Publikationen
- [ 2024 ]
- [ 2023 ]
- [ 2022 ]
- [ 2021 ]
- [ 2020 ]
- [ 2019 ]
- [ 2018 ]
- [ 2017 ]
- [ 2016 ]
- [ 2015 ]
- [ 2014 ]
- [ 2013 ]
- [ 2012 ]
- [ 2011 ]
- [ 2010 ]
- [ 2009 ]
- [ 2008 ]
- [ 2006 ]
2024[ to top ]
-
Micro‐ and macroclimate interactively shape diversity, niches and traits of Orthoptera communities along elevational gradients. Diversity and Distributions.(2024)
- [ DOI ]
-
A straightforward protocol to sample morphological traits of dragonflies and damselflies in the field. Ecology and Evolution 14.(2024)
- [ DOI ]
-
Quantitative description of six fish species’ gut contents and prey abundances in the Baltic Sea (1968--1978). Scientific Data 11: 236.(2024)
- [ DOI ]
-
Flexible foraging behaviour increases predator vulnerability to climate change. Nature Climate Change.(2024)
- [ DOI ]
-
Heatwave predicts a shady future for insects: impacts of an extreme weather event on a chalk grassland in Bedfordshire, UK. Journal of Insect Conservation.(2024)
- [ DOI ]
-
Effects of earthworm invasion on soil properties and plant diversity after two years of field experiment. NeoBiota 94: 31–56.(2024)
- [ DOI ]
-
Hurricane‐induced pollinator shifts in a tightly coadapted plant–hummingbird mutualism. New Phytologist.(2024)
- [ DOI ]
-
Communicating soil biodiversity research to kids around the world.(2024)
- [ DOI ]
-
Global fine-resolution data on springtail abundance and community structure. Scientific Data 11.(2024)
- [ DOI ]
-
Dispersal, glacial refugia and temperature shape biogeographical patterns in European freshwater biodiversity. Global Ecology and Biogeography.(2024)
- [ DOI ]
-
Habitat associations of day-flying Lepidoptera and their foodplants within nature reserves in Bedfordshire, UK. Journal of Insect Conservation.(2024)
- [ DOI ]
2023[ to top ]
-
Tropical butterflies use thermal buffering and thermal tolerance as alternative strategies to cope with temperature increase. Journal of Animal Ecology 92: 1759–1770.(2023)
- [ DOI ]
-
Global change in above-belowground multitrophic grassland communities. Research Ideas and Outcomes 9.(2023)
- [ DOI ]
-
Modelling potential biotope composition on a regional scale revealed that climate variables are stronger drivers than soil variables. Diversity and Distributions 29: 492–508.(2023)
- [ DOI ]
-
Ecosystem consequences of invertebrate decline. Current Biology 33: 4538-4547.e5.(2023)
- [ DOI ]
-
From bottom‐up to top‐down control of invertebrate herbivores in a retrogressive chronosequence. Ecology Letters 26: 411–424.(2023)
- [ DOI ]
-
Globally invariant metabolism but density-diversity mismatch in springtails. Nature Communications 14.(2023)
- [ DOI ]
-
Thermoregulatory ability and mechanism do not differ consistently between neotropical and temperate butterflies. Global Change Biology 29: 4180–4192.(2023)
- [ DOI ]
-
Potential effects of future climate change on global reptile distributions and diversity. Global Ecology and Biogeography 32: 519–534.(2023)
- [ DOI ]
-
Microhabitat conditions remedy heat stress effects on insect activity. Global Change Biology 29: 3747–3758.(2023)
- [ DOI ]
-
Body colour drives optimal insect phenology via thermoregulation.(2023)
- [ DOI ]
-
Seasonal variation in dragonfly assemblage colouration suggests a link between thermal melanism and phenology. Nature Communications 14.(2023)
- [ DOI ]
-
Trait overdispersion in dragonflies reveals the role and drivers of competition in community assembly across space and season. Ecography.(2023)
- [ DOI ]
-
European Habitats Directive has fostered monitoring but not prevented species declines. Conservation Letters 16.(2023)
- [ DOI ]
-
Hot topics in butterfly research: Current knowledge and gaps in understanding of the impacts of temperature on butterflies. Insect Conservation and Diversity 17: 1–15.(2023)
- [ DOI ]
-
Global change impacts on bird biodiversity in South Asia: potential effects of future land-use and climate change on avian species richness in Pakistan. PeerJ 11: e16212.(2023)
- [ DOI ]
2022[ to top ]
-
Potential future climate change effects on global reptile distributions and diversity.(2022)
- [ DOI ]
-
Projected climate change impacts on the phylogenetic diversity of the world’s terrestrial birds: more than species numbers. Proceedings of the Royal Society B: Biological Sciences 289.(2022)
- [ DOI ]
-
Oviposition behaviour and emergence through time of the small blue butterfly (Cupido minimus) in a nature reserve in Bedfordshire, UK. Journal of Insect Conservation 26: 43-58.(2022)
- [ DOI ]
-
Global impacts of climate change on avian functional diversity. Ecology Letters 25: 673-685.(2022)
- [ DOI ]
-
Aboveground impacts of a belowground invader: how invasive earthworms alter aboveground arthropod communities in a northern North American forest. Biology Letters 18.(2022)
- [ DOI ]
-
Heat it up to slow it down: Individual energetics reveal how warming reduces stream decomposition. Journal of Animal Ecology 91: 1944–1947.(2022)
- [ DOI ]
-
Environmental drivers of local abundance–mass scaling in soil animal communities. Oikos 2023.(2022)
- [ DOI ]
-
Climate change aggravates anthropogenic threats of the endangered savanna tree Pterocarpus erinaceus (Fabaceae) in Burkina Faso. Journal for Nature Conservation 70: 126299.(2022)
- [ DOI ]
-
Scientiststextquotesingle warning on climate change and insects. Ecological Monographs.(2022)
- [ DOI ]
-
Climate-change effects on the sex ratio of free-living soil nematodes – perspective and prospect.(2022)
- [ DOI ]
2021[ to top ]
-
Representation of the worldtextquotesingles biophysical conditions by the global protected area network. Conservation Biology 36.(2021)
- [ DOI ]
-
Above- and belowground biodiversity jointly tighten the P cycle in agricultural grasslands. Nature Communications 12.(2021)
- [ DOI ]
-
Towards more integration of physiology, dispersal and land-use change to understand the responses of species to climate change. Journal of Experimental Biology 224.(2021)
- [ DOI ]
-
Thermal acclimation increases the stability of a predator–prey interaction in warmer environments. Global Change Biology 27: 3765–3778.(2021)
- [ DOI ]
-
Earthworm invasion causes declines across soil fauna size classes and biodiversity facets in northern North American forests. Oikos 130: 766–780.(2021)
- [ DOI ]
-
Oil palm and rubber expansion facilitates earthworm invasion in Indonesia. Biological Invasions 23: 2783–2795.(2021)
- [ DOI ]
-
Broad‐scale patterns of geographic avoidance between species emerge in the absence of fine‐scale mechanisms of coexistence. Diversity and Distributions 27: 1606–1618.(2021)
- [ DOI ]
-
Consistent oviposition preferences of the Duke of Burgundy butterfly over 14 years on a chalk grassland reserve in Bedfordshire, UK. Journal of Insect Conservation 25: 611-628.(2021)
- [ DOI ]
-
For flux’s sake: General considerations for energy‐flux calculations in ecological communities. Ecology and Evolution 11: 12948–12969.(2021)
- [ DOI ]
-
Considering sustainability thresholds for BECCS in IPCC and biodiversity assessments. GCB Bioenergy 13: 510–515.(2021)
- [ DOI ]
-
Out of the dark: Using energy flux to connect above- and belowground communities and ecosystem functioning. European Journal of Soil Science 73.(2021)
- [ DOI ]
-
Soil fauna diversity and chemical stressors: a review of knowledge gaps and roadmap for future research. Ecography 44: 845–859.(2021)
- [ DOI ]
2020[ to top ]
-
Trade-offs between multifunctionality and profit in tropical smallholder landscapes. Nature Communications 11.(2020)
- [ DOI ]
-
DNA metabarcoding and spatial modelling link diet diversification with distribution homogeneity in European bats. Nature Communications 11.(2020)
- [ DOI ]
-
Trait-Based Assessments of Climate-Change Impacts on Interacting Species. Trends in Ecology & Evolution 35: 319-328.(2020)
- [ DOI ]
-
Climate change impacts on the phylogenetic diversity of the worldtextquotesingles terrestrial birds: more than species numbers.(2020)
- [ DOI ]
-
The results of biodiversity–ecosystem functioning experiments are realistic. Nature Ecology & Evolution 4: 1485–1494.(2020)
- [ DOI ]
-
Functional losses in ground spider communities due to habitat structure degradation under tropical land‐use change. Ecology 101.(2020)
- [ DOI ]
-
Trophic resource partitioning drives fine-scale coexistence in cryptic bat species.(2020)
- [ DOI ]
-
Open Science principles for accelerating trait-based science across the Tree of Life. Nature Ecology & Evolution 4: 294–303.(2020)
- [ DOI ]
-
Global impacts of climate change on avian functional diversity.(2020)
- [ DOI ]
-
Land-use intensity alters networks between biodiversity, ecosystem functions, and services. Proceedings of the National Academy of Sciences 117: 28140–28149.(2020)
- [ DOI ]
2019[ to top ]
-
Ignoring biotic interactions overestimates climate change effects: The potential response of the spotted nutcracker to changes in climate and resource plants. Journal of Biogeography 47: 143–154.(2019)
- [ DOI ]
-
Consistent temperature dependence of functional response parameters and their use in predicting population abundance. Journal of Animal Ecology 88: 1670–1683.(2019)
- [ DOI ]
-
Towards an ecological trait‐data standard. Methods in Ecology and Evolution 10: 2006–2019.(2019)
- [ DOI ]
-
Host assemblage and environment shape \($\upbeta$\)-diversity of freshwater parasites across diverse taxa at a continental scale. Global Ecology and Biogeography 29: 38-49.(2019)
- [ DOI ]
-
Interaction strength in plant-pollinator networks: Are we using the right measure?. PLOS ONE 14: e0225930.(2019)
- [ DOI ]
-
Macroecology in the age of Big Data – Where to go from here?. Journal of Biogeography 47: 1–12.(2019)
- [ DOI ]
-
Phylogeny of the Eocene Aphalarinae (Hemiptera: Psylloidea) from Baltic amber, with description of a new species using X-ray micro-computed tomography scanning, and a new genus synonymy. Journal of Systematic Palaeontology 17: 1233–1244.(2019)
- [ DOI ]
-
Macroecology as a hub between research disciplines: Opportunities, challenges and possible ways forward. Journal of Biogeography 47: 13–15.(2019)
- [ DOI ]
-
Macroecology as a hub between research disciplines: Opportunities, challenges and possible ways forward. Journal of Biogeography 47: 13-15.(2019)
- [ DOI ]
-
Considering adaptive genetic variation in climate change vulnerability assessment reduces species range loss projections. Proceedings of the National Academy of Sciences 116: 10418–10423.(2019)
- [ DOI ]
-
Ecosystem responses to exotic earthworm invasion in northern North American forests. Research Ideas and Outcomes 5.(2019)
- [ DOI ]
-
Predator traits determine food-web architecture across ecosystems. Nature Ecology & Evolution 3: 919–927.(2019)
- [ DOI ]
-
A comparison of macroecological and stacked species distribution models to predict future global terrestrial vertebrate richness. Journal of Biogeography 47: 114–129.(2019)
- [ DOI ]
2018[ to top ]
-
Evolutionary processes, dispersal limitation and climatic history shape current diversity patterns of European dragonflies. Ecography 41: 795-804.(2018)
-
Moving in the Anthropocene: Global reductions in terrestrial mammalian movements. Science 359: 466-469.(2018)
-
Bioenergy cropland expansion may offset positive effects of climate change mitigation for global vertebrate diversity. Proceedings of the National Academy of Sciences 115: 13294-13299.(2018)
- [ DOI ]
-
Energy Flux: The Link between Multitrophic Biodiversity and Ecosystem Functioning. Trends in Ecology & Evolution 33: 186–197.(2018)
- [ DOI ]
-
Testing the heat dissipation limitation hypothesis: basal metabolic rates of endotherms decrease with increasing upper and lower critical temperatures. PeerJ 6: e5725.(2018)
- [ DOI ]
-
Applying generalized allometric regressions to predict live body mass of tropical and temperate arthropods. Ecology and Evolution 8: 12737–12749.(2018)
- [ DOI ]
-
Does metabolism constrain bird and mammal ranges and predict shifts in response to climate change?. Ecology and Evolution 8: 12375–12385.(2018)
- [ DOI ]
-
Bioenergy cropland expansion may offset positive effects of climate change mitigation for global vertebrate diversity. Proceedings of the National Academy of Sciences 115: 13294-13299.(2018)
- [ DOI ]
-
fluxweb: An(2018)
R package to easily estimate energy fluxes in food webs. Methods in Ecology and Evolution 10: 270–279.- [ DOI ]
-
Application of optical unmanned aerial vehicle-based imagery for the inventory of natural regeneration and standing deadwood in post-disturbed spruce forests.. International Journal of Remote Sensing.(2018)
2017[ to top ]
-
Direct and cascading impacts of tropical land-use change on multi-trophic biodiversity. Nature Ecology & Evolution 1: 1511–1519.(2017)
- [ DOI ]
-
It’s not (all) about the money textemdash supporting IPBES through challenging times. Frontiers of Biogeography 9.(2017)
- [ DOI ]
-
Global patterns of thermal tolerances and vulnerability of endotherms to climate change remain robust irrespective of varying data suitability criteria. Proceedings of the Royal Society B: Biological Sciences 284: 20170232.(2017)
- [ DOI ]
-
The influence of thermal tolerances on geographical ranges of endotherms. Global Ecology and Biogeography 26: 650-668.(2017)
-
Assessing the impacts of 1.5 degrees C global warming - simulation protocol of the Inter-Sectoral Impact Model Intercomparison Project (ISIMIP2b). Geoscientific Model Development 10: 4321-4345.(2017)
-
A framework integrating physiology, dispersal and land-use to project species ranges under climate change. Journal of Avian Biology 48: 1532-1548.(2017)
-
Cross-taxa generalities in the relationship between population abundance and ambient temperatures. Proceedings of the Royal Society B: Biological Sciences 284: 20170870.(2017)
- [ DOI ]
-
Resource stoichiometry and availability modulate species richness and biomass of tropical litter macro‐invertebrates. Journal of Animal Ecology 86: 1114–1123.(2017)
- [ DOI ]
-
Individual-tree- and stand-based development following natural disturbance in a heterogeneously structured forest: A LiDAR-based approach. Ecological Informatics 38: 12-25.(2017)
- [ DOI ]
-
Decreasing Stoichiometric Resource Quality Drives Compensatory Feeding across Trophic Levels in Tropical Litter Invertebrate Communities. The American Naturalist 190: 131–143.(2017)
- [ DOI ]
-
Interactive effects of temperature and habitat complexity on freshwater communities. Ecology and Evolution 7: 9333–9346.(2017)
- [ DOI ]
-
Multi-model estimation of understorey shrub, herb and moss cover in temperate forest stands by laser scanner data. Forestry.(2017)
-
Phylogenetic signals in thermal traits remain stronger in the tropics if we can believe published physiological data. A reply to McKechnie et al., “Data quality problems undermine analyses of endotherm upper critical temperatures”. Journal of Biogeography 44: 2427–2431.(2017)
- [ DOI ]
-
Cross-realm assessment of climate change impacts on species’ abundance trends. Nature Ecology & Evolution 1.(2017)
2016[ to top ]
-
Macroecology meets IPBES. Frontiers of Biogeography 7.(2016)
- [ DOI ]
-
Hatte die Usutu-Virus-Epidemie von 2011 und Folgejahren einen Einfluss auf die Brutbestände ausgewählter Vogelarten in Nordbaden?. Ornithologisches Jahresheft Baden-Württemberg.(2016)
-
Ecological networks are more sensitive to plant than to animal extinction under climate change. Nature Communications 7.(2016)
-
Changes in abundances of forest understorey birds on Africa’s highest mountain suggest subtle effects of climate change. Diversity and Distributions 22: 288-299.(2016)
-
Species richness and biomass explain spatial turnover in ecosystem functioning across tropical and temperate ecosystems. Philosophical Transactions of the Royal Society B: Biological Sciences 371: 20150279.(2016)
- [ DOI ]
-
Land-use choices follow profitability at the expense of ecological functions in Indonesian smallholder landscapes. Nature Communications 7.(2016)
- [ DOI ]
-
Twenty-million-year relationship between mammalian diversity and primary productivity. Proceedings of the National Academy of Sciences of the United States of America 113: 10908-10913.(2016)
2015[ to top ]
-
Integrating climate change vulnerability assessments from species distribution models and trait-based approaches. Biological Conservation 190: 167-178.(2015)
-
Global variation in thermal physiology of birds and mammals: evidence for phylogenetic niche conservatism only in the tropics. Journal of Biogeography 42: 2187-2196.(2015)
-
Metabolic heat production and thermal conductance are mass-independent adaptations to thermal environment in birds and mammals. Proceedings of the National Academy of Sciences of the United States of America 112: 15934-15939.(2015)
-
Functional diversity and stability of litter-invertebrate communities following land-use change in Sumatra, Indonesia. Biological Conservation 191: 750-758.(2015)
- [ DOI ]
-
A cross-taxon analysis of the impact of climate change on abundance trends in central Europe. Biological Conservation 187: 41-50.(2015)
-
Body size and the behavioral ecology of insects: linking individuals to ecological communities. Current Opinion in Insect Science 9: 24-30.(2015)
- [ DOI ]
2014[ to top ]
-
A comparative analysis of dispersal syndromes in terrestrial and semi-terrestrial animals. Ecology Letters 17: 1039-1052.(2014)
-
Conservation implications of omitting narrow-ranging taxa from species distribution models, now and in the future. Diversity and Distributions 20: 1307-1320.(2014)
-
Consequences of tropical land use for multitrophic biodiversity and ecosystem functioning. Nat Commun 5.(2014)
-
Global variation in thermal tolerances and vulnerability of endotherms to climate change. Proceedings of the Royal Society B-Biological Sciences 281.(2014)
2013[ to top ]
-
Recent range shifts of European dragonflies provide support for an inverse relationship between habitat predictability and dispersal. Global Ecology and Biogeography 22: 403-409.(2013)
-
Diversity in time and space: wanted dead and alive. Trends in Ecology & Evolution 28: 509-516.(2013)
2012[ to top ]
-
Climate-induced changes in bottom-up and top-down processes independently alter a marine ecosystem. Philosophical Transactions of the Royal Society B: Biological Sciences 367: 2962-2970.(2012)
-
Habitat stability affects dispersal and the ability to track climate change. Biology Letters 8: 639-643.(2012)
-
What’s on the horizon for macroecology?. Ecography 35: 673-683.(2012)
2011[ to top ]
-
Host diversity and latitude drive trematode diversity patterns in the European freshwater fauna. Global Ecology and Biogeography 20: 675-682.(2011)
-
Additive threats from pathogens, climate and land-use change for global amphibian diversity. Nature 480: 516-U137.(2011)
-
Range size patterns in European freshwater trematodes. Ecography 34: 982-989.(2011)
-
Rethinking species’ ability to cope with rapid climate change. Global Change Biology 17: 2987-2990.(2011)
2010[ to top ]
-
Habitat availability does not explain the species richness patterns of European lentic and lotic freshwater animals. Journal of Biogeography 37: 1919-1926.(2010)
-
Phylogenetic signals in the climatic niches of the world’s amphibians. Ecography 33: 242-250.(2010)
2009[ to top ]
-
Partitioning and mapping uncertainties in ensembles of forecasts of species turnover under climate change. Ecography 32: 897-906.(2009)
2008[ to top ]
-
Latitudinal variation of diversity in European freshwater animals is not concordant across habitat types. Global Ecology and Biogeography 17: 539-546.(2008)
2006[ to top ]
-
Lentic odonates have larger and more northern ranges than lotic species. Journal of Biogeography 33: 63-70.(2006)
-
Expedition Anthropozän. . MyCoRe Community, 2024.
-
Els Odonats del Delta del Llobregat. . In . 2018.