Sanctis, Michele, Didukh, Yakiv, Dítě, Daniel, Fanelli, Giuliano, Golovanov, Yaroslav, Golub, Valentin, Guarino, Riccardo, Hájek, Michal, Iakushenko, Dmytro, Indreica, Adrian, Jansen, Florian, Jašková, Anni, Jiroušek, Martin, Kalníková, Veronika, Kavgacı, Ali, Kucherov, Ilya, Küzmič, Filip, Lebedeva, Maria, Loidi, Javier, Lososová, Zdeňka, Lysenko, Tatiana, Milanović, Đorđije, Onyshchenko, Viktor, Perrin, Gwenhael, Peterka, Tomáš, Rašomavičius, Valerijus, Rodríguez-Rojo, María Pilar, Rodwell, John S., Rūsiņa, Solvita, Sánchez-Mata, Daniel, Schaminée, Joop H.J., Semenishchenkov, Yuri, Shevchenko, Nikolay, Šibík, Jozef, Škvorc, Željko, Smagin, Viktor, Stešević, Danijela, Stupar, Vladimir, Šumberová, Kateřina, Theurillat, Jean-Paul, Tikhonova, Elena, Tzonev, Rossen, Valachovič, Milan, Vassilev, Kiril, Willner, Wolfgang, Yamalov, Sergey, Milan Chytrý, Martin Večeřa, Biología vegetal y ecología, Landaren biologia eta ekologia, Preislerová, Zdenka, Jiménez-Alfaro, Borja, Mucina, Ladislav, Berg, Christian, Bonari, Gianmaria, Kuzemko, Anna, Landucci, Flavia, Marcenò, Corrado, Monteiro-Henriques, Tiago, Novák, Pavel, Vynokurov, Denys, Bergmeier, Erwin, Dengler, Jürgen, Apostolova, Iva, Bioret, Frederic, Biurrun, Idoia, Biurrun Galarraga, Miren Idoia, Campos, Juan Antonio, Capelo, Jorge, Čarni, Andraž, Çoban, Süleyman, Csiky, János, Ćuk, Mirjana, Ćušterevska, Renata, Daniëls, Fred J.A., De Sanctis, Michele, Didukh, Yakiv, Dítě, Daniel, Fanelli, Giuliano, Golovanov, Yaroslav, Golub, Valentin, Guarino, Riccardo, Hájek, Michal, Iakushenko, Dmytro, Indreica, Adrian, Jansen, Florian, Jašková, Anni, Jiroušek, Martin, Kalníková, Veronika, Kavgacı, Ali, Kucherov, Ilya, Küzmič, Filip, Lebedeva, Maria, Loidi, Javier, Lososová, Zdeňka, Lysenko, Tatiana, Milanović, Đorđije, Onyshchenko, Viktor, Perrin, Gwenhael, Peterka, Tomáš, Rašomavičius, Valerijus, Rodríguez-Rojo, María Pilar, Rodwell, John S., Rūsiņa, Solvita, Sánchez-Mata, Daniel, Schaminée, Joop H.J., Semenishchenkov, Yuri, Shevchenko, Nikolay, Šibík, Jozef, Škvorc, Željko, Smagin, Viktor, Stešević, Danijela, Stupar, Vladimir, Šumberová, Kateřina, Theurillat, Jean-Paul, Tikhonova, Elena, Tzonev, Rossen, Valachovič, Milan, Vassilev, Kiril, Willner, Wolfgang, Yamalov, Sergey, and Milan Chytrý, Martin Večeřa

Abstract

Aim The first comprehensive checklist of European phytosociological alliances, orders and classes (EuroVegChecklist) was published by Mucina et al. (2016, Applied Vegetation Science, 19 (Suppl. 1), 3-264). However, this checklist did not contain detailed information on the distribution of individual vegetation types. Here we provide the first maps of all alliances in Europe. Location Europe, Greenland, Canary Islands, Madeira, Azores, Cyprus and the Caucasus countries. Methods We collected data on the occurrence of phytosociological alliances in European countries and regions from literature and vegetation-plot databases. We interpreted and complemented these data using the expert knowledge of an international team of vegetation scientists and matched all the previously reported alliance names and concepts with those of the EuroVegChecklist. We then mapped the occurrence of the EuroVegChecklist alliances in 82 territorial units corresponding to countries, large islands, archipelagos and peninsulas. We subdivided the mainland parts of large or biogeographically heterogeneous countries based on the European biogeographical regions. Specialized alliances of coastal habitats were mapped only for the coastal section of each territorial unit. Results Distribution maps were prepared for 1,105 alliances of vascular-plant dominated vegetation reported in the EuroVegChecklist. For each territorial unit, three levels of occurrence probability were plotted on the maps: (a) verified occurrence; (b) uncertain occurrence; and (c) absence. The maps of individual alliances were complemented by summary maps of the number of alliances and the alliance-area relationship. Distribution data are also provided in a spreadsheet. Conclusions The new map series represents the first attempt to characterize the distribution of all vegetation types at the alliance level across Europe. There are still many knowledge gaps, partly due to a lack of data for some regions and partly due to uncertainti

Published

2022

11. Distribution maps of vegetation alliances in Europe

Author

Preislerová, Zdenka, Jiménez‐Alfaro, Borja, Mucina, Ladislav, Berg, Christian, Bonari, Gianmaria, Kuzemko, Anna, Landucci, Flavia, Marcenò, Corrado, Monteiro‐Henriques, Tiago, Novák, Pavel, Vynokurov, Denys, Bergmeier, Erwin, Dengler, Jürgen, Apostolova, Iva, Bioret, Frederic, Biurrun, Idoia, Campos, Juan Antonio, Capelo, Jorge, Čarni, Andraž, Çoban, Süleyman, Csiky, János, Ćuk, Mirjana, Ćušterevska, Renata, Daniëls, Fred J.A., De Sanctis, Michele, Didukh, Yakiv, Dítě, Daniel, Fanelli, Giuliano, Golovanov, Yaroslav, Golub, Valentin, Guarino, Riccardo, Hájek, Michal, Iakushenko, Dmytro, Indreica, Adrian, Jansen, Florian, Jašková, Anni, Jiroušek, Martin, Kalníková, Veronika, Kavgacı, Ali, Kucherov, Ilya, Küzmič, Filip, Lebedeva, Maria, Loidi, Javier, Lososová, Zdeňka, Lysenko, Tatiana, Milanović, Đorđije, Onyshchenko, Viktor, Perrin, Gwenhael, Peterka, Tomáš, Rašomavičius, Valerijus, Rodríguez‐Rojo, María Pilar, Rodwell, John S., Rūsiņa, Solvita, Sánchez‐Mata, Daniel, Schaminée, Joop H.J., Semenishchenkov, Yuri, Shevchenko, Nikolay, Šibík, Jozef, Škvorc, Željko, Smagin, Viktor, Stešević, Danijela, Stupar, Vladimir, Šumberová, Kateřina, Theurillat, Jean‐Paul, Tikhonova, Elena, Tzonev, Rossen, Valachovič, Milan, Vassilev, Kiril, Willner, Wolfgang, Yamalov, Sergey, Večeřa, Martin, Chytrý, Milan, Preislerová, Zdenka, Jiménez‐Alfaro, Borja, Mucina, Ladislav, Berg, Christian, Bonari, Gianmaria, Kuzemko, Anna, Landucci, Flavia, Marcenò, Corrado, Monteiro‐Henriques, Tiago, Novák, Pavel, Vynokurov, Denys, Bergmeier, Erwin, Dengler, Jürgen, Apostolova, Iva, Bioret, Frederic, Biurrun, Idoia, Campos, Juan Antonio, Capelo, Jorge, Čarni, Andraž, Çoban, Süleyman, Csiky, János, Ćuk, Mirjana, Ćušterevska, Renata, Daniëls, Fred J.A., De Sanctis, Michele, Didukh, Yakiv, Dítě, Daniel, Fanelli, Giuliano, Golovanov, Yaroslav, Golub, Valentin, Guarino, Riccardo, Hájek, Michal, Iakushenko, Dmytro, Indreica, Adrian, Jansen, Florian, Jašková, Anni, Jiroušek, Martin, Kalníková, Veronika, Kavgacı, Ali, Kucherov, Ilya, Küzmič, Filip, Lebedeva, Maria, Loidi, Javier, Lososová, Zdeňka, Lysenko, Tatiana, Milanović, Đorđije, Onyshchenko, Viktor, Perrin, Gwenhael, Peterka, Tomáš, Rašomavičius, Valerijus, Rodríguez‐Rojo, María Pilar, Rodwell, John S., Rūsiņa, Solvita, Sánchez‐Mata, Daniel, Schaminée, Joop H.J., Semenishchenkov, Yuri, Shevchenko, Nikolay, Šibík, Jozef, Škvorc, Željko, Smagin, Viktor, Stešević, Danijela, Stupar, Vladimir, Šumberová, Kateřina, Theurillat, Jean‐Paul, Tikhonova, Elena, Tzonev, Rossen, Valachovič, Milan, Vassilev, Kiril, Willner, Wolfgang, Yamalov, Sergey, Večeřa, Martin, and Chytrý, Milan

Abstract

Aim: The first comprehensive checklist of European phytosociological alliances, orders and classes (EuroVegChecklist) was published by Mucina et al. (2016, Applied Vegetation Science, 19 (Suppl. 1), 3–264). However, this checklist did not contain detailed information on the distribution of individual vegetation types. Here we provide the first maps of all alliances in Europe. Location: Europe, Greenland, Canary Islands, Madeira, Azores, Cyprus and the Caucasus countries. Methods: We collected data on the occurrence of phytosociological alliances in European countries and regions from literature and vegetation-plot databases. We interpreted and complemented these data using the expert knowledge of an international team of vegetation scientists and matched all the previously reported alliance names and concepts with those of the EuroVegChecklist. We then mapped the occurrence of the EuroVegChecklist alliances in 82 territorial units corresponding to countries, large islands, archipelagos and peninsulas. We subdivided the mainland parts of large or biogeographically heterogeneous countries based on the European biogeographical regions. Specialized alliances of coastal habitats were mapped only for the coastal section of each territorial unit. Results: Distribution maps were prepared for 1,105 alliances of vascular-plant dominated vegetation reported in the EuroVegChecklist. For each territorial unit, three levels of occurrence probability were plotted on the maps: (a) verified occurrence; (b) uncertain occurrence; and (c) absence. The maps of individual alliances were complemented by summary maps of the number of alliances and the alliance–area relationship. Distribution data are also provided in a spreadsheet. Conclusions: The new map series represents the first attempt to characterize the distribution of all vegetation types at the alliance level across Europe. There are still many knowledge gaps, partly due to a lack of data for some regions and partly due to uncert

Published

2022

12. Explanation of beta diversity in European alpine grasslands changes with scale

Author

Malanson, George P., primary, Pansing, Elizabeth R., additional, Testolin, Riccardo, additional, Abdulhak, Sylvain, additional, Bergamini, Ariel, additional, Ćušterevska, Renata, additional, Marcenò, Corrado, additional, Kuzmanović, Nevena, additional, Milanović, Đorđije, additional, Ruprecht, Eszter, additional, Šibík, Jozef, additional, Vassilev, Kiril, additional, Willner, Wolfgang, additional, and Jiménez‐Alfaro, Borja, additional

Published

2022

13. Distribution maps of vegetation alliances in Europe

Author

Preislerová, Zdenka, primary, Jiménez‐Alfaro, Borja, additional, Mucina, Ladislav, additional, Berg, Christian, additional, Bonari, Gianmaria, additional, Kuzemko, Anna, additional, Landucci, Flavia, additional, Marcenò, Corrado, additional, Monteiro‐Henriques, Tiago, additional, Novák, Pavel, additional, Vynokurov, Denys, additional, Bergmeier, Erwin, additional, Dengler, Jürgen, additional, Apostolova, Iva, additional, Bioret, Frederic, additional, Biurrun, Idoia, additional, Campos, Juan Antonio, additional, Capelo, Jorge, additional, Čarni, Andraž, additional, Çoban, Süleyman, additional, Csiky, János, additional, Ćuk, Mirjana, additional, Ćušterevska, Renata, additional, Daniëls, Fred J.A., additional, De Sanctis, Michele, additional, Didukh, Yakiv, additional, Dítě, Daniel, additional, Fanelli, Giuliano, additional, Golovanov, Yaroslav, additional, Golub, Valentin, additional, Guarino, Riccardo, additional, Hájek, Michal, additional, Iakushenko, Dmytro, additional, Indreica, Adrian, additional, Jansen, Florian, additional, Jašková, Anni, additional, Jiroušek, Martin, additional, Kalníková, Veronika, additional, Kavgacı, Ali, additional, Kucherov, Ilya, additional, Küzmič, Filip, additional, Lebedeva, Maria, additional, Loidi, Javier, additional, Lososová, Zdeňka, additional, Lysenko, Tatiana, additional, Milanović, Đorđije, additional, Onyshchenko, Viktor, additional, Perrin, Gwenhael, additional, Peterka, Tomáš, additional, Rašomavičius, Valerijus, additional, Rodríguez‐Rojo, María Pilar, additional, Rodwell, John S., additional, Rūsiņa, Solvita, additional, Sánchez‐Mata, Daniel, additional, Schaminée, Joop H.J., additional, Semenishchenkov, Yuri, additional, Shevchenko, Nikolay, additional, Šibík, Jozef, additional, Škvorc, Željko, additional, Smagin, Viktor, additional, Stešević, Danijela, additional, Stupar, Vladimir, additional, Šumberová, Kateřina, additional, Theurillat, Jean‐Paul, additional, Tikhonova, Elena, additional, Tzonev, Rossen, additional, Valachovič, Milan, additional, Vassilev, Kiril, additional, Willner, Wolfgang, additional, Yamalov, Sergey, additional, Večeřa, Martin, additional, and Chytrý, Milan, additional

Published

2022

14. Different Sets of Traits Explain Abundance and Distribution Patterns of European Plants at Different Spatial Scales

Author

Biología vegetal y ecología, Landaren biologia eta ekologia, Sporbert, Maria, Welk, Erik, Seidler, Gunnar, Jandt, Ute, Aćić, Svetlana, Biurrun Galarraga, Miren Idoia, Campos Prieto, Juan Antonio, Čarni, Andraž, Cerabolini, Bruno E. L., Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, De Sanctis, Michele, Dziuba, Tetiana, Fagúndez, Jaime, Field, Richard, Golub, Valentin, He, Tianhua, Jansen, Florian, Lenoir, Jonathan, Marcenò, Corrado, Martín Forés, Irene, Moeslund, Jesper Erenskjold, Moretti, Marco, Niinemets, Ü., Peñuelas, J., Pérez Haase, Aarón, Vandvik, Vigdis, Vassilev, Kiril, Vynokurov, Denys, Bruelheide, Helge, Biología vegetal y ecología, Landaren biologia eta ekologia, Sporbert, Maria, Welk, Erik, Seidler, Gunnar, Jandt, Ute, Aćić, Svetlana, Biurrun Galarraga, Miren Idoia, Campos Prieto, Juan Antonio, Čarni, Andraž, Cerabolini, Bruno E. L., Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, De Sanctis, Michele, Dziuba, Tetiana, Fagúndez, Jaime, Field, Richard, Golub, Valentin, He, Tianhua, Jansen, Florian, Lenoir, Jonathan, Marcenò, Corrado, Martín Forés, Irene, Moeslund, Jesper Erenskjold, Moretti, Marco, Niinemets, Ü., Peñuelas, J., Pérez Haase, Aarón, Vandvik, Vigdis, Vassilev, Kiril, Vynokurov, Denys, and Bruelheide, Helge

Abstract

Aim Plant functional traits summarize the main variability in plant form and function across taxa and biomes. We assess whether geographic range size, climatic niche size, and local abundance of plants can be predicted by sets of traits (trait syndromes) or are driven by single traits. Location Eurasia. Methods Species distribution maps were extracted from the Chorological Database Halle to derive information on the geographic range size and climatic niche size for 456 herbaceous, dwarf shrub and shrub species. We estimated local species abundances based on 740,113 vegetation plots from the European Vegetation Archive, where abundances were available as plant species cover per plot. We compiled a complete species-by-trait matrix of 20 plant functional traits from trait databases (TRY, BiolFlor and CLO-PLA). The relationships of species' geographic range size, climatic niche size and local abundance with single traits and trait syndromes were tested with multiple linear regression models. Results Generally, traits were more strongly related to local abundances than to broad-scale species distribution patterns in geographic and climatic space (range and niche size), but both were better predicted by trait combinations than by single traits. Local abundance increased with leaf area and specific leaf area (SLA). Geographic range size and climatic niche size both increased with SLA. While range size increased with plant height, niche size decreased with leaf carbon content. Conclusion Functional traits matter for species' abundance and distribution at both local and broad geographic scale. Local abundances are associated with different combinations of traits as compared to broad-scale distributions, pointing to filtering by different environmental and ecological factors acting at distinct spatial scales. However, traits related to the leaf economics spectrum were important for species' abundance and occurrence at both spatial scales. This finding emphasizes the general i

Published

2021

15. Mapping species richness of plant families in European vegetation

Author

Večeřa, Martin, Axmanová, Irena, Padullés Cubino, Josep, Lososová, Zdeňka, Divíšek, Jan, Knollová, Ilona, Aćić, Svetlana, Biurrun, Idoia, Boch, Steffen, Bonari, Gianmaria, Campos, Juan Antonio, Čarni, Andraž, Carranza, Maria Laura, Casella, Laura, Chiarucci, Alessandro, Ćušterevska, Renata, Delbosc, Pauline, Dengler, Jürgen, Fernández‐González, Federico, Gégout, Jean‐Claude, Jandt, Ute, Jansen, Florian, Jašková, Anni, Jiménez‐Alfaro, Borja, Kuzemko, Anna, Lebedeva, Maria, Lenoir, Jonathan, Lysenko, Tatiana, Moeslund, Jesper Erenskjold, Pielech, Remigiusz, Ruprecht, Eszter, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Swacha, Grzegorz, Tatarenko, Irina, Vassilev, Kiril, Wohlgemuth, Thomas, Yamalov, Sergey, Chytrý, Milan, Večeřa, Martin, Axmanová, Irena, Padullés Cubino, Josep, Lososová, Zdeňka, Divíšek, Jan, Knollová, Ilona, Aćić, Svetlana, Biurrun, Idoia, Boch, Steffen, Bonari, Gianmaria, Campos, Juan Antonio, Čarni, Andraž, Carranza, Maria Laura, Casella, Laura, Chiarucci, Alessandro, Ćušterevska, Renata, Delbosc, Pauline, Dengler, Jürgen, Fernández‐González, Federico, Gégout, Jean‐Claude, Jandt, Ute, Jansen, Florian, Jašková, Anni, Jiménez‐Alfaro, Borja, Kuzemko, Anna, Lebedeva, Maria, Lenoir, Jonathan, Lysenko, Tatiana, Moeslund, Jesper Erenskjold, Pielech, Remigiusz, Ruprecht, Eszter, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Swacha, Grzegorz, Tatarenko, Irina, Vassilev, Kiril, Wohlgemuth, Thomas, Yamalov, Sergey, and Chytrý, Milan

Abstract

Aims: Biodiversity is traditionally studied mostly at the species level, but biogeographical and macroecological studies at higher taxonomic levels can provide valuable insights into the evolutionary processes at large spatial scales. Our aim was to assess the representation of vascular plant families within different vegetation formations across Europe. Location: Europe. Methods: We used a data set of 816,005 vegetation plots from the European Vegetation Archive (EVA). For each plot, we calculated the relative species richness of each plant family as the number of species belonging to that family divided by the total number of species. We mapped the relative species richness, averaged across all plots in 50 km × 50 km grid cells, for each family and broad habitat groups: forests, grasslands, scrub and wetlands. We also calculated the absolute species richness and the Shannon diversity index for each family. Results: We produced 522 maps of mean relative species richness for a total of 152 vascular plant families occurring in forests, grasslands, scrub and wetlands. We found distinct spatial patterns for many combinations of families and habitat groups. The resulting series of 522 maps is freely available, both as images and GIS layers. Conclusions: The distinct spatial patterns revealed in the maps suggest that the relative species richness of plant families at the community level reflects the evolutionary history of individual families. We believe that the maps and associated data can inspire further biogeographical and macroecological studies and strengthen the ongoing integration of phylogenetic, functional and taxonomic diversity concepts.

Published

2021

16. Climate and socio‐economic factors explain differences between observed and expected naturalization patterns of European plants around the world

Author

Pouteau, Robin, Thuiller, Wilfried, Hobohm, Carsten, Brunel, Caroline, Conn, Barry J., Dawson, Wayne, Sá Dechoum, Michele, Ebel, Aleksandr L., Essl, Franz, Fragman‐Sapir, Ori, Fristoe, Trevor, Jogan, Nejc, Kreft, Holger, Lenzner, Bernd, Meyer, Carsten, Pergl, Jan, Pyšek, Petr, Verkhozina, Alla, Weigelt, Patrick, Yang, Qiang, Zykova, Elena, Aćić, Svetlana, Agrillo, Emiliano, Attorre, Fabio, Bergamini, Ariel, Berg, Christian, Bergmeier, Erwin, Biurrun, Idoia, Boch, Steffen, Bonari, Gianmaria, Botta‐Dukát, Zoltán, Bruelheide, Helge, Campos, Juan Antonio, Čarni, Andraž, Casella, Laura, Carranza, Maria Laura, Chytrý, Milan, Ćušterevska, Renata, De Sanctis, Michele, Dengler, Jürgen, Dimopoulos, Panayotis, Ejrnæs, Rasmus, Ewald, Jörg, Fanelli, Giuliano, Fernández‐González, Federico, Gavilán, Rosario G., Gegout, Jean‐Claude, Haveman, Rense, Isermann, Maike, Jandt, Ute, Jansen, Florian, Jiménez‐Alfaro, Borja, Kavgacı, Ali, Khanina, Larisa, Knollová, Ilona, Kuzemko, Anna, Lebedeva, Maria, Lenoir, Jonathan, Lysenko, Tatiana, Marcenò, Corrado, Martynenko, Vasiliy, Moeslund, Jesper Erenskjold, Pätsch, Ricarda, Pielech, Remigiusz, Rašomavičius, Valerijus, de Ronde, Iris, Ruprecht, Eszter, Rūsiņa, Solvita, Shirokikh, Pavel, Šibík, Jozef, Šilc, Urban, Stanisci, Angela, Stančić, Zvjezdana, Svenning, Jens‐Christian, Swacha, Grzegorz, Dan Turtureanu, Pavel, Valachovič, Milan, Vassilev, Kiril, Yamalov, Sergey, van Kleunen, Mark, Pouteau, Robin, Thuiller, Wilfried, Hobohm, Carsten, Brunel, Caroline, Conn, Barry J., Dawson, Wayne, Sá Dechoum, Michele, Ebel, Aleksandr L., Essl, Franz, Fragman‐Sapir, Ori, Fristoe, Trevor, Jogan, Nejc, Kreft, Holger, Lenzner, Bernd, Meyer, Carsten, Pergl, Jan, Pyšek, Petr, Verkhozina, Alla, Weigelt, Patrick, Yang, Qiang, Zykova, Elena, Aćić, Svetlana, Agrillo, Emiliano, Attorre, Fabio, Bergamini, Ariel, Berg, Christian, Bergmeier, Erwin, Biurrun, Idoia, Boch, Steffen, Bonari, Gianmaria, Botta‐Dukát, Zoltán, Bruelheide, Helge, Campos, Juan Antonio, Čarni, Andraž, Casella, Laura, Carranza, Maria Laura, Chytrý, Milan, Ćušterevska, Renata, De Sanctis, Michele, Dengler, Jürgen, Dimopoulos, Panayotis, Ejrnæs, Rasmus, Ewald, Jörg, Fanelli, Giuliano, Fernández‐González, Federico, Gavilán, Rosario G., Gegout, Jean‐Claude, Haveman, Rense, Isermann, Maike, Jandt, Ute, Jansen, Florian, Jiménez‐Alfaro, Borja, Kavgacı, Ali, Khanina, Larisa, Knollová, Ilona, Kuzemko, Anna, Lebedeva, Maria, Lenoir, Jonathan, Lysenko, Tatiana, Marcenò, Corrado, Martynenko, Vasiliy, Moeslund, Jesper Erenskjold, Pätsch, Ricarda, Pielech, Remigiusz, Rašomavičius, Valerijus, de Ronde, Iris, Ruprecht, Eszter, Rūsiņa, Solvita, Shirokikh, Pavel, Šibík, Jozef, Šilc, Urban, Stanisci, Angela, Stančić, Zvjezdana, Svenning, Jens‐Christian, Swacha, Grzegorz, Dan Turtureanu, Pavel, Valachovič, Milan, Vassilev, Kiril, Yamalov, Sergey, and van Kleunen, Mark

Abstract

Aim: The number of naturalized (i.e. established) alien species has increased rapidly over recent centuries. Given the differences in environmental tolerances among species, little is known about what factors determine the extent to which the observed size of the naturalized range of a species and hence the extent to which the observed richness of naturalized species of a region approach their full potential. Here, we asked which region-and species-specific characteristics explain differences between observed and expected naturalizations. Location: Global. Time period: Present. Major taxa studied: Vascular plants. Methods: We determined the observed naturalized distribution outside Europe for 1,485 species endemic to Europe using the Global Naturalized Alien Flora (GloNAF) database and their expected distributions outside Europe using species distribution models. First, we investigated which of seven socio-economic factors related to introduction pathways, anthropogenic pressures and inventory effort best explained the differences between observed and expected naturalized European floras. Second, we examined whether distributional features, economic use and functional traits explain the extent to which species have filled their expected ranges outside Europe. Results: In terms of suitable area, more than 95% of expected naturalizations of European plants were not yet observed. Species were naturalized in only 4.2% of their suitable regions outside of Europe (range filling) and in 0.4% of their unsuitable regions (range expansion). Anthropogenic habitat disturbance primarily explained the difference between observed and expected naturalized European floras, as did the number of treaties relevant to invasive species. Species of ornamental and economic value and with large specific leaf area performed better at filling and expanding beyond their expected range. Main conclusions: The naturalization of alien plant species is explained by climate matching but also by the

Published

2021

17. sPlotOpen : an environmentally balanced, open‐access, global dataset of vegetation plots

Author

Sabatini, Francesco Maria, Lenoir, Jonathan, Hattab, Tarek, Arnst, Elise Aimee, Chytrý, Milan, Dengler, Jürgen, De Ruffray, Patrice, Hennekens, Stephan M., Jandt, Ute, Jansen, Florian, Jiménez‐Alfaro, Borja, Kattge, Jens, Levesley, Aurora, Pillar, Valério D., Purschke, Oliver, Sandel, Brody, Sultana, Fahmida, Aavik, Tsipe, Aćić, Svetlana, Acosta, Alicia T. R., Agrillo, Emiliano, Alvarez, Miguel, Apostolova, Iva, Arfin Khan, Mohammed A. S., Arroyo, Luzmila, Attorre, Fabio, Aubin, Isabelle, Banerjee, Arindam, Bauters, Marijn, Bergeron, Yves, Bergmeier, Erwin, Biurrun, Idoia, Bjorkman, Anne D., Bonari, Gianmaria, Bondareva, Viktoria, Brunet, Jörg, Čarni, Andraž, Casella, Laura, Cayuela, Luis, Černý, Tomáš, Chepinoga, Victor, Csiky, János, Ćušterevska, Renata, De Bie, Els, Gasper, André Luis, De Sanctis, Michele, Dimopoulos, Panayotis, Dolezal, Jiri, Dziuba, Tetiana, El‐Sheikh, Mohamed Abd El‐Rouf Mousa, Enquist, Brian, Ewald, Jörg, Fazayeli, Farideh, Field, Richard, Finckh, Manfred, Gachet, Sophie, Galán‐de‐Mera, Antonio, Garbolino, Emmanuel, Gholizadeh, Hamid, Giorgis, Melisa, Golub, Valentin, Alsos, Inger Greve, Grytnes, John‐Arvid, Guerin, Gregory Richard, Gutiérrez, Alvaro G., Haider, Sylvia, Hatim, Mohamed Z., Hérault, Bruno, Hinojos Mendoza, Guillermo, Hölzel, Norbert, Homeier, Jürgen, Hubau, Wannes, Indreica, Adrian, Janssen, John A. M., Jedrzejek, Birgit, Jentsch, Anke, Jürgens, Norbert, Kącki, Zygmunt, Kapfer, Jutta, Karger, Dirk Nikolaus, Kavgacı, Ali, Kearsley, Elizabeth, Kessler, Michael, Khanina, Larisa, Killeen, Timothy, Korolyuk, Andrey, Kreft, Holger, Kühl, Hjalmar S., Kuzemko, Anna, Landucci, Flavia, Lengyel, Attila, Lens, Frederic, Lingner, Débora Vanessa, Liu, Hongyan, Lysenko, Tatiana, Mahecha, Miguel D., Marcenò, Corrado, Martynenko, Vasiliy, Moeslund, Jesper Erenskjold, Monteagudo Mendoza, Abel, Mucina, Ladislav, Müller, Jonas V., Munzinger, Jérôme, Naqinezhad, Alireza, Noroozi, Jalil, Nowak, Arkadiusz, Onyshchenko, Viktor, Overbeck, Gerhard E., Pärtel, Meelis, Pauchard, Aníbal, Peet, Robert K., Peñuelas, Josep, Pérez‐Haase, Aaron, Peterka, Tomáš, Petřík, Petr, Peyre, Gwendolyn, Phillips, Oliver L., Prokhorov, Vadim, Rašomavičius, Valerijus, Revermann, Rasmus, Rivas‐Torres, Gonzalo, Rodwell, John S., Ruprecht, Eszter, Rūsiņa, Solvita, Samimi, Cyrus, Schmidt, Marco, Schrodt, Franziska, Shan, Hanhuai, Shirokikh, Pavel, Šibík, Jozef, Šilc, Urban, Sklenář, Petr, Škvorc, Željko, Sparrow, Ben, Sperandii, Marta Gaia, Stančić, Zvjezdana, Svenning, Jens‐Christian, Tang, Zhiyao, Tang, Cindy Q., Tsiripidis, Ioannis, Vanselow, Kim André, Vásquez Martínez, Rodolfo, Vassilev, Kiril, Vélez‐Martin, Eduardo, Venanzoni, Roberto, Vibrans, Alexander Christian, Violle, Cyrille, Virtanen, Risto, Wehrden, Henrik, Wagner, Viktoria, Walker, Donald A., Waller, Donald M., Wang, Hua‐Feng, Wesche, Karsten, Whitfeld, Timothy J. S., Willner, Wolfgang, Wiser, Susan K., Wohlgemuth, Thomas, Yamalov, Sergey, Zobel, Martin, Bruelheide, Helge, Sabatini, Francesco Maria, Lenoir, Jonathan, Hattab, Tarek, Arnst, Elise Aimee, Chytrý, Milan, Dengler, Jürgen, De Ruffray, Patrice, Hennekens, Stephan M., Jandt, Ute, Jansen, Florian, Jiménez‐Alfaro, Borja, Kattge, Jens, Levesley, Aurora, Pillar, Valério D., Purschke, Oliver, Sandel, Brody, Sultana, Fahmida, Aavik, Tsipe, Aćić, Svetlana, Acosta, Alicia T. R., Agrillo, Emiliano, Alvarez, Miguel, Apostolova, Iva, Arfin Khan, Mohammed A. S., Arroyo, Luzmila, Attorre, Fabio, Aubin, Isabelle, Banerjee, Arindam, Bauters, Marijn, Bergeron, Yves, Bergmeier, Erwin, Biurrun, Idoia, Bjorkman, Anne D., Bonari, Gianmaria, Bondareva, Viktoria, Brunet, Jörg, Čarni, Andraž, Casella, Laura, Cayuela, Luis, Černý, Tomáš, Chepinoga, Victor, Csiky, János, Ćušterevska, Renata, De Bie, Els, Gasper, André Luis, De Sanctis, Michele, Dimopoulos, Panayotis, Dolezal, Jiri, Dziuba, Tetiana, El‐Sheikh, Mohamed Abd El‐Rouf Mousa, Enquist, Brian, Ewald, Jörg, Fazayeli, Farideh, Field, Richard, Finckh, Manfred, Gachet, Sophie, Galán‐de‐Mera, Antonio, Garbolino, Emmanuel, Gholizadeh, Hamid, Giorgis, Melisa, Golub, Valentin, Alsos, Inger Greve, Grytnes, John‐Arvid, Guerin, Gregory Richard, Gutiérrez, Alvaro G., Haider, Sylvia, Hatim, Mohamed Z., Hérault, Bruno, Hinojos Mendoza, Guillermo, Hölzel, Norbert, Homeier, Jürgen, Hubau, Wannes, Indreica, Adrian, Janssen, John A. M., Jedrzejek, Birgit, Jentsch, Anke, Jürgens, Norbert, Kącki, Zygmunt, Kapfer, Jutta, Karger, Dirk Nikolaus, Kavgacı, Ali, Kearsley, Elizabeth, Kessler, Michael, Khanina, Larisa, Killeen, Timothy, Korolyuk, Andrey, Kreft, Holger, Kühl, Hjalmar S., Kuzemko, Anna, Landucci, Flavia, Lengyel, Attila, Lens, Frederic, Lingner, Débora Vanessa, Liu, Hongyan, Lysenko, Tatiana, Mahecha, Miguel D., Marcenò, Corrado, Martynenko, Vasiliy, Moeslund, Jesper Erenskjold, Monteagudo Mendoza, Abel, Mucina, Ladislav, Müller, Jonas V., Munzinger, Jérôme, Naqinezhad, Alireza, Noroozi, Jalil, Nowak, Arkadiusz, Onyshchenko, Viktor, Overbeck, Gerhard E., Pärtel, Meelis, Pauchard, Aníbal, Peet, Robert K., Peñuelas, Josep, Pérez‐Haase, Aaron, Peterka, Tomáš, Petřík, Petr, Peyre, Gwendolyn, Phillips, Oliver L., Prokhorov, Vadim, Rašomavičius, Valerijus, Revermann, Rasmus, Rivas‐Torres, Gonzalo, Rodwell, John S., Ruprecht, Eszter, Rūsiņa, Solvita, Samimi, Cyrus, Schmidt, Marco, Schrodt, Franziska, Shan, Hanhuai, Shirokikh, Pavel, Šibík, Jozef, Šilc, Urban, Sklenář, Petr, Škvorc, Željko, Sparrow, Ben, Sperandii, Marta Gaia, Stančić, Zvjezdana, Svenning, Jens‐Christian, Tang, Zhiyao, Tang, Cindy Q., Tsiripidis, Ioannis, Vanselow, Kim André, Vásquez Martínez, Rodolfo, Vassilev, Kiril, Vélez‐Martin, Eduardo, Venanzoni, Roberto, Vibrans, Alexander Christian, Violle, Cyrille, Virtanen, Risto, Wehrden, Henrik, Wagner, Viktoria, Walker, Donald A., Waller, Donald M., Wang, Hua‐Feng, Wesche, Karsten, Whitfeld, Timothy J. S., Willner, Wolfgang, Wiser, Susan K., Wohlgemuth, Thomas, Yamalov, Sergey, Zobel, Martin, and Bruelheide, Helge

Abstract

Motivation: Assessing biodiversity status and trends in plant communities is critical for understanding, quantifying and predicting the effects of global change on ecosystems. Vegetation plots record the occurrence or abundance of all plant species co-occurring within delimited local areas. This allows species absences to be inferred, information seldom provided by existing global plant datasets. Although many vegetation plots have been recorded, most are not available to the global research community. A recent initiative, called ‘sPlot’, compiled the first global vegetation plot database, and continues to grow and curate it. The sPlot database, however, is extremely unbalanced spatially and environmentally, and is not open-access. Here, we address both these issues by (a) resampling the vegetation plots using several environmental variables as sampling strata and (b) securing permission from data holders of 105 local-to-regional datasets to openly release data. We thus present sPlotOpen, the largest open-access dataset of vegetation plots ever released. sPlotOpen can be used to explore global diversity at the plant community level, as ground truth data in remote sensing applications, or as a baseline for biodiversity monitoring. Main types of variable contained: Vegetation plots (n = 95,104) recording cover or abundance of naturally co-occurring vascular plant species within delimited areas. sPlotOpen contains three partially overlapping resampled datasets (c. 50,000 plots each), to be used as replicates in global analyses. Besides geographical location, date, plot size, biome, elevation, slope, aspect, vegetation type, naturalness, coverage of various vegetation layers, and source dataset, plot-level data also include community-weighted means and variances of 18 plant functional traits from the TRY Plant Trait Database. Spatial location and grain: Global, 0.01–40,000 m². Time period and grain: 1888–2015, recording dates. Major taxa and level of measurement: 42,677

Published

2021

18. Different sets of traits explain abundance and distribution patterns of European plants at different spatial scales

Author

Sporbert, Maria, Welk, Erik, Seidler, Gunnar, Jandt, Ute, Aćić, Svetlana, Biurrun, Idoia, Campos, Juan Antonio, Čarni, Andraž, Cerabolini, Bruno E. L., Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, De Sanctis, Michele, Dziuba, Tetiana, Fagúndez, Jaime, Field, Richard, Golub, Valentin, He, Tianhua, Jansen, Florian, Lenoir, Jonathan, Marcenò, Corrado, Martín‐Forés, Irene, Moeslund, Jesper Erenskjold, Moretti, Marco, Niinemets, Ülo, Penuelas, Josep, Pérez‐Haase, Aaron, Vandvik, Vigdis, Vassilev, Kiril, Vynokurov, Denys, Bruelheide, Helge, Sporbert, Maria, Welk, Erik, Seidler, Gunnar, Jandt, Ute, Aćić, Svetlana, Biurrun, Idoia, Campos, Juan Antonio, Čarni, Andraž, Cerabolini, Bruno E. L., Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, De Sanctis, Michele, Dziuba, Tetiana, Fagúndez, Jaime, Field, Richard, Golub, Valentin, He, Tianhua, Jansen, Florian, Lenoir, Jonathan, Marcenò, Corrado, Martín‐Forés, Irene, Moeslund, Jesper Erenskjold, Moretti, Marco, Niinemets, Ülo, Penuelas, Josep, Pérez‐Haase, Aaron, Vandvik, Vigdis, Vassilev, Kiril, Vynokurov, Denys, and Bruelheide, Helge

Abstract

Aim: Plant functional traits summarize the main variability in plant form and function across taxa and biomes. We assess whether geographic range size, climatic niche size, and local abundance of plants can be predicted by sets of traits (trait syndromes) or are driven by single traits. Location: Eurasia. Methods: Species distribution maps were extracted from the Chorological Database Halle to derive information on the geographic range size and climatic niche size for 456 herbaceous, dwarf shrub and shrub species. We estimated local species abundances based on 740,113 vegetation plots from the European Vegetation Archive, where abundances were available as plant species cover per plot. We compiled a complete species-by-trait matrix of 20 plant functional traits from trait databases (TRY, BiolFlor and CLO-PLA). The relationships of species’ geographic range size, climatic niche size and local abundance with single traits and trait syndromes were tested with multiple linear regression models. Results: Generally, traits were more strongly related to local abundances than to broad-scale species distribution patterns in geographic and climatic space (range and niche size), but both were better predicted by trait combinations than by single traits. Local abundance increased with leaf area and specific leaf area (SLA). Geographic range size and climatic niche size both increased with SLA. While range size increased with plant height, niche size decreased with leaf carbon content. Conclusion: Functional traits matter for species’ abundance and distribution at both local and broad geographic scale. Local abundances are associated with different combinations of traits as compared to broad-scale distributions, pointing to filtering by different environmental and ecological factors acting at distinct spatial scales. However, traits related to the leaf economics spectrum were important for species’ abundance and occurrence at both spatial scales. This finding emphasizes the gene

Published

2021

19. sPlotOpen – An environmentally balanced, open‐access, global dataset of vegetation plots

Author

Sabatini, Francesco Maria, primary, Lenoir, Jonathan, additional, Hattab, Tarek, additional, Arnst, Elise Aimee, additional, Chytrý, Milan, additional, Dengler, Jürgen, additional, De Ruffray, Patrice, additional, Hennekens, Stephan M., additional, Jandt, Ute, additional, Jansen, Florian, additional, Jiménez‐Alfaro, Borja, additional, Kattge, Jens, additional, Levesley, Aurora, additional, Pillar, Valério D., additional, Purschke, Oliver, additional, Sandel, Brody, additional, Sultana, Fahmida, additional, Aavik, Tsipe, additional, Aćić, Svetlana, additional, Acosta, Alicia T. R., additional, Agrillo, Emiliano, additional, Alvarez, Miguel, additional, Apostolova, Iva, additional, Arfin Khan, Mohammed A. S., additional, Arroyo, Luzmila, additional, Attorre, Fabio, additional, Aubin, Isabelle, additional, Banerjee, Arindam, additional, Bauters, Marijn, additional, Bergeron, Yves, additional, Bergmeier, Erwin, additional, Biurrun, Idoia, additional, Bjorkman, Anne D., additional, Bonari, Gianmaria, additional, Bondareva, Viktoria, additional, Brunet, Jörg, additional, Čarni, Andraž, additional, Casella, Laura, additional, Cayuela, Luis, additional, Černý, Tomáš, additional, Chepinoga, Victor, additional, Csiky, János, additional, Ćušterevska, Renata, additional, De Bie, Els, additional, Gasper, André Luis, additional, De Sanctis, Michele, additional, Dimopoulos, Panayotis, additional, Dolezal, Jiri, additional, Dziuba, Tetiana, additional, El‐Sheikh, Mohamed Abd El‐Rouf Mousa, additional, Enquist, Brian, additional, Ewald, Jörg, additional, Fazayeli, Farideh, additional, Field, Richard, additional, Finckh, Manfred, additional, Gachet, Sophie, additional, Galán‐de‐Mera, Antonio, additional, Garbolino, Emmanuel, additional, Gholizadeh, Hamid, additional, Giorgis, Melisa, additional, Golub, Valentin, additional, Alsos, Inger Greve, additional, Grytnes, John‐Arvid, additional, Guerin, Gregory Richard, additional, Gutiérrez, Alvaro G., additional, Haider, Sylvia, additional, Hatim, Mohamed Z., additional, Hérault, Bruno, additional, Hinojos Mendoza, Guillermo, additional, Hölzel, Norbert, additional, Homeier, Jürgen, additional, Hubau, Wannes, additional, Indreica, Adrian, additional, Janssen, John A. M., additional, Jedrzejek, Birgit, additional, Jentsch, Anke, additional, Jürgens, Norbert, additional, Kącki, Zygmunt, additional, Kapfer, Jutta, additional, Karger, Dirk Nikolaus, additional, Kavgacı, Ali, additional, Kearsley, Elizabeth, additional, Kessler, Michael, additional, Khanina, Larisa, additional, Killeen, Timothy, additional, Korolyuk, Andrey, additional, Kreft, Holger, additional, Kühl, Hjalmar S., additional, Kuzemko, Anna, additional, Landucci, Flavia, additional, Lengyel, Attila, additional, Lens, Frederic, additional, Lingner, Débora Vanessa, additional, Liu, Hongyan, additional, Lysenko, Tatiana, additional, Mahecha, Miguel D., additional, Marcenò, Corrado, additional, Martynenko, Vasiliy, additional, Moeslund, Jesper Erenskjold, additional, Monteagudo Mendoza, Abel, additional, Mucina, Ladislav, additional, Müller, Jonas V., additional, Munzinger, Jérôme, additional, Naqinezhad, Alireza, additional, Noroozi, Jalil, additional, Nowak, Arkadiusz, additional, Onyshchenko, Viktor, additional, Overbeck, Gerhard E., additional, Pärtel, Meelis, additional, Pauchard, Aníbal, additional, Peet, Robert K., additional, Peñuelas, Josep, additional, Pérez‐Haase, Aaron, additional, Peterka, Tomáš, additional, Petřík, Petr, additional, Peyre, Gwendolyn, additional, Phillips, Oliver L., additional, Prokhorov, Vadim, additional, Rašomavičius, Valerijus, additional, Revermann, Rasmus, additional, Rivas‐Torres, Gonzalo, additional, Rodwell, John S., additional, Ruprecht, Eszter, additional, Rūsiņa, Solvita, additional, Samimi, Cyrus, additional, Schmidt, Marco, additional, Schrodt, Franziska, additional, Shan, Hanhuai, additional, Shirokikh, Pavel, additional, Šibík, Jozef, additional, Šilc, Urban, additional, Sklenář, Petr, additional, Škvorc, Željko, additional, Sparrow, Ben, additional, Sperandii, Marta Gaia, additional, Stančić, Zvjezdana, additional, Svenning, Jens‐Christian, additional, Tang, Zhiyao, additional, Tang, Cindy Q., additional, Tsiripidis, Ioannis, additional, Vanselow, Kim André, additional, Vásquez Martínez, Rodolfo, additional, Vassilev, Kiril, additional, Vélez‐Martin, Eduardo, additional, Venanzoni, Roberto, additional, Vibrans, Alexander Christian, additional, Violle, Cyrille, additional, Virtanen, Risto, additional, Wehrden, Henrik, additional, Wagner, Viktoria, additional, Walker, Donald A., additional, Waller, Donald M., additional, Wang, Hua‐Feng, additional, Wesche, Karsten, additional, Whitfeld, Timothy J. S., additional, Willner, Wolfgang, additional, Wiser, Susan K., additional, Wohlgemuth, Thomas, additional, Yamalov, Sergey, additional, Zobel, Martin, additional, Bruelheide, Helge, additional, and Bates, Amanda, additional

Published

2021

20. Climate and socio‐economic factors explain differences between observed and expected naturalization patterns of European plants around the world

Author

Pouteau, Robin, primary, Thuiller, Wilfried, additional, Hobohm, Carsten, additional, Brunel, Caroline, additional, Conn, Barry J., additional, Dawson, Wayne, additional, Sá Dechoum, Michele, additional, Ebel, Aleksandr L., additional, Essl, Franz, additional, Fragman‐Sapir, Ori, additional, Fristoe, Trevor, additional, Jogan, Nejc, additional, Kreft, Holger, additional, Lenzner, Bernd, additional, Meyer, Carsten, additional, Pergl, Jan, additional, Pyšek, Petr, additional, Verkhozina, Alla, additional, Weigelt, Patrick, additional, Yang, Qiang, additional, Zykova, Elena, additional, Aćić, Svetlana, additional, Agrillo, Emiliano, additional, Attorre, Fabio, additional, Bergamini, Ariel, additional, Berg, Christian, additional, Bergmeier, Erwin, additional, Biurrun, Idoia, additional, Boch, Steffen, additional, Bonari, Gianmaria, additional, Botta‐Dukát, Zoltán, additional, Bruelheide, Helge, additional, Campos, Juan Antonio, additional, Čarni, Andraž, additional, Casella, Laura, additional, Carranza, Maria Laura, additional, Chytrý, Milan, additional, Ćušterevska, Renata, additional, De Sanctis, Michele, additional, Dengler, Jürgen, additional, Dimopoulos, Panayotis, additional, Ejrnæs, Rasmus, additional, Ewald, Jörg, additional, Fanelli, Giuliano, additional, Fernández‐González, Federico, additional, Gavilán, Rosario G., additional, Gegout, Jean‐Claude, additional, Haveman, Rense, additional, Isermann, Maike, additional, Jandt, Ute, additional, Jansen, Florian, additional, Jiménez‐Alfaro, Borja, additional, Kavgacı, Ali, additional, Khanina, Larisa, additional, Knollová, Ilona, additional, Kuzemko, Anna, additional, Lebedeva, Maria, additional, Lenoir, Jonathan, additional, Lysenko, Tatiana, additional, Marcenò, Corrado, additional, Martynenko, Vasiliy, additional, Moeslund, Jesper Erenskjold, additional, Pätsch, Ricarda, additional, Pielech, Remigiusz, additional, Rašomavičius, Valerijus, additional, Ronde, Iris, additional, Ruprecht, Eszter, additional, Rūsiņa, Solvita, additional, Shirokikh, Pavel, additional, Šibík, Jozef, additional, Šilc, Urban, additional, Stanisci, Angela, additional, Stančić, Zvjezdana, additional, Svenning, Jens‐Christian, additional, Swacha, Grzegorz, additional, Dan Turtureanu, Pavel, additional, Valachovič, Milan, additional, Vassilev, Kiril, additional, Yamalov, Sergey, additional, and Kleunen, Mark, additional

Published

2021

21. Mapping species richness of plant families in European vegetation

Author

Večeřa, Martin, primary, Axmanová, Irena, additional, Padullés Cubino, Josep, additional, Lososová, Zdeňka, additional, Divíšek, Jan, additional, Knollová, Ilona, additional, Aćić, Svetlana, additional, Biurrun, Idoia, additional, Boch, Steffen, additional, Bonari, Gianmaria, additional, Campos, Juan Antonio, additional, Čarni, Andraž, additional, Carranza, Maria Laura, additional, Casella, Laura, additional, Chiarucci, Alessandro, additional, Ćušterevska, Renata, additional, Delbosc, Pauline, additional, Dengler, Jürgen, additional, Fernández‐González, Federico, additional, Gégout, Jean‐Claude, additional, Jandt, Ute, additional, Jansen, Florian, additional, Jašková, Anni, additional, Jiménez‐Alfaro, Borja, additional, Kuzemko, Anna, additional, Lebedeva, Maria, additional, Lenoir, Jonathan, additional, Lysenko, Tatiana, additional, Moeslund, Jesper Erenskjold, additional, Pielech, Remigiusz, additional, Ruprecht, Eszter, additional, Šibík, Jozef, additional, Šilc, Urban, additional, Škvorc, Željko, additional, Swacha, Grzegorz, additional, Tatarenko, Irina, additional, Vassilev, Kiril, additional, Wohlgemuth, Thomas, additional, Yamalov, Sergey, additional, and Chytrý, Milan, additional

Published

2021

22. EUNIS Habitat Classification: Expert system, characteristic species combinations and distribution maps of European habitats

Author

Biología vegetal y ecología, Landaren biologia eta ekologia, Chytrý, Milan, Tichý, Lubomír, Hennekens, Stephan M., Knollová, Ilona, Janssen, John A. M., Rodwell, John S., Peterka, Tomáš, Marcenò, Corrado, Landucci, Flavia, Danihelka, Jiří, Hájek, Michal, Dengler, Jürgen, Novák, Pavel, Zukal, Dominik, Jiménez Alfaro, Borja, Mucina, Ladislav, Abdulhak, Sylvain, Aćić, Svetlana, Agrillo, Emiliano, Attorre, Fabio, Bergmeier, Erwin, Biurrun Galarraga, Miren Idoia, Boch, Steffen, Bölöni, János, Bonari, Gianmaria, Braslavskaya, Tatiana, Bruelheide, Helge, Campos Prieto, Juan Antonio, Čarni, Andraž, Casella, Laura, Ćuk, Mirjana, Ćušterevska, Renata, De Bie, Els, Delbosc, Pauline, Demina, Olga, Didukh, Yakiv, Dítě, Daniel, Dziuba, Tetiana, Ewald, Jörg, Gavilán, Rosario G., Gégout, Jean Claude, Giusso del Galdo, Gian Pietro, Golub, Valentin, Goncharova, Nadezhda, Goral, Friedemann, Graf, Ulrich, Indreica, Adrian, Isermann, Maike, Jandt, Ute, Jansen, Florian, Jansen, Jan, Jašková, Anni, Jiroušek, Martin, Kącki, Zygmunt, Kalníková, Veronika, Kavgacı, Ali, Khanina, Larisa, Korolyuk, Andrey Yu., Kozhevnikova, Mariya, Kuzemko, Anna, Küzmič, Filip, Kuznetsov, Oleg L., Laiviņš, Māris, Lavrinenko, Igor, Lavrinenko, Olga, Lebedeva, Maria, Lososová, Zdeňka, Lysenko, Tatiana, Maciejewski, Lise, Mardari, Constantin, Marinšek, Aleksander, Napreenko, Maxim G., Onyshchenko, Viktor, Pérez Haase, Aaron, Pielech, Remigiusz, Prokhorov, Vadim, Rašomavičius, Valerijus, Rodríguez Rojo, Maria Pilar, Rūsiņa, Solvita, Schrautzer, Joachim, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Smagin, Viktor A., Stančić, Zvjezdana, Stanisci, Angela, Tikhonova, Elena, Tonteri, Tiina, Uogintas, Domas, Valachovič, Milan, Vassilev, Kiril, Vynokurov, Denys, Willner, Wolfgang, Yamalov, Sergey, Evans, Douglas, Palitzsch Lund, Mette, Spyropoulou, Rania, Tryfon, Eleni, Schaminée, Joop H. J., Biología vegetal y ecología, Landaren biologia eta ekologia, Chytrý, Milan, Tichý, Lubomír, Hennekens, Stephan M., Knollová, Ilona, Janssen, John A. M., Rodwell, John S., Peterka, Tomáš, Marcenò, Corrado, Landucci, Flavia, Danihelka, Jiří, Hájek, Michal, Dengler, Jürgen, Novák, Pavel, Zukal, Dominik, Jiménez Alfaro, Borja, Mucina, Ladislav, Abdulhak, Sylvain, Aćić, Svetlana, Agrillo, Emiliano, Attorre, Fabio, Bergmeier, Erwin, Biurrun Galarraga, Miren Idoia, Boch, Steffen, Bölöni, János, Bonari, Gianmaria, Braslavskaya, Tatiana, Bruelheide, Helge, Campos Prieto, Juan Antonio, Čarni, Andraž, Casella, Laura, Ćuk, Mirjana, Ćušterevska, Renata, De Bie, Els, Delbosc, Pauline, Demina, Olga, Didukh, Yakiv, Dítě, Daniel, Dziuba, Tetiana, Ewald, Jörg, Gavilán, Rosario G., Gégout, Jean Claude, Giusso del Galdo, Gian Pietro, Golub, Valentin, Goncharova, Nadezhda, Goral, Friedemann, Graf, Ulrich, Indreica, Adrian, Isermann, Maike, Jandt, Ute, Jansen, Florian, Jansen, Jan, Jašková, Anni, Jiroušek, Martin, Kącki, Zygmunt, Kalníková, Veronika, Kavgacı, Ali, Khanina, Larisa, Korolyuk, Andrey Yu., Kozhevnikova, Mariya, Kuzemko, Anna, Küzmič, Filip, Kuznetsov, Oleg L., Laiviņš, Māris, Lavrinenko, Igor, Lavrinenko, Olga, Lebedeva, Maria, Lososová, Zdeňka, Lysenko, Tatiana, Maciejewski, Lise, Mardari, Constantin, Marinšek, Aleksander, Napreenko, Maxim G., Onyshchenko, Viktor, Pérez Haase, Aaron, Pielech, Remigiusz, Prokhorov, Vadim, Rašomavičius, Valerijus, Rodríguez Rojo, Maria Pilar, Rūsiņa, Solvita, Schrautzer, Joachim, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Smagin, Viktor A., Stančić, Zvjezdana, Stanisci, Angela, Tikhonova, Elena, Tonteri, Tiina, Uogintas, Domas, Valachovič, Milan, Vassilev, Kiril, Vynokurov, Denys, Willner, Wolfgang, Yamalov, Sergey, Evans, Douglas, Palitzsch Lund, Mette, Spyropoulou, Rania, Tryfon, Eleni, and Schaminée, Joop H. J.

Abstract

Aim The EUNIS Habitat Classification is a widely used reference framework for European habitat types (habitats), but it lacks formal definitions of individual habitats that would enable their unequivocal identification. Our goal was to develop a tool for assigning vegetation-plot records to the habitats of the EUNIS system, use it to classify a European vegetation-plot database, and compile statistically-derived characteristic species combinations and distribution maps for these habitats. Location Europe. Methods We developed the classification expert system EUNIS-ESy, which contains definitions of individual EUNIS habitats based on their species composition and geographic location. Each habitat was formally defined as a formula in a computer language combining algebraic and set-theoretic concepts with formal logical operators. We applied this expert system to classify 1,261,373 vegetation plots from the European Vegetation Archive (EVA) and other databases. Then we determined diagnostic, constant and dominant species for each habitat by calculating species-to-habitat fidelity and constancy (occurrence frequency) in the classified data set. Finally, we mapped the plot locations for each habitat. Results Formal definitions were developed for 199 habitats at Level 3 of the EUNIS hierarchy, including 25 coastal, 18 wetland, 55 grassland, 43 shrubland, 46 forest and 12 man-made habitats. The expert system classified 1,125,121 vegetation plots to these habitat groups and 73,188 to other habitats, while 63,064 plots remained unclassified or were classified to more than one habitat. Data on each habitat were summarized in factsheets containing habitat description, distribution map, corresponding syntaxa and characteristic species combination. Conclusions EUNIS habitats were characterized for the first time in terms of their species composition and distribution, based on a classification of a European database of vegetation plots using the newly developed electronic expert

Published

2020

23. Testing macroecological abundance patterns: The relationship between local abundance and range size, range position and climatic suitability among European vascular plants

Author

Biología vegetal y ecología, Landaren biologia eta ekologia, Sporbert, Maria, Keil, Petr, Seidler, Gunnar, Bruelheide, Helge, Jandt, Ute, Aćić, Svetlana, Biurrun Galarraga, Miren Idoia, Campos Prieto, Juan Antonio, Čarni, Andraž, Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, Golub, Valentin, Jansen, Florian, Kuzemko, Ana, Lenoir, Jonathan, Marcenò, Corrado, Erenskjold Moeslund, Jesper, Pérez Haase, Aaron, Rūsiņa, Solvita, Šilc, Urban, Tsiripidris, Ioannis, Vandvik, Vigdis, Vasilev, Kiril, Virtanen, Risto, Welk, Erik, Biología vegetal y ecología, Landaren biologia eta ekologia, Sporbert, Maria, Keil, Petr, Seidler, Gunnar, Bruelheide, Helge, Jandt, Ute, Aćić, Svetlana, Biurrun Galarraga, Miren Idoia, Campos Prieto, Juan Antonio, Čarni, Andraž, Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, Golub, Valentin, Jansen, Florian, Kuzemko, Ana, Lenoir, Jonathan, Marcenò, Corrado, Erenskjold Moeslund, Jesper, Pérez Haase, Aaron, Rūsiņa, Solvita, Šilc, Urban, Tsiripidris, Ioannis, Vandvik, Vigdis, Vasilev, Kiril, Virtanen, Risto, and Welk, Erik

Abstract

Aim A fundamental question in macroecology centres around understanding the relationship between species' local abundance and their distribution in geographical and climatic space (i.e. the multi-dimensional climatic space or climatic niche). Here, we tested three macroecological hypotheses that link local abundance to the following range properties: (a) the abundance-range size relationship, (b) the abundance-range centre relationship and (c) the abundance-suitability relationship. Location Europe. Taxon Vascular plants. Methods Distribution range maps were extracted from the Chorological Database Halle to derive information on the range and niche sizes of 517 European vascular plant species. To estimate local abundance, we assessed samples from 744,513 vegetation plots in the European Vegetation Archive, where local species' abundance is available as plant cover per plot. We then calculated the 'centrality', that is, the distance between the location of the abundance observation and each species' range centre in geographical and climatic space. The climatic suitability of plot locations was estimated using coarse-grain species distribution models (SDMs). The relationships between centrality or climatic suitability with abundance was tested using linear models and quantile regression. We summarized the overall trend across species' regression slopes from linear models and quantile regression using a meta-analytical approach. Results We did not detect any positive relationships between a species' mean local abundance and the size of its geographical range or climatic niche. Contrasting yet significant correlations were detected between abundance and centrality or climatic suitability among species. Main conclusions Our results do not provide unequivocal support for any of the relationships tested, demonstrating that determining properties of species' distributions at large grains and extents might be of limited use for predicting local abundance, including current S

Published

2020

24. Testing macroecological abundance patterns : the relationship between local abundance and range size, range position and climatic suitability among European vascular plants

Author

Sporbert, Maria, Keil, Petr, Seidler, Gunnar, Bruelheide, Helge, Jandt, Ute, Aćić, Svetlana, Biurrun, Idoia, Campos, Juan Antonio, Čarni, Andraž, Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, Golub, Valentin, Jansen, Florian, Kuzemko, Anna, Lenoir, Jonathan, Marcenò, Corrado, Moeslund, Jesper Erenskjold, Pérez‐Haase, Aaron, Rūsiņa, Solvita, Šilc, Urban, Tsiripidris, Ioannis, Vandvik, Vigdis, Vasilev, Kiril, Virtanen, Risto, Welk, Erik, Sporbert, Maria, Keil, Petr, Seidler, Gunnar, Bruelheide, Helge, Jandt, Ute, Aćić, Svetlana, Biurrun, Idoia, Campos, Juan Antonio, Čarni, Andraž, Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, Golub, Valentin, Jansen, Florian, Kuzemko, Anna, Lenoir, Jonathan, Marcenò, Corrado, Moeslund, Jesper Erenskjold, Pérez‐Haase, Aaron, Rūsiņa, Solvita, Šilc, Urban, Tsiripidris, Ioannis, Vandvik, Vigdis, Vasilev, Kiril, Virtanen, Risto, and Welk, Erik

Abstract

Aim: A fundamental question in macroecology centres around understanding the relationship between species’ local abundance and their distribution in geographical and climatic space (i.e. the multi-dimensional climatic space or climatic niche). Here, we tested three macroecological hypotheses that link local abundance to the following range properties: (a) the abundance–range size relationship, (b) the abundance–range centre relationship and (c) the abundance–suitability relationship. Location: Europe. Taxon: Vascular plants. Methods: Distribution range maps were extracted from the Chorological Database Halle to derive information on the range and niche sizes of 517 European vascular plant species. To estimate local abundance, we assessed samples from 744,513 vegetation plots in the European Vegetation Archive, where local species’ abundance is available as plant cover per plot. We then calculated the ‘centrality’, that is, the distance between the location of the abundance observation and each species’ range centre in geographical and climatic space. The climatic suitability of plot locations was estimated using coarse-grain species distribution models (SDMs). The relationships between centrality or climatic suitability with abundance was tested using linear models and quantile regression. We summarized the overall trend across species’ regression slopes from linear models and quantile regression using a meta-analytical approach. Results: We did not detect any positive relationships between a species’ mean local abundance and the size of its geographical range or climatic niche. Contrasting yet significant correlations were detected between abundance and centrality or climatic suitability among species. Main conclusions: Our results do not provide unequivocal support for any of the relationships tested, demonstrating that determining properties of species’ distributions at large grains and extents might be of limited use for predicting local abundance, including cur

Published

2020

25. EUNIS Habitat Classification : expert system, characteristic species combinations and distribution maps of European habitats

Author

Chytrý, Milan, Tichý, Lubomír, Hennekens, Stephan M., Knollová, Ilona, Janssen, John A. M., Rodwell, John S., Peterka, Tomáš, Marcenò, Corrado, Landucci, Flavia, Danihelka, Jiří, Hájek, Michal, Dengler, Jürgen, Novák, Pavel, Zukal, Dominik, Jiménez‐Alfaro, Borja, Mucina, Ladislav, Abdulhak, Sylvain, Aćić, Svetlana, Agrillo, Emiliano, Attorre, Fabio, Bergmeier, Erwin, Biurrun, Idoia, Boch, Steffen, Bölöni, János, Bonari, Gianmaria, Braslavskaya, Tatiana, Bruelheide, Helge, Campos, Juan Antonio, Čarni, Andraž, Casella, Laura, Ćuk, Mirjana, Ćušterevska, Renata, De Bie, Els, Delbosc, Pauline, Demina, Olga, Didukh, Yakiv, Dítě, Daniel, Dziuba, Tetiana, Ewald, Jörg, Gavilán, Rosario G., Gégout, Jean‐Claude, Giusso del Galdo, Gian Pietro, Golub, Valentin, Goncharova, Nadezhda, Goral, Friedemann, Graf, Ulrich, Indreica, Adrian, Isermann, Maike, Jandt, Ute, Jansen, Florian, Jansen, Jan, Jašková, Anni, Jiroušek, Martin, Kącki, Zygmunt, Kalníková, Veronika, Kavgacı, Ali, Khanina, Larisa, Yu. Korolyuk, Andrey, Kozhevnikova, Mariya, Kuzemko, Anna, Küzmič, Filip, Kuznetsov, Oleg L., Laiviņš, Māris, Lavrinenko, Igor, Lavrinenko, Olga, Lebedeva, Maria, Lososová, Zdeňka, Lysenko, Tatiana, Maciejewski, Lise, Mardari, Constantin, Marinšek, Aleksander, Napreenko, Maxim G., Onyshchenko, Viktor, Pérez‐Haase, Aaron, Pielech, Remigiusz, Prokhorov, Vadim, Rašomavičius, Valerijus, Rodríguez Rojo, Maria Pilar, Rūsiņa, Solvita, Schrautzer, Joachim, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Smagin, Viktor A., Stančić, Zvjezdana, Stanisci, Angela, Tikhonova, Elena, Tonteri, Tiina, Uogintas, Domas, Valachovič, Milan, Vassilev, Kiril, Vynokurov, Denys, Willner, Wolfgang, Yamalov, Sergey, Evans, Douglas, Palitzsch Lund, Mette, Spyropoulou, Rania, Tryfon, Eleni, Schaminée, Joop H. J., Chytrý, Milan, Tichý, Lubomír, Hennekens, Stephan M., Knollová, Ilona, Janssen, John A. M., Rodwell, John S., Peterka, Tomáš, Marcenò, Corrado, Landucci, Flavia, Danihelka, Jiří, Hájek, Michal, Dengler, Jürgen, Novák, Pavel, Zukal, Dominik, Jiménez‐Alfaro, Borja, Mucina, Ladislav, Abdulhak, Sylvain, Aćić, Svetlana, Agrillo, Emiliano, Attorre, Fabio, Bergmeier, Erwin, Biurrun, Idoia, Boch, Steffen, Bölöni, János, Bonari, Gianmaria, Braslavskaya, Tatiana, Bruelheide, Helge, Campos, Juan Antonio, Čarni, Andraž, Casella, Laura, Ćuk, Mirjana, Ćušterevska, Renata, De Bie, Els, Delbosc, Pauline, Demina, Olga, Didukh, Yakiv, Dítě, Daniel, Dziuba, Tetiana, Ewald, Jörg, Gavilán, Rosario G., Gégout, Jean‐Claude, Giusso del Galdo, Gian Pietro, Golub, Valentin, Goncharova, Nadezhda, Goral, Friedemann, Graf, Ulrich, Indreica, Adrian, Isermann, Maike, Jandt, Ute, Jansen, Florian, Jansen, Jan, Jašková, Anni, Jiroušek, Martin, Kącki, Zygmunt, Kalníková, Veronika, Kavgacı, Ali, Khanina, Larisa, Yu. Korolyuk, Andrey, Kozhevnikova, Mariya, Kuzemko, Anna, Küzmič, Filip, Kuznetsov, Oleg L., Laiviņš, Māris, Lavrinenko, Igor, Lavrinenko, Olga, Lebedeva, Maria, Lososová, Zdeňka, Lysenko, Tatiana, Maciejewski, Lise, Mardari, Constantin, Marinšek, Aleksander, Napreenko, Maxim G., Onyshchenko, Viktor, Pérez‐Haase, Aaron, Pielech, Remigiusz, Prokhorov, Vadim, Rašomavičius, Valerijus, Rodríguez Rojo, Maria Pilar, Rūsiņa, Solvita, Schrautzer, Joachim, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Smagin, Viktor A., Stančić, Zvjezdana, Stanisci, Angela, Tikhonova, Elena, Tonteri, Tiina, Uogintas, Domas, Valachovič, Milan, Vassilev, Kiril, Vynokurov, Denys, Willner, Wolfgang, Yamalov, Sergey, Evans, Douglas, Palitzsch Lund, Mette, Spyropoulou, Rania, Tryfon, Eleni, and Schaminée, Joop H. J.

Abstract

Aim: The EUNIS Habitat Classification is a widely used reference framework for European habitat types (habitats), but it lacks formal definitions of individual habitats that would enable their unequivocal identification. Our goal was to develop a tool for assigning vegetation-plot records to the habitats of the EUNIS system, use it to classify a European vegetation-plot database, and compile statistically-derived characteristic species combinations and distribution maps for these habitats. Location: Europe. Methods: We developed the classification expert system EUNIS-ESy, which contains definitions of individual EUNIS habitats based on their species composition and geographic location. Each habitat was formally defined as a formula in a computer language combining algebraic and set-theoretic concepts with formal logical operators. We applied this expert system to classify 1,261,373 vegetation plots from the European Vegetation Archive (EVA) and other databases. Then we determined diagnostic, constant and dominant species for each habitat by calculating species-to-habitat fidelity and constancy (occurrence frequency) in the classified data set. Finally, we mapped the plot locations for each habitat. Results: Formal definitions were developed for 199 habitats at Level 3 of the EUNIS hierarchy, including 25 coastal, 18 wetland, 55 grassland, 43 shrubland, 46 forest and 12 man-made habitats. The expert system classified 1,125,121 vegetation plots to these habitat groups and 73,188 to other habitats, while 63,064 plots remained unclassified or were classified to more than one habitat. Data on each habitat were summarized in factsheets containing habitat description, distribution map, corresponding syntaxa and characteristic species combination. Conclusions: EUNIS habitats were characterized for the first time in terms of their species composition and distribution, based on a classification of a European database of vegetation plots using the newly developed electronic ex

Published

2020

26. Post‐glacial determinants of regional species pools in alpine grasslands

Author

Jiménez‐Alfaro, Borja, primary, Abdulhak, Sylvain, additional, Attorre, Fabio, additional, Bergamini, Ariel, additional, Carranza, Maria Laura, additional, Chiarucci, Alessandro, additional, Ćušterevska, Renata, additional, Dullinger, Stefan, additional, Gavilán, Rosario G., additional, Giusso del Galdo, Gianpietro, additional, Kuzmanović, Nevena, additional, Laiolo, Paola, additional, Loidi, Javier, additional, Malanson, George P., additional, Marcenó, Corrado, additional, Milanović, Đorđije, additional, Pansing, Elizabeth R., additional, Roces‐Díaz, José V., additional, Ruprecht, Eszter, additional, Šibik, Jozef, additional, Stanisci, Angela, additional, Testolin, Riccardo, additional, Theurillat, Jean‐Paul, additional, Vassilev, Kiril, additional, Willner, Wolfgang, additional, and Winkler, Manuela, additional

Published

2021

27. Different sets of traits explain abundance and distribution patterns of European plants at different spatial scales

Author

Sporbert, Maria, primary, Welk, Erik, additional, Seidler, Gunnar, additional, Jandt, Ute, additional, Aćić, Svetlana, additional, Biurrun, Idoia, additional, Campos, Juan Antonio, additional, Čarni, Andraž, additional, Cerabolini, Bruno E. L., additional, Chytrý, Milan, additional, Ćušterevska, Renata, additional, Dengler, Jürgen, additional, De Sanctis, Michele, additional, Dziuba, Tetiana, additional, Fagúndez, Jaime, additional, Field, Richard, additional, Golub, Valentin, additional, He, Tianhua, additional, Jansen, Florian, additional, Lenoir, Jonathan, additional, Marcenò, Corrado, additional, Martín‐Forés, Irene, additional, Moeslund, Jesper Erenskjold, additional, Moretti, Marco, additional, Niinemets, Ülo, additional, Penuelas, Josep, additional, Pérez‐Haase, Aaron, additional, Vandvik, Vigdis, additional, Vassilev, Kiril, additional, Vynokurov, Denys, additional, and Bruelheide, Helge, additional

Published

2021

28. EUNIS Habitat Classification: Expert system, characteristic species combinations and distribution maps of European habitats

Author

Chytrý, Milan, primary, Tichý, Lubomír, additional, Hennekens, Stephan M., additional, Knollová, Ilona, additional, Janssen, John A. M., additional, Rodwell, John S., additional, Peterka, Tomáš, additional, Marcenò, Corrado, additional, Landucci, Flavia, additional, Danihelka, Jiří, additional, Hájek, Michal, additional, Dengler, Jürgen, additional, Novák, Pavel, additional, Zukal, Dominik, additional, Jiménez‐Alfaro, Borja, additional, Mucina, Ladislav, additional, Abdulhak, Sylvain, additional, Aćić, Svetlana, additional, Agrillo, Emiliano, additional, Attorre, Fabio, additional, Bergmeier, Erwin, additional, Biurrun, Idoia, additional, Boch, Steffen, additional, Bölöni, János, additional, Bonari, Gianmaria, additional, Braslavskaya, Tatiana, additional, Bruelheide, Helge, additional, Campos, Juan Antonio, additional, Čarni, Andraž, additional, Casella, Laura, additional, Ćuk, Mirjana, additional, Ćušterevska, Renata, additional, De Bie, Els, additional, Delbosc, Pauline, additional, Demina, Olga, additional, Didukh, Yakiv, additional, Dítě, Daniel, additional, Dziuba, Tetiana, additional, Ewald, Jörg, additional, Gavilán, Rosario G., additional, Gégout, Jean‐Claude, additional, Giusso del Galdo, Gian Pietro, additional, Golub, Valentin, additional, Goncharova, Nadezhda, additional, Goral, Friedemann, additional, Graf, Ulrich, additional, Indreica, Adrian, additional, Isermann, Maike, additional, Jandt, Ute, additional, Jansen, Florian, additional, Jansen, Jan, additional, Jašková, Anni, additional, Jiroušek, Martin, additional, Kącki, Zygmunt, additional, Kalníková, Veronika, additional, Kavgacı, Ali, additional, Khanina, Larisa, additional, Yu. Korolyuk, Andrey, additional, Kozhevnikova, Mariya, additional, Kuzemko, Anna, additional, Küzmič, Filip, additional, Kuznetsov, Oleg L., additional, Laiviņš, Māris, additional, Lavrinenko, Igor, additional, Lavrinenko, Olga, additional, Lebedeva, Maria, additional, Lososová, Zdeňka, additional, Lysenko, Tatiana, additional, Maciejewski, Lise, additional, Mardari, Constantin, additional, Marinšek, Aleksander, additional, Napreenko, Maxim G., additional, Onyshchenko, Viktor, additional, Pérez‐Haase, Aaron, additional, Pielech, Remigiusz, additional, Prokhorov, Vadim, additional, Rašomavičius, Valerijus, additional, Rodríguez Rojo, Maria Pilar, additional, Rūsiņa, Solvita, additional, Schrautzer, Joachim, additional, Šibík, Jozef, additional, Šilc, Urban, additional, Škvorc, Željko, additional, Smagin, Viktor A., additional, Stančić, Zvjezdana, additional, Stanisci, Angela, additional, Tikhonova, Elena, additional, Tonteri, Tiina, additional, Uogintas, Domas, additional, Valachovič, Milan, additional, Vassilev, Kiril, additional, Vynokurov, Denys, additional, Willner, Wolfgang, additional, Yamalov, Sergey, additional, Evans, Douglas, additional, Palitzsch Lund, Mette, additional, Spyropoulou, Rania, additional, Tryfon, Eleni, additional, and Schaminée, Joop H. J., additional

Published

2020

29. Testing macroecological abundance patterns: The relationship between local abundance and range size, range position and climatic suitability among European vascular plants

Author

Sporbert, Maria, primary, Keil, Petr, additional, Seidler, Gunnar, additional, Bruelheide, Helge, additional, Jandt, Ute, additional, Aćić, Svetlana, additional, Biurrun, Idoia, additional, Campos, Juan Antonio, additional, Čarni, Andraž, additional, Chytrý, Milan, additional, Ćušterevska, Renata, additional, Dengler, Jürgen, additional, Golub, Valentin, additional, Jansen, Florian, additional, Kuzemko, Anna, additional, Lenoir, Jonathan, additional, Marcenò, Corrado, additional, Moeslund, Jesper Erenskjold, additional, Pérez‐Haase, Aaron, additional, Rūsiņa, Solvita, additional, Šilc, Urban, additional, Tsiripidris, Ioannis, additional, Vandvik, Vigdis, additional, Vasilev, Kiril, additional, Virtanen, Risto, additional, and Welk, Erik, additional

Published

2020

30. sPlot : a new tool for global vegetation analyses

Author

Bruelheide, Helge, Dengler, Jürgen, Jiménez‐Alfaro, Borja, Purschke, Oliver, Hennekens, Stephan M., Chytrý, Milan, Pillar, Valério D., Jansen, Florian, Kattge, Jens, Sandel, Brody, Aubin, Isabelle, Biurrun, Idoia, Field, Richard, Haider, Sylvia, Jandt, Ute, Lenoir, Jonathan, Peet, Robert K., Peyre, Gwendolyn, Sabatini, Francesco Maria, Schmidt, Marco, Schrodt, Franziska, Winter, Marten, Aćić, Svetlana, Agrillo, Emiliano, Alvarez, Miguel, Ambarlı, Didem, Angelini, Pierangela, Apostolova, Iva, Arfin Khan, Mohammed A. S., Arnst, Elise, Attorre, Fabio, Baraloto, Christopher, Beckmann, Michael, Berg, Christian, Bergeron, Yves, Bergmeier, Erwin, Bjorkman, Anne D., Bondareva, Viktoria, Borchardt, Peter, Botta‐Dukát, Zoltán, Boyle, Brad, Breen, Amy, Brisse, Henry, Byun, Chaeho, Cabido, Marcelo R., Casella, Laura, Cayuela, Luis, Černý, Tomáš, Chepinoga, Victor, Csiky, János, Curran, Michael, Ćušterevska, Renata, Dajić Stevanović, Zora, De Bie, Els, de Ruffray, Patrice, De Sanctis, Michele, Dimopoulos, Panayotis, Dressler, Stefan, Ejrnæs, Rasmus, El‐Sheikh, Mohamed Abd El‐Rouf Mousa, Enquist, Brian, Ewald, Jörg, Fagúndez, Jaime, Finckh, Manfred, Font, Xavier, Forey, Estelle, Fotiadis, Georgios, García‐Mijangos, Itziar, Gasper, André Luis, Golub, Valentin, Gutierrez, Alvaro G., Hatim, Mohamed Z., He, Tianhua, Higuchi, Pedro, Holubová, Dana, Hölzel, Norbert, Homeier, Jürgen, Indreica, Adrian, Işık Gürsoy, Deniz, Jansen, Steven, Janssen, John, Jedrzejek, Birgit, Jiroušek, Martin, Jürgens, Norbert, Kącki, Zygmunt, Kavgacı, Ali, Kearsley, Elizabeth, Kessler, Michael, Knollová, Ilona, Kolomiychuk, Vitaliy, Korolyuk, Andrey, Kozhevnikova, Maria, Kozub, Łukasz, Krstonošić, Daniel, Kühl, Hjalmar, Kühn, Ingolf, Kuzemko, Anna, Küzmič, Filip, Landucci, Flavia, Lee, Michael T., Levesley, Aurora, Li, Ching‐Feng, Liu, Hongyan, Lopez‐Gonzalez, Gabriela, Lysenko, Tatiana, Macanović, Armin, Mahdavi, Parastoo, Manning, Peter, Marcenò, Corrado, Martynenko, Vassiliy, Mencuccini, Maurizio, Minden, Vanessa, Moeslund, Jesper Erenskjold, Moretti, Marco, Müller, Jonas V., Munzinger, Jérôme, Niinemets, Ülo, Nobis, Marcin, Noroozi, Jalil, Nowak, Arkadiusz, Onyshchenko, Viktor, Overbeck, Gerhard E., Ozinga, Wim A., Pauchard, Anibal, Pedashenko, Hristo, Peñuelas, Josep, Pérez‐Haase, Aaron, Peterka, Tomáš, Petřík, Petr, Phillips, Oliver L., Prokhorov, Vadim, Rašomavičius, Valerijus, Revermann, Rasmus, Rodwell, John, Ruprecht, Eszter, Rūsiņa, Solvita, Samimi, Cyrus, Schaminée, Joop H.J., Schmiedel, Ute, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Smyth, Anita, Sop, Tenekwetche, Sopotlieva, Desislava, Sparrow, Ben, Stančić, Zvjezdana, Svenning, Jens‐Christian, Swacha, Grzegorz, Tang, Zhiyao, Tsiripidis, Ioannis, Turtureanu, Pavel Dan, Uğurlu, Emin, Uogintas, Domas, Valachovič, Milan, Vanselow, Kim André, Vashenyak, Yulia, Vassilev, Kiril, Vélez‐Martin, Eduardo, Venanzoni, Roberto, Vibrans, Alexander Christian, Violle, Cyrille, Virtanen, Risto, Wehrden, Henrik, Wagner, Viktoria, Walker, Donald A., Wana, Desalegn, Weiher, Evan, Wesche, Karsten, Whitfeld, Timothy, Willner, Wolfgang, Wiser, Susan, Wohlgemuth, Thomas, Yamalov, Sergey, Zizka, Georg, Zverev, Andrei, Bruelheide, Helge, Dengler, Jürgen, Jiménez‐Alfaro, Borja, Purschke, Oliver, Hennekens, Stephan M., Chytrý, Milan, Pillar, Valério D., Jansen, Florian, Kattge, Jens, Sandel, Brody, Aubin, Isabelle, Biurrun, Idoia, Field, Richard, Haider, Sylvia, Jandt, Ute, Lenoir, Jonathan, Peet, Robert K., Peyre, Gwendolyn, Sabatini, Francesco Maria, Schmidt, Marco, Schrodt, Franziska, Winter, Marten, Aćić, Svetlana, Agrillo, Emiliano, Alvarez, Miguel, Ambarlı, Didem, Angelini, Pierangela, Apostolova, Iva, Arfin Khan, Mohammed A. S., Arnst, Elise, Attorre, Fabio, Baraloto, Christopher, Beckmann, Michael, Berg, Christian, Bergeron, Yves, Bergmeier, Erwin, Bjorkman, Anne D., Bondareva, Viktoria, Borchardt, Peter, Botta‐Dukát, Zoltán, Boyle, Brad, Breen, Amy, Brisse, Henry, Byun, Chaeho, Cabido, Marcelo R., Casella, Laura, Cayuela, Luis, Černý, Tomáš, Chepinoga, Victor, Csiky, János, Curran, Michael, Ćušterevska, Renata, Dajić Stevanović, Zora, De Bie, Els, de Ruffray, Patrice, De Sanctis, Michele, Dimopoulos, Panayotis, Dressler, Stefan, Ejrnæs, Rasmus, El‐Sheikh, Mohamed Abd El‐Rouf Mousa, Enquist, Brian, Ewald, Jörg, Fagúndez, Jaime, Finckh, Manfred, Font, Xavier, Forey, Estelle, Fotiadis, Georgios, García‐Mijangos, Itziar, Gasper, André Luis, Golub, Valentin, Gutierrez, Alvaro G., Hatim, Mohamed Z., He, Tianhua, Higuchi, Pedro, Holubová, Dana, Hölzel, Norbert, Homeier, Jürgen, Indreica, Adrian, Işık Gürsoy, Deniz, Jansen, Steven, Janssen, John, Jedrzejek, Birgit, Jiroušek, Martin, Jürgens, Norbert, Kącki, Zygmunt, Kavgacı, Ali, Kearsley, Elizabeth, Kessler, Michael, Knollová, Ilona, Kolomiychuk, Vitaliy, Korolyuk, Andrey, Kozhevnikova, Maria, Kozub, Łukasz, Krstonošić, Daniel, Kühl, Hjalmar, Kühn, Ingolf, Kuzemko, Anna, Küzmič, Filip, Landucci, Flavia, Lee, Michael T., Levesley, Aurora, Li, Ching‐Feng, Liu, Hongyan, Lopez‐Gonzalez, Gabriela, Lysenko, Tatiana, Macanović, Armin, Mahdavi, Parastoo, Manning, Peter, Marcenò, Corrado, Martynenko, Vassiliy, Mencuccini, Maurizio, Minden, Vanessa, Moeslund, Jesper Erenskjold, Moretti, Marco, Müller, Jonas V., Munzinger, Jérôme, Niinemets, Ülo, Nobis, Marcin, Noroozi, Jalil, Nowak, Arkadiusz, Onyshchenko, Viktor, Overbeck, Gerhard E., Ozinga, Wim A., Pauchard, Anibal, Pedashenko, Hristo, Peñuelas, Josep, Pérez‐Haase, Aaron, Peterka, Tomáš, Petřík, Petr, Phillips, Oliver L., Prokhorov, Vadim, Rašomavičius, Valerijus, Revermann, Rasmus, Rodwell, John, Ruprecht, Eszter, Rūsiņa, Solvita, Samimi, Cyrus, Schaminée, Joop H.J., Schmiedel, Ute, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Smyth, Anita, Sop, Tenekwetche, Sopotlieva, Desislava, Sparrow, Ben, Stančić, Zvjezdana, Svenning, Jens‐Christian, Swacha, Grzegorz, Tang, Zhiyao, Tsiripidis, Ioannis, Turtureanu, Pavel Dan, Uğurlu, Emin, Uogintas, Domas, Valachovič, Milan, Vanselow, Kim André, Vashenyak, Yulia, Vassilev, Kiril, Vélez‐Martin, Eduardo, Venanzoni, Roberto, Vibrans, Alexander Christian, Violle, Cyrille, Virtanen, Risto, Wehrden, Henrik, Wagner, Viktoria, Walker, Donald A., Wana, Desalegn, Weiher, Evan, Wesche, Karsten, Whitfeld, Timothy, Willner, Wolfgang, Wiser, Susan, Wohlgemuth, Thomas, Yamalov, Sergey, Zizka, Georg, and Zverev, Andrei

Abstract

Aims: Vegetation‐plot records provide information on the presence and cover or abundance of plants co‐occurring in the same community. Vegetation‐plot data are spread across research groups, environmental agencies and biodiversity research centers and, thus, are rarely accessible at continental or global scales. Here we present the sPlot database, which collates vegetation plots worldwide to allow for the exploration of global patterns in taxonomic, functional and phylogenetic diversity at the plant community level. Results: sPlot version 2.1 contains records from 1,121,244 vegetation plots, which comprise 23,586,216 records of plant species and their relative cover or abundance in plots collected worldwide between 1885 and 2015. We complemented the information for each plot by retrieving climate and soil conditions and the biogeographic context (e.g., biomes) from external sources, and by calculating community‐weighted means and variances of traits using gap‐filled data from the global plant trait database TRY. Moreover, we created a phylogenetic tree for 50,167 out of the 54,519 species identified in the plots. We present the first maps of global patterns of community richness and community‐weighted means of key traits. Conclusions: The availability of vegetation plot data in sPlot offers new avenues for vegetation analysis at the global scale.

Published

2019

31. sPlot – A new tool for global vegetation analyses

Author

Bruelheide, Helge, primary, Dengler, Jürgen, additional, Jiménez‐Alfaro, Borja, additional, Purschke, Oliver, additional, Hennekens, Stephan M., additional, Chytrý, Milan, additional, Pillar, Valério D., additional, Jansen, Florian, additional, Kattge, Jens, additional, Sandel, Brody, additional, Aubin, Isabelle, additional, Biurrun, Idoia, additional, Field, Richard, additional, Haider, Sylvia, additional, Jandt, Ute, additional, Lenoir, Jonathan, additional, Peet, Robert K., additional, Peyre, Gwendolyn, additional, Sabatini, Francesco Maria, additional, Schmidt, Marco, additional, Schrodt, Franziska, additional, Winter, Marten, additional, Aćić, Svetlana, additional, Agrillo, Emiliano, additional, Alvarez, Miguel, additional, Ambarlı, Didem, additional, Angelini, Pierangela, additional, Apostolova, Iva, additional, Arfin Khan, Mohammed A. S., additional, Arnst, Elise, additional, Attorre, Fabio, additional, Baraloto, Christopher, additional, Beckmann, Michael, additional, Berg, Christian, additional, Bergeron, Yves, additional, Bergmeier, Erwin, additional, Bjorkman, Anne D., additional, Bondareva, Viktoria, additional, Borchardt, Peter, additional, Botta‐Dukát, Zoltán, additional, Boyle, Brad, additional, Breen, Amy, additional, Brisse, Henry, additional, Byun, Chaeho, additional, Cabido, Marcelo R., additional, Casella, Laura, additional, Cayuela, Luis, additional, Černý, Tomáš, additional, Chepinoga, Victor, additional, Csiky, János, additional, Curran, Michael, additional, Ćušterevska, Renata, additional, Dajić Stevanović, Zora, additional, De Bie, Els, additional, de Ruffray, Patrice, additional, De Sanctis, Michele, additional, Dimopoulos, Panayotis, additional, Dressler, Stefan, additional, Ejrnæs, Rasmus, additional, El‐Sheikh, Mohamed Abd El‐Rouf Mousa, additional, Enquist, Brian, additional, Ewald, Jörg, additional, Fagúndez, Jaime, additional, Finckh, Manfred, additional, Font, Xavier, additional, Forey, Estelle, additional, Fotiadis, Georgios, additional, García‐Mijangos, Itziar, additional, de Gasper, André Luis, additional, Golub, Valentin, additional, Gutierrez, Alvaro G., additional, Hatim, Mohamed Z., additional, He, Tianhua, additional, Higuchi, Pedro, additional, Holubová, Dana, additional, Hölzel, Norbert, additional, Homeier, Jürgen, additional, Indreica, Adrian, additional, Işık Gürsoy, Deniz, additional, Jansen, Steven, additional, Janssen, John, additional, Jedrzejek, Birgit, additional, Jiroušek, Martin, additional, Jürgens, Norbert, additional, Kącki, Zygmunt, additional, Kavgacı, Ali, additional, Kearsley, Elizabeth, additional, Kessler, Michael, additional, Knollová, Ilona, additional, Kolomiychuk, Vitaliy, additional, Korolyuk, Andrey, additional, Kozhevnikova, Maria, additional, Kozub, Łukasz, additional, Krstonošić, Daniel, additional, Kühl, Hjalmar, additional, Kühn, Ingolf, additional, Kuzemko, Anna, additional, Küzmič, Filip, additional, Landucci, Flavia, additional, Lee, Michael T., additional, Levesley, Aurora, additional, Li, Ching‐Feng, additional, Liu, Hongyan, additional, Lopez‐Gonzalez, Gabriela, additional, Lysenko, Tatiana, additional, Macanović, Armin, additional, Mahdavi, Parastoo, additional, Manning, Peter, additional, Marcenò, Corrado, additional, Martynenko, Vassiliy, additional, Mencuccini, Maurizio, additional, Minden, Vanessa, additional, Moeslund, Jesper Erenskjold, additional, Moretti, Marco, additional, Müller, Jonas V., additional, Munzinger, Jérôme, additional, Niinemets, Ülo, additional, Nobis, Marcin, additional, Noroozi, Jalil, additional, Nowak, Arkadiusz, additional, Onyshchenko, Viktor, additional, Overbeck, Gerhard E., additional, Ozinga, Wim A., additional, Pauchard, Anibal, additional, Pedashenko, Hristo, additional, Peñuelas, Josep, additional, Pérez‐Haase, Aaron, additional, Peterka, Tomáš, additional, Petřík, Petr, additional, Phillips, Oliver L., additional, Prokhorov, Vadim, additional, Rašomavičius, Valerijus, additional, Revermann, Rasmus, additional, Rodwell, John, additional, Ruprecht, Eszter, additional, Rūsiņa, Solvita, additional, Samimi, Cyrus, additional, Schaminée, Joop H.J., additional, Schmiedel, Ute, additional, Šibík, Jozef, additional, Šilc, Urban, additional, Škvorc, Željko, additional, Smyth, Anita, additional, Sop, Tenekwetche, additional, Sopotlieva, Desislava, additional, Sparrow, Ben, additional, Stančić, Zvjezdana, additional, Svenning, Jens‐Christian, additional, Swacha, Grzegorz, additional, Tang, Zhiyao, additional, Tsiripidis, Ioannis, additional, Turtureanu, Pavel Dan, additional, Uğurlu, Emin, additional, Uogintas, Domas, additional, Valachovič, Milan, additional, Vanselow, Kim André, additional, Vashenyak, Yulia, additional, Vassilev, Kiril, additional, Vélez‐Martin, Eduardo, additional, Venanzoni, Roberto, additional, Vibrans, Alexander Christian, additional, Violle, Cyrille, additional, Virtanen, Risto, additional, von Wehrden, Henrik, additional, Wagner, Viktoria, additional, Walker, Donald A., additional, Wana, Desalegn, additional, Weiher, Evan, additional, Wesche, Karsten, additional, Whitfeld, Timothy, additional, Willner, Wolfgang, additional, Wiser, Susan, additional, Wohlgemuth, Thomas, additional, Yamalov, Sergey, additional, Zizka, Georg, additional, and Zverev, Andrei, additional

Published

2019

32. Syntaxonomy and biogeography of dry grasslands on calcareous substrates in the central and southern Balkans

Author

Matevski, Vlado, primary, Čarni, Andraž, additional, Ćušterevska, Renata, additional, Kostadinovski, Mitko, additional, and Mucina, Ladislav, additional

Published

2018

33. Alien plant invasions in European woodlands

Author

Wagner, Viktoria, primary, Chytrý, Milan, additional, Jiménez-Alfaro, Borja, additional, Pergl, Jan, additional, Hennekens, Stephan, additional, Biurrun, Idoia, additional, Knollová, Ilona, additional, Berg, Christian, additional, Vassilev, Kiril, additional, Rodwell, John S., additional, Škvorc, Željko, additional, Jandt, Ute, additional, Ewald, Jörg, additional, Jansen, Florian, additional, Tsiripidis, Ioannis, additional, Botta-Dukát, Zoltán, additional, Casella, Laura, additional, Attorre, Fabio, additional, Rašomavičius, Valerijus, additional, Ćušterevska, Renata, additional, Schaminée, Joop H. J., additional, Brunet, Jörg, additional, Lenoir, Jonathan, additional, Svenning, Jens-Christian, additional, Kącki, Zygmunt, additional, Petrášová-Šibíková, Mária, additional, Šilc, Urban, additional, García-Mijangos, Itziar, additional, Campos, Juan Antonio, additional, Fernández-González, Federico, additional, Wohlgemuth, Thomas, additional, Onyshchenko, Viktor, additional, and Pyšek, Petr, additional

Published

2017

34. Classification of European beech forests: a Gordian Knot?

Author

Willner, Wolfgang, primary, Jiménez-Alfaro, Borja, additional, Agrillo, Emiliano, additional, Biurrun, Idoia, additional, Campos, Juan Antonio, additional, Čarni, Andraž, additional, Casella, Laura, additional, Csiky, János, additional, Ćušterevska, Renata, additional, Didukh, Yakiv P., additional, Ewald, Jörg, additional, Jandt, Ute, additional, Jansen, Florian, additional, Kącki, Zygmunt, additional, Kavgacı, Ali, additional, Lenoir, Jonathan, additional, Marinšek, Aleksander, additional, Onyshchenko, Viktor, additional, Rodwell, John S., additional, Schaminée, Joop H.J., additional, Šibík, Jozef, additional, Škvorc, Željko, additional, Svenning, Jens-Christian, additional, Tsiripidis, Ioannis, additional, Turtureanu, Pavel Dan, additional, Tzonev, Rossen, additional, Vassilev, Kiril, additional, Venanzoni, Roberto, additional, Wohlgemuth, Thomas, additional, and Chytrý, Milan, additional

Published

2017

35. Formalized classification of European fen vegetation at the alliance level

Author

Peterka, Tomáš, primary, Hájek, Michal, additional, Jiroušek, Martin, additional, Jiménez-Alfaro, Borja, additional, Aunina, Liene, additional, Bergamini, Ariel, additional, Dítě, Daniel, additional, Felbaba-Klushyna, Ljuba, additional, Graf, Ulrich, additional, Hájková, Petra, additional, Hettenbergerová, Eva, additional, Ivchenko, Tatiana G., additional, Jansen, Florian, additional, Koroleva, Natalia E., additional, Lapshina, Elena D., additional, Lazarević, Predrag M., additional, Moen, Asbjørn, additional, Napreenko, Maxim G., additional, Pawlikowski, Paweł, additional, Plesková, Zuzana, additional, Sekulová, Lucia, additional, Smagin, Viktor A., additional, Tahvanainen, Teemu, additional, Thiele, Annett, additional, Biţǎ-Nicolae, Claudia, additional, Biurrun, Idoia, additional, Brisse, Henry, additional, Ćušterevska, Renata, additional, De Bie, Els, additional, Ewald, Jörg, additional, FitzPatrick, Úna, additional, Font, Xavier, additional, Jandt, Ute, additional, Kącki, Zygmunt, additional, Kuzemko, Anna, additional, Landucci, Flavia, additional, Moeslund, Jesper E., additional, Pérez-Haase, Aaron, additional, Rašomavičius, Valerijus, additional, Rodwell, John S., additional, Schaminée, Joop H.J., additional, Šilc, Urban, additional, Stančić, Zvjezdana, additional, and Chytrý, Milan, additional

Published

2016

36. European Vegetation Archive (EVA): an integrated database of European vegetation plots

Author

Chytrý, Milan, primary, Hennekens, Stephan M., additional, Jiménez‐Alfaro, Borja, additional, Knollová, Ilona, additional, Dengler, Jürgen, additional, Jansen, Florian, additional, Landucci, Flavia, additional, Schaminée, Joop H.J., additional, Aćić, Svetlana, additional, Agrillo, Emiliano, additional, Ambarlı, Didem, additional, Angelini, Pierangela, additional, Apostolova, Iva, additional, Attorre, Fabio, additional, Berg, Christian, additional, Bergmeier, Erwin, additional, Biurrun, Idoia, additional, Botta‐Dukát, Zoltán, additional, Brisse, Henry, additional, Campos, Juan Antonio, additional, Carlón, Luis, additional, Čarni, Andraž, additional, Casella, Laura, additional, Csiky, János, additional, Ćušterevska, Renata, additional, Dajić Stevanović, Zora, additional, Danihelka, Jiří, additional, De Bie, Els, additional, de Ruffray, Patrice, additional, De Sanctis, Michele, additional, Dickoré, W. Bernhard, additional, Dimopoulos, Panayotis, additional, Dubyna, Dmytro, additional, Dziuba, Tetiana, additional, Ejrnæs, Rasmus, additional, Ermakov, Nikolai, additional, Ewald, Jörg, additional, Fanelli, Giuliano, additional, Fernández‐González, Federico, additional, FitzPatrick, Úna, additional, Font, Xavier, additional, García‐Mijangos, Itziar, additional, Gavilán, Rosario G., additional, Golub, Valentin, additional, Guarino, Riccardo, additional, Haveman, Rense, additional, Indreica, Adrian, additional, Işık Gürsoy, Deniz, additional, Jandt, Ute, additional, Janssen, John A.M., additional, Jiroušek, Martin, additional, Kącki, Zygmunt, additional, Kavgacı, Ali, additional, Kleikamp, Martin, additional, Kolomiychuk, Vitaliy, additional, Krstivojević Ćuk, Mirjana, additional, Krstonošić, Daniel, additional, Kuzemko, Anna, additional, Lenoir, Jonathan, additional, Lysenko, Tatiana, additional, Marcenò, Corrado, additional, Martynenko, Vassiliy, additional, Michalcová, Dana, additional, Moeslund, Jesper Erenskjold, additional, Onyshchenko, Viktor, additional, Pedashenko, Hristo, additional, Pérez‐Haase, Aaron, additional, Peterka, Tomáš, additional, Prokhorov, Vadim, additional, Rašomavičius, Valerijus, additional, Rodríguez‐Rojo, Maria Pilar, additional, Rodwell, John S., additional, Rogova, Tatiana, additional, Ruprecht, Eszter, additional, Rūsiņa, Solvita, additional, Seidler, Gunnar, additional, Šibík, Jozef, additional, Šilc, Urban, additional, Škvorc, Željko, additional, Sopotlieva, Desislava, additional, Stančić, Zvjezdana, additional, Svenning, Jens‐Christian, additional, Swacha, Grzegorz, additional, Tsiripidis, Ioannis, additional, Turtureanu, Pavel Dan, additional, Uğurlu, Emin, additional, Uogintas, Domas, additional, Valachovič, Milan, additional, Vashenyak, Yulia, additional, Vassilev, Kiril, additional, Venanzoni, Roberto, additional, Virtanen, Risto, additional, Weekes, Lynda, additional, Willner, Wolfgang, additional, Wohlgemuth, Thomas, additional, and Yamalov, Sergey, additional

Published

2015

37. sPlot : a new tool for global vegetation analyses

Author

Bruelheide, Helge, Dengler, Jürgen, Jiménez‐Alfaro, Borja, Purschke, Oliver, Hennekens, Stephan M., Chytrý, Milan, Pillar, Valério D., Jansen, Florian, Kattge, Jens, Sandel, Brody, Aubin, Isabelle, Biurrun, Idoia, Field, Richard, Haider, Sylvia, Jandt, Ute, Lenoir, Jonathan, Peet, Robert K., Peyre, Gwendolyn, Sabatini, Francesco Maria, Schmidt, Marco, Schrodt, Franziska, Winter, Marten, Aćić, Svetlana, Agrillo, Emiliano, Alvarez, Miguel, Ambarlı, Didem, Angelini, Pierangela, Apostolova, Iva, Arfin Khan, Mohammed A. S., Arnst, Elise, Attorre, Fabio, Baraloto, Christopher, Beckmann, Michael, Berg, Christian, Bergeron, Yves, Bergmeier, Erwin, Bjorkman, Anne D., Bondareva, Viktoria, Borchardt, Peter, Botta‐Dukát, Zoltán, Boyle, Brad, Breen, Amy, Brisse, Henry, Byun, Chaeho, Cabido, Marcelo R., Casella, Laura, Cayuela, Luis, Černý, Tomáš, Chepinoga, Victor, Csiky, János, Curran, Michael, Ćušterevska, Renata, Dajić Stevanović, Zora, De Bie, Els, de Ruffray, Patrice, De Sanctis, Michele, Dimopoulos, Panayotis, Dressler, Stefan, Ejrnæs, Rasmus, El‐Sheikh, Mohamed Abd El‐Rouf Mousa, Enquist, Brian, Ewald, Jörg, Fagúndez, Jaime, Finckh, Manfred, Font, Xavier, Forey, Estelle, Fotiadis, Georgios, García‐Mijangos, Itziar, Gasper, André Luis, Golub, Valentin, Gutierrez, Alvaro G., Hatim, Mohamed Z., He, Tianhua, Higuchi, Pedro, Holubová, Dana, Hölzel, Norbert, Homeier, Jürgen, Indreica, Adrian, Işık Gürsoy, Deniz, Jansen, Steven, Janssen, John, Jedrzejek, Birgit, Jiroušek, Martin, Jürgens, Norbert, Kącki, Zygmunt, Kavgacı, Ali, Kearsley, Elizabeth, Kessler, Michael, Knollová, Ilona, Kolomiychuk, Vitaliy, Korolyuk, Andrey, Kozhevnikova, Maria, Kozub, Łukasz, Krstonošić, Daniel, Kühl, Hjalmar, Kühn, Ingolf, Kuzemko, Anna, Küzmič, Filip, Landucci, Flavia, Lee, Michael T., Levesley, Aurora, Li, Ching‐Feng, Liu, Hongyan, Lopez‐Gonzalez, Gabriela, Lysenko, Tatiana, Macanović, Armin, Mahdavi, Parastoo, Manning, Peter, Marcenò, Corrado, Martynenko, Vassiliy, Mencuccini, Maurizio, Minden, Vanessa, Moeslund, Jesper Erenskjold, Moretti, Marco, Müller, Jonas V., Munzinger, Jérôme, Niinemets, Ülo, Nobis, Marcin, Noroozi, Jalil, Nowak, Arkadiusz, Onyshchenko, Viktor, Overbeck, Gerhard E., Ozinga, Wim A., Pauchard, Anibal, Pedashenko, Hristo, Peñuelas, Josep, Pérez‐Haase, Aaron, Peterka, Tomáš, Petřík, Petr, Phillips, Oliver L., Prokhorov, Vadim, Rašomavičius, Valerijus, Revermann, Rasmus, Rodwell, John, Ruprecht, Eszter, Rūsiņa, Solvita, Samimi, Cyrus, Schaminée, Joop H.J., Schmiedel, Ute, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Smyth, Anita, Sop, Tenekwetche, Sopotlieva, Desislava, Sparrow, Ben, Stančić, Zvjezdana, Svenning, Jens‐Christian, Swacha, Grzegorz, Tang, Zhiyao, Tsiripidis, Ioannis, Turtureanu, Pavel Dan, Uğurlu, Emin, Uogintas, Domas, Valachovič, Milan, Vanselow, Kim André, Vashenyak, Yulia, Vassilev, Kiril, Vélez‐Martin, Eduardo, Venanzoni, Roberto, Vibrans, Alexander Christian, Violle, Cyrille, Virtanen, Risto, Wehrden, Henrik, Wagner, Viktoria, Walker, Donald A., Wana, Desalegn, Weiher, Evan, Wesche, Karsten, Whitfeld, Timothy, Willner, Wolfgang, Wiser, Susan, Wohlgemuth, Thomas, Yamalov, Sergey, Zizka, Georg, and Zverev, Andrei

Subjects

580: Pflanzen (Botanik), sPlot, Ecoinformatics, 15. Life on land, 577: Ökologie

Abstract

Aims: Vegetation‐plot records provide information on the presence and cover or abundance of plants co‐occurring in the same community. Vegetation‐plot data are spread across research groups, environmental agencies and biodiversity research centers and, thus, are rarely accessible at continental or global scales. Here we present the sPlot database, which collates vegetation plots worldwide to allow for the exploration of global patterns in taxonomic, functional and phylogenetic diversity at the plant community level. Results: sPlot version 2.1 contains records from 1,121,244 vegetation plots, which comprise 23,586,216 records of plant species and their relative cover or abundance in plots collected worldwide between 1885 and 2015. We complemented the information for each plot by retrieving climate and soil conditions and the biogeographic context (e.g., biomes) from external sources, and by calculating community‐weighted means and variances of traits using gap‐filled data from the global plant trait database TRY. Moreover, we created a phylogenetic tree for 50,167 out of the 54,519 species identified in the plots. We present the first maps of global patterns of community richness and community‐weighted means of key traits. Conclusions: The availability of vegetation plot data in sPlot offers new avenues for vegetation analysis at the global scale.

38. Different sets of traits explain abundance and distribution patterns of European plants at different spatial scales

Author

Sporbert, Maria, Welk, Erik, Seidler, Gunnar, Jandt, Ute, Aćić, Svetlana, Biurrun, Idoia, Campos, Juan Antonio, Čarni, Andraž, Cerabolini, Bruno E. L., Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, De Sanctis, Michele, Dziuba, Tetiana, Fagúndez, Jaime, Field, Richard, Golub, Valentin, He, Tianhua, Jansen, Florian, Lenoir, Jonathan, Marcenò, Corrado, Martín‐Forés, Irene, Moeslund, Jesper Erenskjold, Moretti, Marco, Niinemets, Ülo, Penuelas, Josep, Pérez‐Haase, Aaron, Vandvik, Vigdis, Vassilev, Kiril, Vynokurov, Denys, and Bruelheide, Helge

Subjects

2. Zero hunger, 580: Pflanzen (Botanik), fungi, food and beverages, 15. Life on land

Abstract

Aim: Plant functional traits summarize the main variability in plant form and function across taxa and biomes. We assess whether geographic range size, climatic niche size, and local abundance of plants can be predicted by sets of traits (trait syndromes) or are driven by single traits. Location: Eurasia. Methods: Species distribution maps were extracted from the Chorological Database Halle to derive information on the geographic range size and climatic niche size for 456 herbaceous, dwarf shrub and shrub species. We estimated local species abundances based on 740,113 vegetation plots from the European Vegetation Archive, where abundances were available as plant species cover per plot. We compiled a complete species-by-trait matrix of 20 plant functional traits from trait databases (TRY, BiolFlor and CLO-PLA). The relationships of species’ geographic range size, climatic niche size and local abundance with single traits and trait syndromes were tested with multiple linear regression models. Results: Generally, traits were more strongly related to local abundances than to broad-scale species distribution patterns in geographic and climatic space (range and niche size), but both were better predicted by trait combinations than by single traits. Local abundance increased with leaf area and specific leaf area (SLA). Geographic range size and climatic niche size both increased with SLA. While range size increased with plant height, niche size decreased with leaf carbon content. Conclusion: Functional traits matter for species’ abundance and distribution at both local and broad geographic scale. Local abundances are associated with different combinations of traits as compared to broad-scale distributions, pointing to filtering by different environmental and ecological factors acting at distinct spatial scales. However, traits related to the leaf economics spectrum were important for species’ abundance and occurrence at both spatial scales. This finding emphasizes the general importance of resource acquisition strategies for the abundance and distribution of herbaceous, dwarf shrub and shrub species.

39. EUNIS Habitat Classification : expert system, characteristic species combinations and distribution maps of European habitats

Author

Chytrý, Milan, Tichý, Lubomír, Hennekens, Stephan M., Knollová, Ilona, Janssen, John A. M., Rodwell, John S., Peterka, Tomáš, Marcenò, Corrado, Landucci, Flavia, Danihelka, Jiří, Hájek, Michal, Dengler, Jürgen, Novák, Pavel, Zukal, Dominik, Jiménez‐Alfaro, Borja, Mucina, Ladislav, Abdulhak, Sylvain, Aćić, Svetlana, Agrillo, Emiliano, Attorre, Fabio, Bergmeier, Erwin, Biurrun, Idoia, Boch, Steffen, Bölöni, János, Bonari, Gianmaria, Braslavskaya, Tatiana, Bruelheide, Helge, Campos, Juan Antonio, Čarni, Andraž, Casella, Laura, Ćuk, Mirjana, Ćušterevska, Renata, De Bie, Els, Delbosc, Pauline, Demina, Olga, Didukh, Yakiv, Dítě, Daniel, Dziuba, Tetiana, Ewald, Jörg, Gavilán, Rosario G., Gégout, Jean‐Claude, Giusso del Galdo, Gian Pietro, Golub, Valentin, Goncharova, Nadezhda, Goral, Friedemann, Graf, Ulrich, Indreica, Adrian, Isermann, Maike, Jandt, Ute, Jansen, Florian, Jansen, Jan, Jašková, Anni, Jiroušek, Martin, Kącki, Zygmunt, Kalníková, Veronika, Kavgacı, Ali, Khanina, Larisa, Yu. Korolyuk, Andrey, Kozhevnikova, Mariya, Kuzemko, Anna, Küzmič, Filip, Kuznetsov, Oleg L., Laiviņš, Māris, Lavrinenko, Igor, Lavrinenko, Olga, Lebedeva, Maria, Lososová, Zdeňka, Lysenko, Tatiana, Maciejewski, Lise, Mardari, Constantin, Marinšek, Aleksander, Napreenko, Maxim G., Onyshchenko, Viktor, Pérez‐Haase, Aaron, Pielech, Remigiusz, Prokhorov, Vadim, Rašomavičius, Valerijus, Rodríguez Rojo, Maria Pilar, Rūsiņa, Solvita, Schrautzer, Joachim, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Smagin, Viktor A., Stančić, Zvjezdana, Stanisci, Angela, Tikhonova, Elena, Tonteri, Tiina, Uogintas, Domas, Valachovič, Milan, Vassilev, Kiril, Vynokurov, Denys, Willner, Wolfgang, Yamalov, Sergey, Evans, Douglas, Palitzsch Lund, Mette, Spyropoulou, Rania, Tryfon, Eleni, and Schaminée, Joop H. J.

Subjects

Coastal habitat, Distribution map, 15. Life on land, Dune vegetation, Grassland, Habitat classification, Vegetation plot, Shrubland, Diagnostic species, Man‐made habitat, Vegetation database, Wetland, 14. Life underwater, Forest, 577: Ökologie, European Nature Information System (EUNIS), Expert system, European Vegetation Archive (EVA)

Abstract

Aim: The EUNIS Habitat Classification is a widely used reference framework for European habitat types (habitats), but it lacks formal definitions of individual habitats that would enable their unequivocal identification. Our goal was to develop a tool for assigning vegetation-plot records to the habitats of the EUNIS system, use it to classify a European vegetation-plot database, and compile statistically-derived characteristic species combinations and distribution maps for these habitats. Location: Europe. Methods: We developed the classification expert system EUNIS-ESy, which contains definitions of individual EUNIS habitats based on their species composition and geographic location. Each habitat was formally defined as a formula in a computer language combining algebraic and set-theoretic concepts with formal logical operators. We applied this expert system to classify 1,261,373 vegetation plots from the European Vegetation Archive (EVA) and other databases. Then we determined diagnostic, constant and dominant species for each habitat by calculating species-to-habitat fidelity and constancy (occurrence frequency) in the classified data set. Finally, we mapped the plot locations for each habitat. Results: Formal definitions were developed for 199 habitats at Level 3 of the EUNIS hierarchy, including 25 coastal, 18 wetland, 55 grassland, 43 shrubland, 46 forest and 12 man-made habitats. The expert system classified 1,125,121 vegetation plots to these habitat groups and 73,188 to other habitats, while 63,064 plots remained unclassified or were classified to more than one habitat. Data on each habitat were summarized in factsheets containing habitat description, distribution map, corresponding syntaxa and characteristic species combination. Conclusions: EUNIS habitats were characterized for the first time in terms of their species composition and distribution, based on a classification of a European database of vegetation plots using the newly developed electronic expert system EUNISESy. The data provided and the expert system have considerable potential for future use in European nature conservation planning, monitoring and assessment.

40. sPlotOpen : an environmentally balanced, open‐access, global dataset of vegetation plots

Author

Sabatini, Francesco Maria, Lenoir, Jonathan, Hattab, Tarek, Arnst, Elise Aimee, Chytrý, Milan, Dengler, Jürgen, De Ruffray, Patrice, Hennekens, Stephan M., Jandt, Ute, Jansen, Florian, Jiménez‐Alfaro, Borja, Kattge, Jens, Levesley, Aurora, Pillar, Valério D., Purschke, Oliver, Sandel, Brody, Sultana, Fahmida, Aavik, Tsipe, Aćić, Svetlana, Acosta, Alicia T. R., Agrillo, Emiliano, Alvarez, Miguel, Apostolova, Iva, Arfin Khan, Mohammed A. S., Arroyo, Luzmila, Attorre, Fabio, Aubin, Isabelle, Banerjee, Arindam, Bauters, Marijn, Bergeron, Yves, Bergmeier, Erwin, Biurrun, Idoia, Bjorkman, Anne D., Bonari, Gianmaria, Bondareva, Viktoria, Brunet, Jörg, Čarni, Andraž, Casella, Laura, Cayuela, Luis, Černý, Tomáš, Chepinoga, Victor, Csiky, János, Ćušterevska, Renata, De Bie, Els, Gasper, André Luis, De Sanctis, Michele, Dimopoulos, Panayotis, Dolezal, Jiri, Dziuba, Tetiana, El‐Sheikh, Mohamed Abd El‐Rouf Mousa, Enquist, Brian, Ewald, Jörg, Fazayeli, Farideh, Field, Richard, Finckh, Manfred, Gachet, Sophie, Galán‐de‐Mera, Antonio, Garbolino, Emmanuel, Gholizadeh, Hamid, Giorgis, Melisa, Golub, Valentin, Alsos, Inger Greve, Grytnes, John‐Arvid, Guerin, Gregory Richard, Gutiérrez, Alvaro G., Haider, Sylvia, Hatim, Mohamed Z., Hérault, Bruno, Hinojos Mendoza, Guillermo, Hölzel, Norbert, Homeier, Jürgen, Hubau, Wannes, Indreica, Adrian, Janssen, John A. M., Jedrzejek, Birgit, Jentsch, Anke, Jürgens, Norbert, Kącki, Zygmunt, Kapfer, Jutta, Karger, Dirk Nikolaus, Kavgacı, Ali, Kearsley, Elizabeth, Kessler, Michael, Khanina, Larisa, Killeen, Timothy, Korolyuk, Andrey, Kreft, Holger, Kühl, Hjalmar S., Kuzemko, Anna, Landucci, Flavia, Lengyel, Attila, Lens, Frederic, Lingner, Débora Vanessa, Liu, Hongyan, Lysenko, Tatiana, Mahecha, Miguel D., Marcenò, Corrado, Martynenko, Vasiliy, Moeslund, Jesper Erenskjold, Monteagudo Mendoza, Abel, Mucina, Ladislav, Müller, Jonas V., Munzinger, Jérôme, Naqinezhad, Alireza, Noroozi, Jalil, Nowak, Arkadiusz, Onyshchenko, Viktor, Overbeck, Gerhard E., Pärtel, Meelis, Pauchard, Aníbal, Peet, Robert K., Peñuelas, Josep, Pérez‐Haase, Aaron, Peterka, Tomáš, Petřík, Petr, Peyre, Gwendolyn, Phillips, Oliver L., Prokhorov, Vadim, Rašomavičius, Valerijus, Revermann, Rasmus, Rivas‐Torres, Gonzalo, Rodwell, John S., Ruprecht, Eszter, Rūsiņa, Solvita, Samimi, Cyrus, Schmidt, Marco, Schrodt, Franziska, Shan, Hanhuai, Shirokikh, Pavel, Šibík, Jozef, Šilc, Urban, Sklenář, Petr, Škvorc, Željko, Sparrow, Ben, Sperandii, Marta Gaia, Stančić, Zvjezdana, Svenning, Jens‐Christian, Tang, Zhiyao, Tang, Cindy Q., Tsiripidis, Ioannis, Vanselow, Kim André, Vásquez Martínez, Rodolfo, Vassilev, Kiril, Vélez‐Martin, Eduardo, Venanzoni, Roberto, Vibrans, Alexander Christian, Violle, Cyrille, Virtanen, Risto, Wehrden, Henrik, Wagner, Viktoria, Walker, Donald A., Waller, Donald M., Wang, Hua‐Feng, Wesche, Karsten, Whitfeld, Timothy J. S., Willner, Wolfgang, Wiser, Susan K., Wohlgemuth, Thomas, Yamalov, Sergey, Zobel, Martin, and Bruelheide, Helge

Subjects

Database, Functional trait, Vascular plant, Big data, 580: Pflanzen (Botanik), Biogeography, Biodiversity, 15. Life on land, 577: Ökologie, Macroecology, Vegetation plot

Abstract

Motivation: Assessing biodiversity status and trends in plant communities is critical for understanding, quantifying and predicting the effects of global change on ecosystems. Vegetation plots record the occurrence or abundance of all plant species co-occurring within delimited local areas. This allows species absences to be inferred, information seldom provided by existing global plant datasets. Although many vegetation plots have been recorded, most are not available to the global research community. A recent initiative, called ‘sPlot’, compiled the first global vegetation plot database, and continues to grow and curate it. The sPlot database, however, is extremely unbalanced spatially and environmentally, and is not open-access. Here, we address both these issues by (a) resampling the vegetation plots using several environmental variables as sampling strata and (b) securing permission from data holders of 105 local-to-regional datasets to openly release data. We thus present sPlotOpen, the largest open-access dataset of vegetation plots ever released. sPlotOpen can be used to explore global diversity at the plant community level, as ground truth data in remote sensing applications, or as a baseline for biodiversity monitoring. Main types of variable contained: Vegetation plots (n = 95,104) recording cover or abundance of naturally co-occurring vascular plant species within delimited areas. sPlotOpen contains three partially overlapping resampled datasets (c. 50,000 plots each), to be used as replicates in global analyses. Besides geographical location, date, plot size, biome, elevation, slope, aspect, vegetation type, naturalness, coverage of various vegetation layers, and source dataset, plot-level data also include community-weighted means and variances of 18 plant functional traits from the TRY Plant Trait Database. Spatial location and grain: Global, 0.01–40,000 m². Time period and grain: 1888–2015, recording dates. Major taxa and level of measurement: 42,677 vascular plant taxa, plot-level records. Software format: Three main matrices (.csv), relationally linked.

41. Testing macroecological abundance patterns : the relationship between local abundance and range size, range position and climatic suitability among European vascular plants

Author

Sporbert, Maria, Keil, Petr, Seidler, Gunnar, Bruelheide, Helge, Jandt, Ute, Aćić, Svetlana, Biurrun, Idoia, Campos, Juan Antonio, Čarni, Andraž, Chytrý, Milan, Ćušterevska, Renata, Dengler, Jürgen, Golub, Valentin, Jansen, Florian, Kuzemko, Anna, Lenoir, Jonathan, Marcenò, Corrado, Moeslund, Jesper Erenskjold, Pérez‐Haase, Aaron, Rūsiņa, Solvita, Šilc, Urban, Tsiripidris, Ioannis, Vandvik, Vigdis, Vasilev, Kiril, Virtanen, Risto, and Welk, Erik

Subjects

2. Zero hunger, Realized climatic niche, 580: Pflanzen (Botanik), Abundance, Climatic suitability, Commonness and rarity, Range size, Species distribution model, 15. Life on land, Resolution, 577: Ökologie, Vegetation‐plot data

Abstract

Aim: A fundamental question in macroecology centres around understanding the relationship between species’ local abundance and their distribution in geographical and climatic space (i.e. the multi-dimensional climatic space or climatic niche). Here, we tested three macroecological hypotheses that link local abundance to the following range properties: (a) the abundance–range size relationship, (b) the abundance–range centre relationship and (c) the abundance–suitability relationship. Location: Europe. Taxon: Vascular plants. Methods: Distribution range maps were extracted from the Chorological Database Halle to derive information on the range and niche sizes of 517 European vascular plant species. To estimate local abundance, we assessed samples from 744,513 vegetation plots in the European Vegetation Archive, where local species’ abundance is available as plant cover per plot. We then calculated the ‘centrality’, that is, the distance between the location of the abundance observation and each species’ range centre in geographical and climatic space. The climatic suitability of plot locations was estimated using coarse-grain species distribution models (SDMs). The relationships between centrality or climatic suitability with abundance was tested using linear models and quantile regression. We summarized the overall trend across species’ regression slopes from linear models and quantile regression using a meta-analytical approach. Results: We did not detect any positive relationships between a species’ mean local abundance and the size of its geographical range or climatic niche. Contrasting yet significant correlations were detected between abundance and centrality or climatic suitability among species. Main conclusions: Our results do not provide unequivocal support for any of the relationships tested, demonstrating that determining properties of species’ distributions at large grains and extents might be of limited use for predicting local abundance, including current SDM approaches. We conclude that environmental factors influencing individual performance and local abundance are likely to differ from those factors driving plant species’ distribution at coarse resolution and broad geographical extents.