@article{MTMT:34623316,
	title = {Floristic records from Northern Hungary IV. Helleborus dumetorum from the Cserhát Hills and other occurrences},
	url = {https://m2.mtmt.hu/api/publication/34623316},
	author = {Vojtkó, András},
	doi = {10.17542/kit.28.039},
	journal-iso = {KITAIBELIA},
	journal = {KITAIBELIA},
	volume = {28},
	unique-id = {34623316},
	issn = {1219-9672},
	abstract = {In this publication, the author provides occurrences of geobotanical importance from the North Hungarian Mountains collected in the spring of 2023. First occurrence for the following species was recorded: Helleborus dumetorum from the Cserhát Hills, Lunaria annua from the Mátra Mts. and Dryopteris affinis from the Bükk Mts. Ranunculus aquatilis was found again in the Bükk Mts., where it had been collected more than 100 years ago, and Rubus saxatilis was found for the fourth time in the Zemplén Mts. © 2023 Faculty of Science and Technology, University of Debrecen. All Rights Reserved.},
	keywords = {species distribution; Vascular plants; North Hungarian Mountains; occurence data},
	year = {2023},
	eissn = {2064-4507},
	pages = {209-210}
}

@article{MTMT:34219655,
	title = {Topographic depressions can provide climate and resource microrefugia for biodiversity},
	url = {https://m2.mtmt.hu/api/publication/34219655},
	author = {Frei, Kata and Vojtkó, András and Farkas, Tünde and Erdős, László and Barta, Károly and E-Vojtkó, Anna and Tölgyesi, Csaba and Bátori, Zoltán},
	doi = {10.1016/j.isci.2023.108202},
	journal-iso = {ISCIENCE},
	journal = {ISCIENCE},
	volume = {26},
	unique-id = {34219655},
	abstract = {Microrefugia are often located within topographically complex regions where stable environmental conditions prevail. Most of the studies concerning the distributions of climate change-sensitive species have emphasized the dominance of cold air pooling over other environmental factors, such as resource availability. There is a shortage of information on the relationships among topography-related microsite diversity, microclimate, resource availability, and species composition in microrefugia. To fill this knowledge gap, we studied the effects of microclimatic conditions and soil resources on plant species occurrence within and adjacent to 30 large topographic depressions (i.e., dolines) in two distant karst regions. Our results showed that both microclimate and soil resource availability may play a key role in maintaining climate change-sensitive species and biodiversity in dolines; therefore, they may simultaneously act as climate and resource microrefugia. Establishing climate-smart conservation priorities and strategies is required to maintain or increase the refugial capacity of such safe havens.},
	keywords = {nature conservation; plant ecology; Environmental science; Ecology},
	year = {2023},
	eissn = {2589-0042},
	orcid-numbers = {Erdős, László/0000-0002-6750-0961; E-Vojtkó, Anna/0000-0001-6370-680X; Tölgyesi, Csaba/0000-0002-0770-2107; Bátori, Zoltán/0000-0001-9915-5309}
}

@article{MTMT:34119390,
	title = {Heat tolerance changes of an intact semi-desert cryptobiotic crust during desiccation dominated by Didymodon species},
	url = {https://m2.mtmt.hu/api/publication/34119390},
	author = {Dulai, Sándor András and Tarnai, Réka and Radnai, Zsófia and Allem, Ammar and Vojtkó, András and Pócs, Tamás},
	doi = {10.21406/abpa.2023.11.1.199},
	journal-iso = {ACTA BIOL PLAN AGR},
	journal = {ACTA BIOLOGICA PLANTARUM AGRIENSIS},
	volume = {11},
	unique-id = {34119390},
	issn = {2061-6716},
	abstract = {The thermal stability of photosysthetic apparatus was examined under different (light and desiccation) treatments in the mosses (Didymodon luridus Hornsch, Didymodon nicholsonii Culm) dominated intact semi-desert cryptobiotic crusts. The relatively low temperature tolerance measured in default state (non energised thylakoids at full turgor) in the samples was inadequate to survive the thermal conditions of the original habitat. This was also manifested in the temperature sensitivity of optimal quantum yield (Fv/Fm) measured in dark-adapted state. The temperature dependence of the steady-state level of fluorescence, measured in light-adapted state, indicated a moderate decrease in heat sensitivity of PS II which was further enhanced by moderate water deficit. Moreover, a considerable water loss extremely increased the thermal stability of PS II in both dark and light-adapted states. Temperature dependence of the different quenching parameters suggests that in light-adapted state, the secondary effects of low lumen pH may protect against both temperature stress and water loss: i.e., it is likely that protection against the effects of light, temperature, and water deficit can be partly based on common bases. At very high temperatures the thermal damage of the oxygen-evolving complex is unlikely to be avoided, however, under continuous actinic light, the variable fluorescence (Fm’-Fs=AF) was partially recovered even above the critical temperature values of the Fs-T curves. This indicates the partial restoration of the electron donation of the PS II reaction centres by alternative electron donors. These changes in heat tolerance play a significant role to tolerate the effects of daily changing of the ecological factors in the habitat and it has a pronounced ecological significance and partly explains the survival of the examined crusts even under extreme semi-desert conditions.},
	year = {2023},
	eissn = {2063-6725},
	pages = {199-210}
}

@article{MTMT:33645158,
	title = {Environmental heterogeneity increases the conservation value of small natural features in karst landscapes},
	url = {https://m2.mtmt.hu/api/publication/33645158},
	author = {Bátori, Zoltán and Valkó, Orsolya and Vojtkó, András and Tölgyesi, Csaba and Farkas, Tünde and Frei, Kata and Hábenczyus, Alida Anna and Tóth, Ágnes and Li, Gábor and Rádai, Zoltán and Dulai, Sándor András and Barta, Károly and Erdős, László and Deák, Balázs},
	doi = {10.1016/j.scitotenv.2023.162120},
	journal-iso = {SCI TOTAL ENVIRON},
	journal = {SCIENCE OF THE TOTAL ENVIRONMENT},
	volume = {872},
	unique-id = {33645158},
	issn = {0048-9697},
	year = {2023},
	eissn = {1879-1026},
	orcid-numbers = {Bátori, Zoltán/0000-0001-9915-5309; Valkó, Orsolya/0000-0001-7919-6293; Tölgyesi, Csaba/0000-0002-0770-2107; Rádai, Zoltán/0000-0001-7011-5055; Erdős, László/0000-0002-6750-0961; Deák, Balázs/0000-0001-6938-1997}
}

@{MTMT:33041447,
	title = {The Vegetation of Karsts in Hungary},
	url = {https://m2.mtmt.hu/api/publication/33041447},
	author = {Bátori, Zoltán and Bauer, Norbert and Erdős, László and Vojtkó, András},
	booktitle = {Cave and karst systems of Hungary},
	doi = {10.1007/978-3-030-92960-2_19},
	unique-id = {33041447},
	year = {2022},
	pages = {535-552},
	orcid-numbers = {Bátori, Zoltán/0000-0001-9915-5309; Erdős, László/0000-0002-6750-0961}
}

@article{MTMT:32182572,
	title = {Florisztikai adatok Észak-Magyarországról II. Északi-Cserehát és Felső-Bódva-völgy},
	url = {https://m2.mtmt.hu/api/publication/32182572},
	author = {Vojtkó, András and Farkas, Tünde},
	doi = {10.17542/kit.26.31},
	journal-iso = {KITAIBELIA},
	journal = {KITAIBELIA},
	volume = {26},
	unique-id = {32182572},
	issn = {1219-9672},
	year = {2021},
	eissn = {2064-4507},
	pages = {31-48}
}

@{MTMT:32169073,
	title = {A fotoszintetizáló apparátus hőmérsékleti akklimációs mechanizmusai mikroléptékben változó klimatikus gradiensek mentén},
	url = {https://m2.mtmt.hu/api/publication/32169073},
	author = {Dulai, Sándor András and Tarnai, R and Szopkó, Dóra and E-Vojtkó, Anna and Bátori, Zoltán and Allem, A and Vojtkó, András},
	booktitle = {XIII. Magyar Növénybiológiai Kongresszus: Összefoglaló kötet},
	unique-id = {32169073},
	year = {2021},
	pages = {47},
	orcid-numbers = {E-Vojtkó, Anna/0000-0001-6370-680X; Bátori, Zoltán/0000-0001-9915-5309}
}

@article{MTMT:32080882,
	title = {Benchmarking plant diversity of Palaearctic grasslands and other open habitats},
	url = {https://m2.mtmt.hu/api/publication/32080882},
	author = {Biurrun, Idoia and Pielech, Remigiusz and Dembicz, Iwona and Gillet, François and Kozub, Łukasz and Marcenò, Corrado and Reitalu, Triin and Van Meerbeek, Koenraad and Guarino, Riccardo and Chytrý, Milan and J. Pakeman, Robin and Preislerová, Zdenka and Axmanová, Irena and Burrascano, Sabina and Bartha, Sándor and Boch, Steffen and Henrik Bruun, Hans and Conradi, Timo and De Frenne, Pieter and Essl, Franz and Filibeck, Goffredo and Hájek, Michal and Jiménez-Alfaro, Borja and Kuzemko, Anna and Molnár, Zsolt and Pärtel, Meelis and Pätsch, Ricarda and C. Prentice, Honor and Roleček, Jan and M.E. Sutcliffe, Laura and Terzi, Massimo and Winkler, Manuela and Wu, Jianshuang and Aćić, Svetlana and T.R. Acosta, Alicia and Afif, Elias and Akasaka, Munemitsu and M. Alatalo, Juha and Aleffi, Michele and Aleksanyan, Alla and Ali, Arshad and Apostolova, Iva and Ashouri, Parvaneh and Bátori, Zoltán and Baumann, Esther and Becker, Thomas and Belonovskaya, Elena and Luis Benito Alonso, José and Berastegi, Asun and Bergamini, Ariel and Prasad Bhatta, Kuber and Bonini, Ilaria and Büchler, Marc-Olivier and Budzhak, Vasyl and Bueno, Álvaro and Buldrini, Fabrizio and Antonio Campos, Juan and Cancellieri, Laura and Carboni, Marta and Ceulemans, Tobias and Chiarucci, Alessandro and Chocarro, Cristina and Conti, Luisa and Csergő, Anna Mária and Cykowska-Marzencka, Beata and Czarniecka-Wiera, Marta and Czarnocka-Cieciura, Marta and Czortek, Patryk and Danihelka, Jiří and de Bello, Francesco and Deák, Balázs and Deng, Lei and Diekmann, Martin and Dolezal, Jiri and Dolnik, Christian and Dřevojan, Pavel and Dupré, Cecilia and Ecker, Klaus and Ejtehadi, Hamid and Erschbamer, Brigitta and Etayo, Javier and Etzold, Jonathan and Farkas, Tünde and Farzam, Mohammad and Fayvush, George and Rosa Fernández Calzado, María and Finckh, Manfred and Fjellstad, Wendy and Fotiadis, Georgios and García-Magro, Daniel and García-Mijangos, Itziar and G. Gavilán, Rosario and Germany, Markus and Ghafari, Sahar and Pietro Giusso del Galdo, Gian and Grytnes, John-Arvid and Güler, Behlül and Gutiérrez-Girón, Alba and Helm, Aveliina and Herrera, Mercedes and M. Hüllbusch, Elisabeth and Ingerpuu, Nele and K. Jägerbrand, Annika and Jandt, Ute and Janišová, Monika and Jeanneret, Philippe and Jeltsch, Florian and Jensen, Kai and Jentsch, Anke and Kącki, Zygmunt and Kakinuma, Kaoru and Kapfer, Jutta and Kargar, Mansoureh and Kelemen, András and Kiehl, Kathrin and Kirschner, Philipp and Koyama, Asuka and Langer, Nancy and Lazzaro, Lorenzo and Lepš, Jan and Li, Ching-Feng and Yonghong Li, Frank and Liendo, Diego and Lindborg, Regina and Löbel, Swantje and Lomba, Angela and Lososová, Zdeňka and Lustyk, Pavel and L. Luzuriaga, Arantzazu and Ma, Wenhong and Maccherini, Simona and Magnes, Martin and Malicki, Marek and Manthey, Michael and Mardari, Constantin and May, Felix and Mayrhofer, Helmut and Seraina Meier, Eliane and Memariani, Farshid and Merunková, Kristina and Michelsen, Ottar and Molero Mesa, Joaquín and Moradi, Halime and Moysiyenko, Ivan and Mugnai, Michele and Naqinezhad, Alireza and Natcheva, Rayna and M. Ninot, Josep and Nobis, Marcin and Noroozi, Jalil and Nowak, Arkadiusz and Onipchenko, Vladimir and Palpurina, Salza and Pauli, Harald and Pedashenko, Hristo and Pedersen, Christian and K. Peet, Robert and Pérez-Haase, Aaron and Peters, Jan and Pipenbaher, Nataša and Pirini, Chrisoula and Pladevall-Izard, Eulàlia and Plesková, Zuzana and Potenza, Giovanna and Rahmanian, Soroor and Pilar Rodríguez-Rojo, Maria and Ronkin, Vladimir and Rosati, Leonardo and Ruprecht, Eszter and Rusina, Solvita and Sabovljević, Marko and Sanaei, Anvar and M. Sánchez, Ana and Santi, Francesco and Savchenko, Galina and Teresa Sebastià, Maria and Shyriaieva, Dariia and Silva, Vasco and Škornik, Sonja and Šmerdová, Eva and Sonkoly, Judit and Gaia Sperandii, Marta and Staniaszek-Kik, Monika and Stevens, Carly and Stifter, Simon and Suchrow, Sigrid and Swacha, Grzegorz and Świerszcz, Sebastian and Talebi, Amir and Teleki, Balázs and Tichý, Lubomír and Tölgyesi, Csaba and Torca, Marta and Török, Péter and Tsarevskaya, Nadezda and Tsiripidis, Ioannis and Turisova, Ingrid and Ushimaru, Atushi and Valkó, Orsolya and Van Mechelen, Carmen and Vanneste, Thomas and Vasheniak, Iuliia and Vassilev, Kiril and Viciani, Daniele and Villar, Luis and Virtanen, Risto and Vitasović-Kosić, Ivana and Vojtkó, András and Vynokurov, Denys and Waldén, Emelie and Wang, Yun and Weiser, Frank and Wen, Lu and Wesche, Karsten and White, Hannah and Widmer, Stefan and Wolfrum, Sebastian and Wróbel, Anna and Yuan, Zuoqiang and Zelený, David and Zhao, Liqing and Dengler, Jürgen},
	doi = {10.1111/jvs.13050},
	journal-iso = {J VEG SCI},
	journal = {JOURNAL OF VEGETATION SCIENCE},
	volume = {32},
	unique-id = {32080882},
	issn = {1100-9233},
	abstract = {Aims Understanding fine-grain diversity patterns across large spatial extents is fundamental for macroecological research and biodiversity conservation. Using the GrassPlot database, we provide benchmarks of fine-grain richness values of Palaearctic open habitats for vascular plants, bryophytes, lichens and complete vegetation (i.e., the sum of the former three groups). Location Palaearctic biogeographic realm. Methods We used 126,524 plots of eight standard grain sizes from the GrassPlot database: 0.0001, 0.001, 0.01, 0.1, 1, 10, 100 and 1,000 m(2) and calculated the mean richness and standard deviations, as well as maximum, minimum, median, and first and third quartiles for each combination of grain size, taxonomic group, biome, region, vegetation type and phytosociological class. Results Patterns of plant diversity in vegetation types and biomes differ across grain sizes and taxonomic groups. Overall, secondary (mostly semi-natural) grasslands and natural grasslands are the richest vegetation type. The open-access file "GrassPlot Diversity Benchmarks" and the web tool "GrassPlot Diversity Explorer" are now available online () and provide more insights into species richness patterns in the Palaearctic open habitats. Conclusions The GrassPlot Diversity Benchmarks provide high-quality data on species richness in open habitat types across the Palaearctic. These benchmark data can be used in vegetation ecology, macroecology, biodiversity conservation and data quality checking. While the amount of data in the underlying GrassPlot database and their spatial coverage are smaller than in other extensive vegetation-plot databases, species recordings in GrassPlot are on average more complete, making it a valuable complementary data source in macroecology.},
	year = {2021},
	eissn = {1654-1103},
	orcid-numbers = {Bartha, Sándor/0000-0001-6331-7521; Bátori, Zoltán/0000-0001-9915-5309; Csergő, Anna Mária/0000-0003-3325-2995; Deák, Balázs/0000-0001-6938-1997; Tölgyesi, Csaba/0000-0002-0770-2107; Valkó, Orsolya/0000-0001-7919-6293}
}

@misc{MTMT:33701987,
	title = {Botanikai Közlemények},
	url = {https://m2.mtmt.hu/api/publication/33701987},
	editor = {Kalapos, Tibor and Vojtkó, András},
	unique-id = {33701987},
	year = {2020},
	orcid-numbers = {Kalapos, Tibor/0000-0002-1393-5580}
}

@misc{MTMT:33701984,
	title = {Botanikai Közlemények},
	url = {https://m2.mtmt.hu/api/publication/33701984},
	editor = {Kalapos, Tibor and Vojtkó, András},
	unique-id = {33701984},
	year = {2020},
	orcid-numbers = {Kalapos, Tibor/0000-0002-1393-5580}
}