Non-native tree species growth characteristics inventoried three decades after planting in the Danube Lowland

1Ábri, T., Keserü, Z., Szabó, F., Rédei, K., 2021: Structure of black walnut (Juglans nigra L.) stands on sandy soils in Hungary. Journal of Forest Science, 67:298–305.Search in Google Scholar

2Adamčíková, K., Ondrušková, E., Kobza, M., 2019: Hypovirulence in chestnut blight fungus, Cryphonectria parasitica, in Slovakia. Biocontrol Science and Technology, 29:840–851.Search in Google Scholar

3Benčať, F., 1960: Rozšírenie gaštana jedlého (Castanea sativa Mill.) a jeho stanovištné podmienky na Slovensku. Bratislava, Slovenská akadémia vied, 151 p. (In Slovak).Search in Google Scholar

4Boiffin, J., Badeau, V., Breda, N., 2017: Species distribution models may misdirect assisted migration: insights from the introduction of Douglas-fir to Europe. Ecological Applications, 27:446–457.Search in Google Scholar

5Brunner, I., Herzog, C., Dawes, M. A., Arend, M., Sperisen, C., 2015: How tree roots respond to drought. Frontiers in Plant Science, 6:547.Search in Google Scholar

6Buras, A., Menzel, A., 2019: Projecting tree species composition changes of European forests for 2061–2090 under RCP 4.5 and RCP 8.5 scenarios. Frontiers in Plant Science, 9:1986.Search in Google Scholar

7Chlepko, V., 1996: Biologické aspekty zásad hospodárenia a nápravné opatrenia v lesných oblastiach Slovenska. Zvolen, LVÚ, 109 p. (In Slovak).Search in Google Scholar

8Conedera, M., Krebs, P., Gehring, E., Wunder, J., Hülsmannn, L., Abegg, M. et al., 2021: How future-proof is Sweet chestnut (Castanea sativa) in a global change context? Forest Ecology and Management, 494:119320.Search in Google Scholar

9Cseresnyés, I., Tamás, J., 2014: Evaluation of Austrian pine (Pinus nigra) plantations in Hungary with respect to nature conservation – A Review. Journal of Landscape Ecology, 12:267–284.Search in Google Scholar

10Fernow, B. E., 2019: A brief history of forestry: in Europe, the United States and Other Countries. Glasgow, Good Press, 567 p.Search in Google Scholar

11Frýdl, J., Dostál, J., Beran, F., Čáp, J., Fulín, M., Frampton, J. et al., 2018: Exotic Abies species in Czech provenance trials: assessment after decades. Acta Silvatica et Lignaria Hungarica, 14:9–34.Search in Google Scholar

12Fulín, M., Novotný, P., Podrázský, V., Beran, F., Dostál, J., Jehlička, J., 2017: Evaluation of the provenence plot Hrubá Skála (Northern Bohemia) with grand fir at the age of 36 years. Journal of Forest Science, 63:75–87.Search in Google Scholar

13Halaj, J., Petráš, R., 1998: Rastové tabuľky hlavných drevín. Bratislava, Slovak Academic Press, 325 p. (In Slovak).Search in Google Scholar

14Hečková, Z., Adamčíková, K., Košťál, J., 2010: The black pine health condition in the Zoborské vrchy Mts. Folia Oecologica, 37:162–167.Search in Google Scholar

15Hlásny, T., Turčáni, M., 2013: Persisting bark beetle outbreak indicates the unsustainability of secondary Norway spruce forests: Case study from Central Europe. Annals of Forest Science, 70:481–491. Hlásny, T., Zimová, S., Merganičová, K., Štěpánek, P., Search in Google Scholar

16Modlinger, R., Turčáni, M., 2021: Devastating outbreak of bark beetles in the Czech Republic: Drivers, impacts, and management implications. Forest Ecology and Management, 490:119075.Search in Google Scholar

17Holubčík, M., 1968: Cudzokrajné dreviny v lesnom hospodárstve. Bratislava, Slovenské vydavateľstvo pôdohospodárskej literatúry, 370 p. (In Slovak).Search in Google Scholar

18Isaac-Renton, M. G., Roberts, D. R., Hamann, A., Spiecker, H., 2014: Douglas-fir plantations in Europe: a retrospective test of assisted migration to address climate change. Global Change Biology, 20:2607–2617.Search in Google Scholar

19Koltay, A., 1999: Health of Hungarian pine stands (in Hungarian). Erdészeti Lapok, 134:15–16.Search in Google Scholar

20Kormuťák, A., Benčať, T., Slobodník, B., 2017: Slovakia. In: Hasenauer, H. et al. (eds.): Non-native tree species for European forests: experiences, risks and opportunities. Vienna, University of Natural resources and life sciences, p. 342–349.Search in Google Scholar

21Kovalčík, M., Sarvašová, Z., Schwarz, M., Moravčík, M., Oravec, M., Lásková, J. et al., 2012: Financial and socioeconomic impacts of nature conservation on forestry in Slovakia. Journal of Forest Science, 58:425–435.Search in Google Scholar

22Kupka, I., Baláš, M., Miltner, S., 2018: Quantitative and qualitative evaluation of Northern red oak (Quercus rubra L.) in arid areas of North-Western Bohemia. Journal of Forest Science, 64:53–58.Search in Google Scholar

23Lojka, B., Teutscherová, N., Chládová, A., Kala, L., Szabó, P., Martiník, A. et al., 2022: Agroforestry in the Czech Republic: What hampers the comeback of a once traditional land use system? Agronomy, 12:69. Search in Google Scholar

24Martinez-Meier, A., Sanchez, L., Pastorino, M., Gallo, L., Rozenberg, P., 2008: What is hot in tree rings? The wood density of surviving Douglas-firs to the 2003 drought and heat wave. Forest Ecology and Management, 256:837–843.Search in Google Scholar

25Nicolescu, V. N., Vor, T., Mason, W. L., Bastien, J. C., Brus, R., Henin, J. M. et al., 2018: Ecology and management of northern red oak (Quercus rubra L.) in Europe: a review. Forestry: International Journal of Forest Research, 93:481–494.Search in Google Scholar

26Nicolescu, V. N., Rédei, K., Vor, T., Bastien, J. C., Brus, R., Benčať, T. et al., 2020: A review of black walnut (Juglans nigra L.) ecology and management in Europe. Trees, 34:1087–1112.Search in Google Scholar

27Novotný, P., Modlinger, R., Pešková, V., Čáp, J., 2012: Vyhodnocení růstu a zdravotního stavu proveniencí borovice černé (Pinus nigra Arnold) ve Středních Čechách ve věku 41 let. Zprávy lesnického výzkumu, 57:266–273. (In Czech).Search in Google Scholar

28Pástor, M., Jankovič J., Belko M., Modranský, J., 2022: Evaluation of selected growth parameters of Paulownia cotevisa plantations in the Danubian Lowland. Journal of Forest Science, 68:156–162.Search in Google Scholar

29Paul, C., Brandl, S., Friedrich, S., Falk, W., Härtl, F., Knoke, T., 2019: Climate change and mixed forests: how do altered survival probabilities impact economically desirable species proportions of Norway spruce and European beech? Annals of Forest Science, 76:14.Search in Google Scholar

30Podrázský, V., Čermák, R., Zahradník, D., Kouba, J., 2013: Production of Douglas-fir in the Czech Republic based on national forest inventory data. Journal of Forest Science, 10:398–404.Search in Google Scholar

31Podrázský, V., Vacek, Z., Vacek, S., Vítamvás, J., Gallo, J., Prokůpková, A. et al., 2020: Production potential and structural variability of pine stand in the Czech Republic: Scots pine (Pinus sylvestris L.) vs. Introduced pines – case study and problem review. Journal of Forest Science, 66:197–207.Search in Google Scholar

32Pötzelsberger, E., Spiecker, H., Neophytou, C., Mohren, F., Gazda, A., Hasenauer, H., 2020: Growing non-native trees in European forests brings benefits and opportunities but also has its risks and limits. Current Forestry Reports, 6:339–353.Search in Google Scholar

33Rédei, K., Antal, B., 2017: Black walnut as a valuable stand-forming tree species in Hungary – a growing technology review. Acta Agraria Debreceniensis, 72:129–132.Search in Google Scholar

34Remeš, J., Zeidler, A., 2014: Production potential and wood quality of Douglas fir from selected sites in the Czech Republic. Wood Research, 59:509–520.Search in Google Scholar

35Remiš, J., Soják, D., 1986: Priemyselné plantáže ihličnatých a tvrdých listnatých drevín na Slovensku. Bratislava, Príroda. 245 p. (In Slovak).Search in Google Scholar

36Schnabel, F., Liu, X. J., Kunz, M., Barry, K. E., Bongers, F. J., Bruelheide, H. et al., 2021: Species richness stabilizes productivity via asynchrony and drought-tolerance diversity in a large-scale tree biodiversity experiment. Ecology, 7:1643.Search in Google Scholar

37Slávik, M., Capuliak, J., Jankovič, J., Pástor, M., 2018: Kysihýbel Forestry Arboretum – precious source of non-native tree species in Central Europe. In: Pötzelsberger, E., Spiecker, H., Hasenauer, H., Konnert, M., Mohren G. M. J., Gazda, A., (eds.): Non-native tree species for European forests – experiences, risks, and opportunities. Vienna, University of Natural resources and life sciences, 92 p.Search in Google Scholar

38Sobocká, J., Saksa, M., Pástor, M., Pekárová, E., 2022: Pedoclimatic conditions of black walnut (Juglans nigra L.) used for agroforestry systems in Slovakia. Pedosphere Research, 2:74–85.Search in Google Scholar

39Szabó, F., Ábri, T., Rédei, K., 2021: Yield and crown structure characteristics in a red oak (Quercus rubra L.) stand: Case study. Acta Agrararia Debreceniensis, 2:49–53.Search in Google Scholar

40Šálek, L., Hejcmanová, P., 2011: Comparison of the growth pattern of black walnut (Juglans nigra L.) in two riparian forests in the region of South Moravia, Czech Republic. Journal of Forest Science, 57:107–113.Search in Google Scholar

41Šálek, L., Zahradník, D., Tipmann, L., Marušák, R., 2012: Black walnut (Juglans nigra L.) standing volume in the riparian forests of the Czech Republic. Turkish Journal of Agriculture and Forestry, 36:629–635.Search in Google Scholar

42Tokár, F., Kukla, J., 2005: European chestnut (Castanea sativa Mill) aboveground dendromass and its impact on composition of phytocenoses in Jelenec castanetarium pa. Ekológia, 24:217–230.Search in Google Scholar

43Tokár, F., Kukla, J., 2006: Ecological conditions in the castanetarium Horné Lefantovce and growth of European chestnut (Castanea sativa Mill.). Ekológia, 25:188–207.Search in Google Scholar

44Tokár, F., Kukla, J., 2008: Development of phytocoenoses and of above ground production of red oak (Quercus rubra L.) and black walnut (Juglans nigra L.) stands on the PRP series Ivanka pri Nitre. Folia Oecologica, 35:74–87.Search in Google Scholar

45Tomczak, K., Mania, P., Tomczak, A., 2023: Quality of beech, birch and oak wood from stands growing on post-agricultural lands. Wood Research, 68:279–292.Search in Google Scholar

46Vacek, S., Vacek, Z., Ulbrichová, I., Bulušek, D., Prokůpková, A., Král, J. et al., 2019: Biodiversity dynamics of differently managed lowland forests left to spontaneous development in Central Europe. Austrian Journal of Forest Science, 136:249–281.Search in Google Scholar

47Vejpustková, M., Čihák, T., 2019: Climate Response of Douglas Fir Reveals Recently Increased Sensitivity to Drought Stress in Central Europe. Forests:10:97.Search in Google Scholar

48Wohlgemuth, T., 2015: Climate change and tree responses in Central European forests. Annals of Forest Science, 72:285–287.Search in Google Scholar

49Zeidler, A., Salem, M., Borůvka, V., 2015: Mechanical properties of grand fir wood grown in the Czech Republic in vertical and horizontal positions. BioRe-sources, 10:793–808.Search in Google Scholar

50Zeidler, A., Borůvka, V., Černý, J., Baláš, M., 2022: Douglas-fir outperforms most commercial European soft-woods. Industrial Crops and Products, 181:114828.Search in Google Scholar

51Anonymous, 2022: Report on the forest sector of the Slovak republic 2021 – Green report. Bratislava. Ministry of Agriculture and Rural Development of the Slovak Republic, 66 p.Search in Google Scholar