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Emigration propensity and flight performance are decoupled in a butterfly. Ecosphere 9: .
Reduced host‐plant specialization is associated with the rapid range expansion of a Mediterranean butterfly. Journal of Biogeography 48: 3016.
Biodiversity and climate change in relation to the Natura 2000 network. Advances in Science and Research 3: 35.
Patterns of beta diversity in Europe: the role of climate, land cover and distance across scales. Journal of Biogeography 39: 1473.
Population turnover, habitat use and microclimate at the contracting range margin of a butterfly. Journal of Insect Conservation 19: 205.
Anthropogenic and natural barriers affect genetic connectivity in an Alpine butterfly. Molecular Ecology 30: 114.
Interacting effects of climate change and habitat fragmentation on drought-sensitive butterflies. Nature Climate Change 5: 941.
Assigning occurrence data to cryptic taxa improves climatic niche assessments: Biodecrypt, a new tool tested on European butterflies. Global Ecology and Biogeography 29: 1852.
Do all inter-patch movements represent dispersal? A mixed kernel study of butterfly mobility in fragmented landscapes. Journal of Animal Ecology 80: 1070.
Forest management and its impact on present and potential future Chinese insect biodiversity—A butterfly case study from Gansu Province. Journal for Nature Conservation 19: 285.
Large‐ and small‐scale geographic structures affecting genetic patterns across populations of an Alpine butterfly. Ecology and Evolution 11: 14697.
Phylogeny and palaeoecology of Polyommatus blue butterflies show Beringia was a climate-regulated gateway to the New World . Proceedings of the Royal Society B: Biological Sciences 278: 2737.
Inter‐ and intra‐specific differences in butterfly behaviour at boundaries. Insect Conservation and Diversity 7: 232.
Assessing the sensitivity of alpine birds to potential future changes in habitat and climate to inform management strategies. Biological Conservation 167: 127.
A new comprehensive trait database of European and Maghreb butterflies, Papilionoidea. Scientific Data 7: .
Differentiating the effects of climate and land use change on European biodiversity: A scenario analysis. Ambio 46: 277.
Species vulnerability to climate change: impacts on spatial conservation priorities and species representation. Global Change Biology 18: 2335.
Dispersal in a metapopulation of the critically endangered Danube Clouded Yellow butterfly Colias myrmidone: implications for conservation. Journal of Insect Conservation 23: 291.
Combining environmental niche models, multi‐grain analyses, and species traits identifies pervasive effects of land use on butterfly biodiversity across Italy. Global Change Biology 29: 1715.
Cold‐adapted species in a warming world – an explorative study on the impact of high winter temperatures on a continental butterfly. Entomologia Experimentalis et Applicata 151: 270.
RED LISTS OF EUROPEAN BUTTERFLIES (LEPIDOPTERA: HESPERIOIDEA ET PAPILIONOIDEA): PROBLEMS OF CRITERIA AND INTEGRATION OF RUSSIAN ECOLOGICAL AND FAUNAL DATA. Bulletin of the Moscow State Regional University (Natural Sciences) : 95.
Habitat preferences ofPapilio alexanorEsper, [1800]: implications for habitat management in the Italian Maritime Alps. Zoosystema 37: 169.
Modelling the scope to conserve an endemic‐rich mountain butterfly taxon in a changing climate. Insect Conservation and Diversity 16: 451.
Microtopography determines the habitat quality of a threatened peatland butterfly at its southern range margin. Journal of Insect Conservation 22: 707.
Protected areas do not mitigate biodiversity declines: A case study on butterflies. Diversity and Distributions 25: 217.
Resource availability drives trait composition of butterfly assemblages. Oecologia 190: 913.
Assessing the vulnerability of European butterflies to climate change using multiple criteria. Biodiversity and Conservation 19: 695.
Global pollinator declines: trends, impacts and drivers. Trends in Ecology & Evolution 25: 345.
Multiple stressors on biotic interactions: how climate change and alien species interact to affect pollination. Biological Reviews 85: 777.
Current and future effectiveness of Natura 2000 network in the central Alps for the conservation of mountain forest owl species in a warming climate. European Journal of Wildlife Research 61: 35.
Fitness implications of simulated climate change in three species of copper butterflies (Lepidoptera: Lycaenidae). Biological Journal of the Linnean Society : .
Signals of Climate Change in Butterfly Communities in a Mediterranean Protected Area. PLoS ONE 9: e87245.
Effects of recent and past climatic shifts on the genetic structure of the high mountain Yellow‐spotted ringlet butterfly Erebia manto (Lepidoptera, Satyrinae): a conservation problem. Global Change Biology 20: 2045.
The social fabric of citizen science—drivers for long-term engagement in the German butterfly monitoring scheme. Journal of Insect Conservation 22: 731.
Characterisation of polymorphic microsatellite loci in three copper butterfly species (Lycaena spp.). Molecular Biology Reports 46: 6585.
Accelerating extinction risk from climate change. Science 348: 571.
Past, current, and potential future distributions of unique genetic diversity in a cold‐adapted mountain butterfly. Ecology and Evolution 10: 11155.
The importance of hidden diversity for insect conservation: a case study in hoverflies (the Merodon atratus complex, Syrphidae, Diptera). Journal of Insect Conservation 23: 29.
Butterfly species respond differently to climate warming and land use change in the northern Alps. Science of The Total Environment 890: 164268.
Habitat associations of thermophilous butterflies are reduced despite climatic warming. Global Change Biology 18: 2720.
Individual plasticity drives boldness senescence in a territorial butterfly. Ethology 126: 1061.
Anthropogenic host plant expansion leads a nettle‐feeding butterfly out of the forest: consequences for larval survival and developmental plasticity in adult morphology. Evolutionary Applications 8: 363.
Global warming and plant–pollinator mismatches. Emerging Topics in Life Sciences 4: 77.
A complete time-calibrated multi-gene phylogeny of the European butterflies. ZooKeys 938: 97.
Mediterranean island biodiversity and climate change: the last 10,000 years and the future. Biodiversity and Conservation 25: 2597.
Biogeography, ecology and conservation ofErebia oeme(Hübner) in the Carpathians (Lepidoptera: Nymphalidae: Satyrinae). Annales de la Société entomologique de France (N.S.) 46: 486.
Bioclimatic context of species' populations determines community stability. Global Ecology and Biogeography 31: 1542.
Climate change vulnerability assessment of species. WIREs Climate Change 10: .
Morphological variability of Argynnis paphia (Lepidoptera: Nymphalidae) across different environmental conditions in eastern Slovakia. Biologia 76: 2941.
Adult thermoregulatory behaviour does not provide, by itself, an adaptive explanation for the reflectance–climate relationship (Bogert's pattern) in Iberian butterflies. Ecological Entomology : .
Phenology, mobility and behaviour of the arcto-alpine species Boloria napaea in its arctic habitat. Scientific Reports 9: .
Aridity could have driven the local extinction of a common and multivoltine butterfly. Ecological Entomology 48: 40.
Poleward range expansion without a southern contraction in the ground beetle Agonum viridicupreum (Coleoptera, Carabidae). ZooKeys 100: 333.
Modelling ecological systems in a changing world. Philosophical Transactions of the Royal Society B: Biological Sciences 367: 181.
Microclimate affects landscape level persistence in the British Lepidoptera. Journal of Insect Conservation 19: 237.
Dos and Don’ts for butterflies of the Habitats Directive of the European Union. Nature Conservation 1: 73.
Molecular phylogeny of the Palaearctic butterfly genus Pseudophilotes (Lepidoptera: Lycaenidae) with focus on the Sardinian endemic P. barbagiae. BMC Zoology 3: .
Conservation planning with insects at three different spatial scales. Ecography 33: 54.
Climate change effects on multi-taxa pollinator diversity and distribution along the elevation gradient of Mount Olympus, Greece. Ecological Indicators 132: 108335.
Are habitat changes driving the decline of the UK’s most threatened butterfly: the High Brown Fritillary Argynnis adippe (Lepidoptera: Nymphalidae)?. Journal of Insect Conservation 23: 351.
Morphological variation of Melanargia russiae (Esper, 1783) (Lepidoptera, Satyridae) from the main part of the range and in case of its expansion to the north under climate change conditions. Contemporary Problems of Ecology 10: 488.
A worthy conservation target? Revising the status of the rarest bumblebee of Europe. Insect Conservation and Diversity 14: 661.
Does specialisation affect genetic diversity in (pre-)Alpine populations of four species of Copper butterflies?. Journal of Insect Conservation 25: 321.
The Host Genera of Ant-Parasitic Lycaenidae Butterflies: A Review. Psyche: A Journal of Entomology 2012: 1.
Impact of landscape configuration and composition on pollinator communities across different European biogeographic regions. Frontiers in Ecology and Evolution 11: .
Ten challenges for 2010 and beyond to conserve Lepidoptera in Europe. Journal of Insect Conservation 15: 321.
Pollinator Diversity: Distribution, Ecological Function, and Conservation. Annual Review of Ecology, Evolution, and Systematics 48: 353.
Preserving Colias myrmidone in European cultural landscapes: requirements for the successful development from egg to higher larval stages at a Natura 2000 site in Romania. Journal of Insect Conservation 25: 643.
Climate change and its possible influence on the occurrence and importance of insect pests. Plant Protection Science 45: S53.
What more can plant scientists do to help save the green stuff?. Botanical Journal of the Linnean Society 166: 233.
Composition and diversity of butterflies (Lepidoptera, Papilionoidea) along an atmospheric pollution gradient in the Monterrey Metropolitan Area, Mexico. ZooKeys 1037: 73.
Sown wildflower strips offer promising long term results for butterfly conservation. Journal of Insect Conservation 26: 387.
Inter-annual variation in adult demography, but no sex bias in a large lowland population of the threatened Clouded Apollo Parnassius mnemosyne butterfly. The European Zoological Journal 90: 648.
The larval ecology of the butterfly Euphydryas desfontainii (Lepidoptera: Nymphalidae) in SW-Portugal: food plant quantity and quality as main predictors of habitat quality. Journal of Insect Conservation 17: 195.
Global warming favours light-coloured insects in Europe. Nature Communications 5: .
Population dynamics of the butterfly Pyrgus armoricanus after translocation beyond its northern range margin. Insect Conservation and Diversity 13: 617.
Effects of temperature and drought on early life stages in three species of butterflies: Mortality of early life stages as a key determinant of vulnerability to climate change?. Ecology and Evolution 7: 10871.
Better up, worse down: bidirectional consequences of three decades of climate change on a relict population of Erebia cassioides. Journal of Insect Conservation 18: 643.
Movements of a Specialist Butterfly in Relation to Mowing Management of Its Habitat Patches. Biology 12: 344.
High-Arctic butterflies become smaller with rising temperatures. Biology Letters 11: .
Genomic evidence for three distinct species in the Erebia manto complex in Central Europe (Lepidoptera, Nymphalidae). Conservation Genetics 24: 293.
Developing European conservation and mitigation tools for pollination services: approaches of the STEP (Status and Trends of European Pollinators) project. Journal of Apicultural Research 50: 152.
Mitigating the precipitous decline of terrestrial European insects: Requirements for a new strategy. Biodiversity and Conservation 28: 1343.
A decision framework for considering climate change adaptation in biodiversity conservation planning. Journal of Applied Ecology 49: 1247.
Latitudinal and altitudinal variation in ecologically important traits in a widespread butterfly. Biological Journal of the Linnean Society 128: 742.
Population Genetic Differences along a Latitudinal Cline between Original and Recently Colonized Habitat in a Butterfly. PLoS ONE 5: e13810.
Strong reduction in diapause survival under warm and humid overwintering conditions in a temperate‐zone butterfly. Population Ecology 61: 150.
CLIMBER: Climatic niche characteristics of the butterflies in Europe. ZooKeys 367: 65.
Large spatial scale effects of rising temperatures: modelling a dragonfly’s life cycle and range throughout Europe. Insect Conservation and Diversity 5: 461.
Threatened European butterflies concentrate in areas of strong climatic change and atmospheric deposition pressure. Biological Conservation 288: 110352.
Climate Change and Evolutionary Adaptations at Species' Range Margins. Annual Review of Entomology 56: 143.
The intraspecific variability of Colias croceus (Geoffroy, 1785) and C. erate (Esper, 1805) (Lepidoptera, Pieridae) from the perspective of comparative morphology. Zoomorphology 140: 353.
Implications of Pollinator Biodiversity Decline for Food Security, Economy, and Pollinator Conservation Policies. E3S Web of Conferences 259: 01006.
Mosaic landscapes provide conservation pockets for an endangered species: Colias myrmidone in Romania. Insect Conservation and Diversity 15: 359.
The central Alps comprise a major dispersal barrier between western and eastern populations of two butterfly species. Journal of Biogeography 49: 1508.
Succession matters: Community shifts in moths over three decades increases multifunctionality in intermediate successional stages. Scientific Reports 9: .
Applying IUCN criteria to invertebrates: How red is the Red List of European butterflies?. Biological Conservation 144: 470.
Biodiversity impacts of climate change – the PRONAS software as educational tool. Web Ecology 15: 49.
Butterfly abundance in a warming climate: patterns in space and time are not congruent. Journal of Insect Conservation 15: 233.
Nitrogen fertilization and high plant growing temperature increase herbivore performance. Ecosphere 12: .
Variation in adult stress resistance does not explain vulnerability to climate change in copper butterflies. Insect Science 25: 894.
An experimental test of changed personality in butterflies from anthropogenic landscapes. Behavioral Ecology and Sociobiology 74: .
Simulating effects of climate change under direct and diapause development in a butterfly. Entomologia Experimentalis et Applicata 158: 60.
Butterfly diversity and biogeography on the Croatian karst mountain Biokovo: Vertical distribution and preference for altitude and aspect?. European Journal of Entomology 108: 623.
Abundant Citizen Science Data Reveal That the Peacock Butterfly Aglais io Recently Became Bivoltine in Belgium. Insects 12: 683.
Modelling the effect of temperature on the range expansion of species by reaction–diffusion equations. Mathematical Biosciences 235: 171.
Challenges and bottlenecks for butterfly conservation in a highly anthropogenic region: Europe's worst case scenario revisited. Biological Conservation 274: 109732.
A novel tool to assess the effect of intraspecific spatial niche variation on species distribution shifts under climate change. Global Ecology and Biogeography 29: 590.
A question of adaptability: Climate and habitat change lower trait diversity in butterfly communities in south-western Germany. European Journal of Entomology 110: 633.
Light and Malaise traps tell different stories about the spatial variations in arthropod biomass and method‐specific insect abundance. Insect Conservation and Diversity 15: 655.
Latitudinal gradients in butterfly population variability are influenced by landscape heterogeneity. Ecography 37: 863.
Morphological Variability of the Satyrid Butterflies, Aphantopus hyperantus and Erebia ligea (Lepidoptera, Satyridae) in Allopatric and Allochronous Micropopulations. Entomological Review 101: 902.
Applying IUCN Red List criteria at a small regional level: A test case with butterflies in Flanders (north Belgium). Biological Conservation 145: 258.
The importance of unique populations for conservation: the case of the great orme’s head grayling butterfly Hipparchia semele (Linnaeus, 1758) (Lepidoptera: Satyrinae). Journal of Insect Conservation 23: 381.
Sexual differences in the morphology and movement of a butterfly: Good shape does not make good dispersers. European Journal of Entomology 116: 468.
The need for large‐scale distribution data to estimate regional changes in species richness under future climate change. Diversity and Distributions 23: 1393.
The decline of butterflies in Europe: Problems, significance, and possible solutions. Proceedings of the National Academy of Sciences 118: .
Expanding insect pollinators in the Anthropocene. Biological Reviews 96: 2755.
Potential distribution models and the effect of climatic change on the distribution of Phengaris nausithous considering its food plant and host ants. Journal of Insect Conservation 19: 1101.
Behavioural repeatability is affected by early developmental conditions in a butterfly. Animal Behaviour 157: 219.
Otakar Kudrna 1939–2021. Nota Lepidopterologica 44: 133.
The complete mitochondrial genome of the Alpine black swallowtail,Papilio Maackii(Insecta: Lepidoptera: Papilionidae). Mitochondrial DNA 24: 639.
Evolutionary consequences of climate‐induced range shifts in insects. Biological Reviews 91: 1050.
A butterfly hotspot in western China, its environmental threats and conservation. Journal of Insect Conservation 15: 617.
Integrating national Red Lists for prioritising conservation actions for European butterflies. Journal of Insect Conservation 23: 301.
Grizzled Skippers stuck in the south: Population‐level responses of an early‐successional specialist butterfly to climate across its UK range over 40 years. Diversity and Distributions 27: 962.
Taxonomy of hybridizing Colias croceus (Geoffroy, 1785) and Colias erate (Esper, 1805) (Lepidoptera, Pieridae) in light of mitochondrial and nuclear DNA, with occurrence and effects of Wolbachia infection. Zoologischer Anzeiger 299: 73.
Large extents of intensive land use limit community reorganization during climate warming. Global Change Biology 23: 2272.
Use of the single rope access technique reveals habitat use patterns for the elusive Erebia christi (Lepidoptera: Nymphalidae). Journal of Insect Conservation 25: 77.
Plants, Birds and Butterflies: Short-Term Responses of Species Communities to Climate Warming Vary by Taxon and with Altitude. PLoS ONE 9: e82490.
Local populations of endangered Maculinea (Phengaris) butterflies are flood resistant. Journal of Insect Conservation 17: 1105.
Long-distance dispersal of migrant butterflies to the Arctic Ocean islands, with a record of Nymphalis xanthomelas at the northern edge of Novaya Zemlya (76.95°N). Nota Lepidopterologica 44: 73.
The importance of the gravel excavation industry for the conservation of grassland butterflies. Biological Conservation 148: 180.
Temperature drives abundance fluctuations, but spatial dynamics is constrained by landscape configuration: Implications for climate‐driven range shift in a butterfly. Journal of Animal Ecology 86: 1339.
Erebia epiphronandErebia orientalis: sibling butterfly species with contrasting histories. Biological Journal of the Linnean Society 126: 338.
Wildlife conservation strategies should incorporate both taxon identity and geographical context ‐ further evidence with bumblebees. Diversity and Distributions 26: 1741.
Effects of climate change on the distribution of ecologically interacting species: butterflies and their main food plants in Spain. Ecography 37: 1063.
Metapopulation Patterns of Iberian Butterflies Revealed by Fuzzy Logic. Insects 12: 392.
Habitat and host plant use of the Large Copper Butterfly Lycaena dispar in an urban environment. Journal of Insect Conservation 16: 709.
Distribution Atlas of Butterflies in Europe. Zoological Journal of the Linnean Society 165: 720.
Contrasting genetic responses to habitat fragmentation for two Lycaenid butterfly species. Insect Conservation and Diversity 15: 337.
The distribution pattern of mire specialist butterflies in raised bogs of the northern lowlands of Central Europe. Nota Lepidopterologica 45: 41.
The distribution and status of Sage Skipper Muschampia proto (Ochsenheimer, 1808) (Lepidoptera, Hesperiidae) at the limit of its range in the north-western Balkans. Nota Lepidopterologica 43: 211.
A combined approach of methods for determining the regional assessment of the disjunct plant Primula pedemontana in Spain. Plant Biosystems - An International Journal Dealing with all Aspects of Plant Biology 151: 191.
Contrasting effects of altitude on species groups with different traits in a non-fragmented montane temperate forest. Nature Conservation 37: 99.
The butterfly fauna of the Italian Maritime Alps: results of the EDIT project. Zoosystema 37: 139.
Climate change and biological invasions: evidence, expectations, and response options. Biological Reviews 92: 1297.
Climate change impacts on pollination. Nature Plants 2: .
The role of climate change in pollinator decline across the Northern Hemisphere is underestimated. Science of The Total Environment 775: 145788.
Threatened grassland butterflies as indicators of microclimatic niches along an elevational gradient – Implications for conservation in times of climate change. Ecological Indicators 94: 83.
Complete mitochondrial genome ofPapilio syfanius(Lepidoptera: Papilionidae). Mitochondrial DNA 27: 403.
Genetic assessment and climate modelling of the Iberian specialist butterfly Euchloe bazae (Lepidoptera: Pieridae). Insect Conservation and Diversity 15: 594.
Mobility, habitat selection and population connectivity of the butterfly Lycaena helle in central Sweden. Journal of Insect Conservation 24: 821.
Direct and indirect effects of weather variability in a specialist butterfly. Ecological Entomology 41: 263.
Forecasts of butterfly future richness change in the southwest Mediterranean. The role of sampling effort and non-climatic variables. Journal of Insect Conservation 26: 639.
When habitat management can be a bad thing: effects of habitat quality, isolation and climate on a declining grassland butterfly. Journal of Insect Conservation 18: 965.
Increasing range mismatching of interacting species under global change is related to their ecological characteristics. Global Ecology and Biogeography 21: 88.
The Iberian Peninsula as a potential source for the plant species pool in Germany under projected climate change. Plant Ecology 207: 191.
Drivers and pressures behind insect decline in Central and Western Europe based on long-term monitoring data. PLOS ONE 18: e0289565.
Evaluating Presence Data versus Expert Opinions to Assess Occurrence, Habitat Preferences and Landscape Permeability: A Case Study of Butterflies. Environments 5: 36.
Identifying fine‐scale habitat preferences of threatened butterflies using airborne laser scanning. Diversity and Distributions 27: 1251.
How threatened are alpine environments? a cross taxonomic study. Biodiversity and Conservation 21: 517.
The potential of species distribution modelling for reintroduction projects: the case study of the Chequered Skipper in England. Journal of Insect Conservation 23: 419.
Constructing a hybrid species distribution model from standard large-scale distribution data. Ecological Modelling 373: 39.
Using species distribution models for IUCN Red Lists of threatened species. Journal of Insect Conservation 18: 427.
A meta‐analysis of dispersal in butterflies. Biological Reviews 85: 625.
Similarities in butterfly emergence dates among populations suggest local adaptation to climate. Global Change Biology 21: 3313.
Identification of potential source and sink areas for butterflies on the Iberian Peninsula. Insect Conservation and Diversity 11: 479.
Disproportional risk for habitat loss of high‐altitude endemic species under climate change. Global Change Biology 17: 990.
Lepidoptera Conservation in a Changing World. Chapter 10: 85.
Pollination Biology. Chapter 17: 545.
Klimawandel in Deutschland. Chapter 15: 151.
Global Climate Change and Terrestrial Invertebrates. : 9.
Lepidoptera Conservation in a Changing World. Chapter 14: 141.
Horticulture: Plants for People and Places, Volume 2. Chapter 10: 817.
Insect Conservation: Past, Present and Prospects. Chapter 6: 133.
Climate Change and the Economic Importance and Damages of Insects. chapter 7: 147.
Lepidoptera Conservation in a Changing World. Chapter 33: 361.
Biodiversität: Grundlagen, Gefährdung, Schutz. Chapter 12: 335.
Naturschutzrecht im Klimawandel. Chapter 3: 7.
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