Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary

Bauer, Norbert; Csiky, János; Mesterházy, Attila; Wolf, Mátyás; Schmidt, Dávid

doi:10.37427/botcro-2025-002

Acta Botanica Croatica, Vol. 84 No. 1, 2025.

Izvorni znanstveni članak

https://doi.org/10.37427/botcro-2025-002

Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary

Norbert Bauer orcid.org/0000-0001-6037-0773 ; Hungarian Natural History Museum, Department of Botany, Könyves K. krt. 40, H-1089 Budapest, Hungary *
János Csiky orcid.org/0000-0002-7920-5070 ; University of Pécs, Department of Ecology, Ifjúság u. 6, H-7624 Pécs, Hungary
Attila Mesterházy ; Hunyadi utca 55, H-9500 Celldömölk, Hungary
Mátyás Wolf ; Árvácska utca 38, H-7451 Kaposvár, Hungary
Dávid Schmidt ; Sopron University, Institute of Environmental Protection and Nature Conservation, Bajcsy- Zsilinszky u. 4, H-9400 Sopron, Hungary

* Dopisni autor.

Puni tekst: engleski pdf 396 Kb

preuzimanja: 71

citiraj

APA 6th Edition

Bauer, N., Csiky, J., Mesterházy, A., Wolf, M. i Schmidt, D. (2025). Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary. Acta Botanica Croatica, 84 (1), 0-0. https://doi.org/10.37427/botcro-2025-002

MLA 8th Edition

Bauer, Norbert, et al. "Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary." Acta Botanica Croatica, vol. 84, br. 1, 2025, str. 0-0. https://doi.org/10.37427/botcro-2025-002. Citirano 28.11.2024.

Chicago 17th Edition

Bauer, Norbert, János Csiky, Attila Mesterházy, Mátyás Wolf i Dávid Schmidt. "Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary." Acta Botanica Croatica 84, br. 1 (2025): 0-0. https://doi.org/10.37427/botcro-2025-002

Harvard

Bauer, N., et al. (2025). 'Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary', Acta Botanica Croatica, 84(1), str. 0-0. https://doi.org/10.37427/botcro-2025-002

Vancouver

Bauer N, Csiky J, Mesterházy A, Wolf M, Schmidt D. Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary. Acta Botanica Croatica [Internet]. 2025 [pristupljeno 28.11.2024.];84(1). https://doi.org/10.37427/botcro-2025-002

IEEE

N. Bauer, J. Csiky, A. Mesterházy, M. Wolf i D. Schmidt, "Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary", Acta Botanica Croatica, vol.84, br. 1, str. 0-0, 2025. [Online]. https://doi.org/10.37427/botcro-2025-002

Preuzmi JATS datoteku

Sažetak

This paper discusses the spread of the Mediterranean plant Catapodium rigidum (L.) C.E. Hubb. in Hungary, which is found in the transition zone between the sub-Mediterranean and continental climatic zones of Central Europe. This alien species has been found at 12 new localities in Hungary in recent years. Some of these stands are located along main roads, while others are found in urban weed vegetation. The species was most likely introduced by increasing road traffic and tourism. Our preliminary findings suggest that the spread of the species is not concentrated along main roads due to its salt sensitivity. Instead, it is more likely to be found in xerothermic weed vegetation in urban areas where salting and winter de-icing are not applied.

Ključne riječi

agochory; anthropochory; global warming; Poaceae; urban flora; weed species

Hrčak ID:

319705

URI

https://hrcak.srce.hr/319705

Datum izdavanja:

1.4.2025.

Posjeta: 316 *

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Publication date: 01 April 2025

Volume: 84

DOI: 10.37427/botcro-2025-002

Article Information (continued)

Categories:

Subject: Izvorni znanstveni članak

Categories:

Subject: Original scientific paper

Keywords:

Keyword: agochory

Keyword: anthropochory

Keyword: global warming

Keyword: Poaceae

Keyword: urban flora

Keyword: weed species

Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary

Norbert Bauer

Email: bauer.norbert@nhmus.hu

János Csiky

Email: moon@ttk.pte.hu

Attila Mesterházy

Email: amesterhazy@gmail.com

Mátyás Wolf

Email: matyas.wf@gmail.com

Dávid Schmidt

Email: schmidt.david@uni-sopron.hu

Abstract

Introduction

Catapodium rigidum (L.) C.E. Hubb. (Desmazeria rigida (L.) Tutin), fern grass or rigid-fescue (Poaceae family), is one of the most common synanthropic weed species in the Mediterranean region. It occurs in dry stony grasslands, particularly in ruderal places along roadsides, and municipal areas (Coste 1906, Fiori 1923, Jávorka 1925, Horvat et al. 1974). A recent study by Jasprica et al. (2017) found that this species is one of the most widespread weed species in railway stations in the North-Western Balkans. Catapodium rigidum s. str. has a Mediterranean-Atlantic distribution (Rikli 1943–1948, Meusel et al. 1965, Tutin et al. 1980). However, fern grass has been known to occur adventitiously in areas far from its original range, such as Asia, North and South America, Southern Africa, Australia (Clark 1974, Bhat et al. 2021, GBIF 2023). The species is considered indigenous to a small part of Switzerland (between Sézegnin and Soral), but introduced occurrences have also been long known in several large towns and cities, at railway stations, along railway lines, and in several cities in Germany (Hegi 1935, Buttler et al. 2018). Very few occurrences have been reported in Central Europe, east of Germany. Its casual occurrence was reported for the first time from Graz, Austria (Melzer 1954). The first report of this species in the Czech flora was almost 50 years ago by Dostál (1989), but there have been no confirmations. In 2009, Stöhr et al. reported a second observation of fern grass in Austria, in the surroundings of Salzburg (the community of Lamprechtshausen).

Old data (published or herbarium) reported occasional introductions of many Mediterranean species in Hungary. An accelerated spread of such plants has been observed recently (see Schmidt et al. 2016, Kun et al. 2023). However, in the BP herbarium specimens of C. rigidum originated from 19^th century and the plants were grown from seeds in the botanical garden. Neither Borbás (1891) nor Filarszky (1894) mentioned it in their related papers. The species was first observed in Hungary by Solymosi (2008) along the main road near Becsehely (Zala County, Western Hungary). A decade later, Schmidt (2019) reported a finding of the species on the Szombathely bypass (Vas County, Western Hungary). In recent years, the species has been found in many locations, particularly in the western part of the country (Transdanubia). While the manuscript of this study was being written, Rigó et al. (2023) reported the species from the capital (Budapest) in a single locality. The aim of our study is to provide a comprehensive summary of the current distribution of C. rigidum in Hungary, based on both published and unpublished data.

Material and methods

All authors conducted independent fieldwork, examining roadside vegetation and urban areas in various regions of the country. We recorded the geographic coordinates of the occurrences using GPS devices. A list of the sites is provided, along with the observation dates, geographical coordinates, grid numbers in the Central European Flora Mapping System (Niklfeld 1971), estimated number of individuals, and occurrence conditions. The specimens collected from the new sites in Hungary have been deposited in the BP and JPU Herbaria (Thiers 2024).

Results

The oldest specimens of Catapodium rigidum collected in Hungary were obtained from plants grown from seeds sown in a botanical garden (leg. Fekete, 30.10.1903, culta in h. bot. Budapest BP 313807, 408777). Recent spontaneous occurrences are summarised in Tab. 1.

Tab. 1. Introduced occurrences of Catapodium rigidum found in Hungary until the end of 2023. CEU = grid number of the Central European Flora Mapping System (Niklfeld 1971).

CEU	Settlement	Locality	Coordinate	Habitat	Number of individuals	Date	Observer / Collector	Herbarium specimen
9566.2 / 9566.4	Becsehely	main road 7	–	road bank	?	2007	P. Solymosi	–
8765.4	Szombathely	main road 86 (E65)	N 47.221971 E 16.658571	road bank	appr. 200	2017, 2019- onwards	D. Schmidt	–
8965.2	Egyházasrádóc	main road 86 (E65)	N 47.104442 E 16,637393	monodominant along road bank	1000×	22.06.2022.	N. Bauer	HNHM-TRA 00129733, HNHM-TRA 00129734
8965.4	Körmend	main road 86 (E65)	N 47,025314 E 16, 365181	asphalt road edge	< 20	26.06.2022.	A. Mesterházy	–
9975.1	Pécs	Tettye, Zöldfa street	N 46.081557 E 18.232826	along the pavement and the asphalt road	10–20	25.05.2023.	M. Wolf	–
8765.4	Szombathely	main road 86 (E65)	N 47.221971 E 16.658571	smaller stand on road bank	100×	28.05.2023.	D. Schmidt	HNHM-TRA 00702573
8480.1	Budapest	III. District, Gyűrű street	N 47.598549 E 19.060334	small trampled lawn patch and crevices of pavement	~400	31.05.2023.	A. Rigó	–
9975.1	Pécs	Tímár street (in the city centre)	N 46.074521 E 18.233905	in a one-way street with limited traffic, at the foot of the buildings	10-20	16.06.2023.	J. Csiky	JPU
9364.4	Rédics	main road 86 (E65)	N 46.618997 E 16.465032	massive population along road bank	1000×	17.06.2023.	D. Schmidt	HNHM-TRA 00702574
9172.4	Balatonszemes	pedestrian section at yacht harbor	N 46.812442 E 17.770822	under the strip of shrubs at the edge of the sidewalk, few	< 20	18.06.2023.	N. Bauer & A. Hüvös-Récsi	HNHM-TRA 00702591
9270.3	Balatonmáriafürdő	interior area, Keszeg street	N 46.703155 E 17.375309	sidewalk edge, car driveway	10–20	30.06.2023.	D. Schmidt	–
9270.4	Balatonfenyves	interior area, at the crossing of Kölcsey street and the railway	N 46.712215 E 17.478821	asphalt road edge	< 20	02.07.2023.	N. Bauer	HNHM-TRA 00702590

The distribution pattern of the species in Hungary (Fig. 1) indicates a spread in Western and Southern Transdanubia. The species was predominantly found in high-traffic locations, such as main roads and popular tourist areas.

Fig. 1. Current known occurrences of Catapodium rigidum in Hungary (December 2023). The red triangle shows the places where Catapodium rigidum was found: 1 – Szombathely, 2 – Egyházasrádóc, 3 – Körmend, 4 – Rédics, 5 – Becsehely, 6 – Balatonmáriafürdő, 7 – Balatonfenyves, 8 – Balatonszemes, 9 – Pécs, 10 – Budapest.

Discussion

Our presumption is that the presence of the fern grass in Hungary can be attributed to human activities, particularly international transport and tourism. The type of dispersal can be classified as anthropochory and agochory, as described by van der Maarel (2005) and Schulze et al. (2005). Where heavy traffic occurs on main roads (roadsides, roundabouts, pavements), the vector could be mainly motor vehicles carrying propagules on pieces of gravel. However, small populations found at sites where waste accumulates (e.g. Balatonszemes harbour; Pécs, at the base of buildings in a one-way street) suggest that lesser amounts of propagules may have been transported by human clothing and tools. The current new occurrences may be the result of independent introductions.

Although mentioned as a synanthropic species by Hegi (1935), its recent distribution in Europe (Fig. 2. GBIF) is rather dispersed and scattered outside of its original climatic requirements, specifically outside of the regions with oceanic and Mediterranean climates.

Fig. 2. Distribution of Catapodium rigidum in Europe based on GBIF data (2 October 2023). The dots show the reported occurrences of C. rigidum, the shades of yellow (from light to dark) reflect the amount of data detected.

Its natural distribution limit is almost identical to the January 0 C° isotherm (Michael 2021, p. 52.). Previous occurrences of this species in Central Europe were sporadic, and for a long time, its presence was not confirmed in Austria and in the Czech Republic (Melzer 1954, Dostál 1989, Stöhr et al. 2009, Pyšek et al. 2012). The establishment of the species in continental areas has been restricted, due to the limiting effect of winter frost (see Manley 1958, Grimm et al. 2008). However, according to the current climate change trends in the Pannonian region (Bartholy et al. 2014), the species is predicted to become established in Central Europe and other areas with a humid continental climate (Beck et al. 2018).

Currently, there are limited and conflicting data regarding the survival of plants in the stands. In the city of Szombathely, it was first discovered in 2017, disappeared for a year, and then reappeared in 2019, remaining present ever since. This observation suggests that if the habitat is suitable self-sustaining populations may develop. Mild winters do not appear to be a limiting factor if there are no periods of heavy frost. However, not all of the stands known for more than two years can be confirmed in the coming year. For instance, one of the most abundant populations found in 2022 (Egyházasrádóc village) was not observed on the roadside during the same period the following year. Given that the winter between the two field surveys of the site was the second mildest in the last 100 years (Szolnoki-Tótiván 2023), it is necessary to consider other limiting factors that may affect the survival of the introduced plants. Occasional mass emergence may occur due to extensive propagule introduction after winter. However, despite significant mass seed dispersal, germination in the following early spring may not be possible due to the high osmotic stress on roadside verges (Davison 1971). According to the Ellenberg-type indicator values database (Tichý et al. 2023), the species is presumably a glycophyte (salt-sensitive), so the use of salt to de-ice main roads is likely to reduce its long-term viability. The experimental confirmation by Talbi Zribi et al. (2018) also supports the strong salt sensitivity of C. rigidum when planted for forage in arid areas. Additionally, its long-term survival on main road verges may be reduced because C. rigidum is an annual C3 species. Its phenology is characterised by early spring germination, when the effect of winter salting is still strong and the leaching effect of precipitation is still weak. It is uncertain whether a population, even a relatively large one, can be considered self-sustaining in the future. However, due to the ever-increasing flow of traffic from the Mediterranean, the frequent introduction of its propagules is almost inevitable. It is possible that urban weed vegetation not subject to salting and de-icing will be more likely to have persistent, established populations, even if these are smaller. The aforementioned increases in the chance of establishment are already assumed for many species with similar climatic requirements and have shown recent area expansion (Bátori et al. 2012, Schmidt et al. 2016, Bauer 2018, Mesterházy et al. 2021, Bauer and Verloove 2023, Kun et al. 2023). It is expected that C. rigidum will continue to occur and spread in temperate continental areas of Central Europe, particularly along busy roads and in towns, with an increasing number of observations in the coming years.

Author contribution statement

N.B., D.S. and J.Cs. compiled a significant part of the manuscript, all the authors together wrote the conclusions.

Acknowledgements

We thank everyone who helped us, Annamária Hüvös-Récsi, Zoltán Kenyeres, Attila Rigó, Tamás Wirth in the fieldwork and/or with their remarks. The authors would like to express their gratitude to the two anonymous reviewers for their remarks.

References

Bartholy, J., Pongrácz, R., Pieczka, I. 2014;How the climate will change in this century? Hungarian Geographical Bulletin. 63(1):55–67. https://doi.org/10.15201/hungeobull.63.1.5

Bátori, Z., Erdős, L., Somlyay, L., 2012;Euphorbia prostrata (Euphorbiaceae), a new alien in the Carpathian Basin. Acta Botanica Hungarica. 5434:235–243. https://doi.org/10.1556/ABot.54.2012.3-4.2

Bauer, N., 2018;Distribution of Medicago orbicularis (Fabaceae) in Hungary. Studia Botanica Hungarica. 49(2):49–60. https://doi.org/10.17110/StudBot.2018.49.2.49

Bauer, N., Verloove, F., 2023;The accelerated spread of a neophyte introduced to Europe long ago. First occurrence of Sporobolus indicus (Poaceae) in Hungary. Acta Botanica Croatica. 82(1):20–26. https://doi.org/10.37427/botcro-2022-024

Beck, H. E., Zimmermann, N. E., McVicar, T. R., Vergopolan, N., Berg, A., Wood, E. F., 2018;"Present and future Köppen-Geiger climate classification maps at 1-km resolution". Scientific Data. 5:180214. https://doi.org/10.1038/sdata.2018.214

Bhat, M. A., Shakoor, S. A., Chowdhary, P., Badgal, P., Mir, B. A., Soodan, A. S., 2021. Taxonomic description and annotation of Catapodium rigidum (L.) C.E. Hubbard (Poaceae: Pooideae, Poeae, Parapholiinae) from Kashmir Himalayas, India. Vegetos. 34(3):p. 692–699. https://doi.org/10.1007/s42535-021-00223-z

Borbás, V., 1891;A növények vándorlása s Budapest flórájának vendégei (The migration of plants and alien plants of Budapest). Pótfüzetek a Természettudományi Közlönyhöz. 13(1):1–18

Buttler, K. P., Thieme, M. et al. 2018;Florenliste von Deutschland – Gefäßpflanzen. Version. 10:2018Frankfurt am Main. https://doi.org/10.11585 /buttler_et_al_florenliste_v10. Retrieved October 3, 2023 from https://publikationen.ub.uni-frankfurt.de/frontdoor/index/index/docId/52612.

Clark, S. C., 1974;Biological Flora of British Isles Catapodium rigidum (L.) C. E. Hubbard. Journal of Ecology. 62(3):937–958. https://doi.org/10.2307/2258963

Coste, H., 1906;Flore descriptive et illustrée de la France de la Corse et des contrées limitrophes. Tome. 3:(Paul Elinsieck, Paris.).

Davison, A. W., 1971;The effects of de-icing salt on roadside verges. I. Soil and plant analysis. Journal of Applied Ecology. 8(2):555–561. https://doi.org/10.2307/2402891

Dostál, J., 1989. Nová květena ČSSR (New flora of the CSSR). Academia,; Praha.:

Filarszky, N., 1894. Adatok Budapest flórájához (Data for the flora of Budapest). Pótfüzetek a Természettudományi Közlönyhöz 29–30 (Supplementum), 117–121.

Fiori, A., 1923. Nuova flora analitica d’Italia. Ricci, Firenze.:

GBIF, 2023. Global Biodiversity Information Facility. Species: Catapodium rigidum (L.) C.E. Hubb.Retrieved October 2, 2023 from. https://www.gbif.orgbifg/species/2705228

Grimm, N. B., Faeth, S. H., Golubiewski, N. E., Redman, C. L., Wu, J., Bai, X., Briggs, J. M., 2008;Global change and the ecology of cities. Science. 319(5864):756–760. https://doi.org/10.1126/science.1150195

Hegi, G., 1935. Illustrierte Flora von Mittel-Europa. Band I.: 2. Auflage. J. F. Lehmans Verlag, München.

Horvat, I., Glavač, V., Ellenberg, H., 1974. Vegetation Südosteuropas. Gustav Fischer Verlag,; Stuttgart.:

Jasprica, N., Milović, M., Dolina, K., Lasić, A., 2017;Analyses of the flora of railway stations in the Mediterranean and sub-Mediterranean areas of Croatia and Bosnia and Herzegovina. Natura Croatica. 26(2):271–303. https://doi.org/10.20302/NC.2017.26.21

Jávorka, S., 1925. Magyar Flóra. Flora Hungarica. Studium,; Budapest.:

Kun, A., Exner, T., Bauer, N., 2023;A Torilis nodosa új behurcolásai és terjedése Magyarországon. (New occurrences and spread of the adventive species Torilis nodosa in Hungary). Kitaibelia. 28(1):26–31. https://doi.org/10.17542/kit.28.030

Manley, G., 1958;On the frequency of snowfall in metropolitan England. Quarterly Journal of the Royal Meteorological Society. 84(1):70–72. https://doi.org/10.1002/qj.49708435910

Melzer, H., 1954;Zur Adventivflora der Steiermark I. Mitteilungen des Naturwissenschaftlichen Vereines Steiermark. 84:103–120

Mesterházy, A., Wirth, T., Schmidt, D., Csiky, J. 2021;A Vulpia ciliata morfológiája és magyarországi terjedésének sikere a vasúthálózat mentén (Spreading along the railways: morphology and invasion success of Vulpia ciliata in Hungary). Kitaibelia. 26(2):145–156. https://doi.org/10.17542/kit.26.145

Meusel, H., Jäger, E. J., Weinert, E. 1965Vergleichende Chorologie der Zentraleuropäischen Flora. Band I.: Gustav Fischer Verlag,; Jena.:

Michael, T. , editor. 2021. Diercke International Atlas. Westermann,; Braunschweig (Brunswick).:

Niklfeld, H., 1971;Bericht über die Kartierung der Flora Mitteleuropas. Taxon. 20(4):545–571. http://dx.doi.org/10.2307/1218258

Pyšek, P., Danihelka, J., Sádlo, J., Chrtek, J., Chytrý, M., Jarošík, V., Kaplan, Z., Krahulec, F., Moravcová, L., Pergl, J., Štajerová, K., Tichý, L., 2012;Catalogue of alien plants of the Czech Republic. ((2nd edition):). Checklist update, taxonomic diversity and invasion patterns. Preslia. 84:155–255

Rigó, A., Malatinszky, Á., Barina, Z., 2023;Inventory of the urban flora of Budapest (Hungary) hightlighting new and noteworthy floristic records. Biodiversity Data Journal. 11(2):110450. https://doi.org/10.3897/BDJ.11e110450

Rikli, M., 1943, 1946, 1948. Das Pflanzenkleid der Mittelmeerländer. p. 1–3. Band.: Verlag Hans Huber,; Bern.:

Schmidt, D., 2019;Vonalas létesítmények mentén terjedő növények Vas megyében (Plants spreading along the linear facilities in Vas County). Vasi Szemle. 73(2):160–174

Schmidt, D., Dítě, Z., Horváth, A., Szűcs, P., 2016;Coastal newcomer on motorways: the invasion of Plantago coronopus in Hungary. Studia Botanica Hungarica. 47(2):319–334. https://doi.org/10.17110/StudBot.2016.47.2.319

Schulze, E-D., Beck, E., ‎Müller-Hohenstein, K., 2005. Plant Ecology. Springer,; Berlin, Heidelberg.:

Solymosi, P., 2008;Két új termofil pázsitfűfaj jelent meg Magyarországon (Two new thermophilic grass species appeared in Hungary). Növényvédelem. 44(3):141–142

Stöhr, O., Pilsl, P., Essl, F., Wittmann, H., Hohla, M., 2009;Beiträge zur Flora von Österreich, III. Linzer biologische Beiträge. 41(2):1677–1755. https://doi.org/10.5281/zenodo.5279728

Szolnoki-Tótiván, B., 2023;2022/2023 telének időjárása (Weather in winter 2022/2023). Időjárás. 68(2):96–101

Talbi Zribi, O., Slama, I., Trabelsi, N., Hamdi, A., Abdelly, C., 2018;Combined effects of salinity and phosphorus availability on growth, gas exchange, and nutrient status of Catapodium rigidum. Arid Land Research and Management. 32(3):277–290. https://doi.org/10.1080/15324982.2018.1427640

Tichý, L., Axmanová, I., Dengler, J., Guarino, R., Jansen, F., Midolo, G., Nobis, M. P., van Meerbeek, K., Aćić, S., Attorre, F., Bergmeier, E., Biurrun, I., Bonari, G., Bruelheide, H., Campos, J. A., Čarni, A., Chiarucci, A., Ćuk, M., Ćušterevska, M., Didukh, Y., Dítě, D., Dítě, Z., Dziuba, T., Fanelli, G., Fernández-Pascual, E., Garbolino, E., Gavilán, R. G., Gégout, J.-C., Graf, U., Güler, B., Hájek, M., Hennekens, S. M., Jandt, U., Jašková, A., Jiménez-Alfaro, B., Julve, P., Kambach, S., Karger, D. N., Karrer, G., Kavgacı, A., Knollová, I., Kuzemko, A., Küzmič, F., Landucci, F., 2023;Ellenberg-type indicator values for European vascular plant species. Journal of Vegetation Science. 34(1):13168. https://doi.org/10.1111/jvs.13168

Tutin, T. G., Heywood, V. H., Burges, N. A., Moore, D. M., Valentine, D. H., Walters, S. M., Webb, D.A. , editors. 1980. Flora Europaea. 5. Cambridge University Press,; Cambridge.:

Thiers, B. M., 2024;Index Herbariorum: A global directory of public herbaria and associated staff. New York Botanical Garden’s Virtual Herbarium. Retreived April 4, 2024 from. https://sweetgum.nybg.org/science/ih/

van der Maarel, E. , editor. 2005. Vegetation Ecology. Blackwell Publishing, Malden-Oxford-Carlton.;

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Acta Botanica Croatica, Vol. 84 No. 1, 2025.

Sažetak

Ključne riječi

Hrčak ID:

URI

Datum izdavanja:

Article Information (continued)

Rapid spread of the Mediterranean glycophyte Catapodium rigidum in Hungary

Abstract

Introduction

Material and methods

Results

Discussion

Author contribution statement

Acknowledgements

References