Trade-offs or complementarity between biomass production and biodiversity in European forests: a review

1Adler, P. B., Seabloom, E. W., Borer, E. T., Hillebrand, H., Hautier, Y., Hector, A. et al., 2011: Productivity is a poor predictor of plant species richness. Science, 333:1750–1753.Search in Google Scholar

2Aggestam, F., Konczal, A., Sotirov, M., Wallin, I., Paillet, Y., Spinelli, R. et al., 2020: Can nature conservation and wood production be reconciled in managed forests? A review of driving factors for integrated forest management in Europe. Journal of Environmental Management, 268:110670.Search in Google Scholar

3Ampoorter, E., Barbaro, L., Jactel, H., Baeten, L., Boberg, J., Carnol, M. et al., 2020: Tree diversity is key for promoting the diversity and abundance of forest-associated taxa in Europe. Oikos, 129:133–146.Search in Google Scholar

4Angelstam, P. K., 1998: Maintaining and restoring bio-diversity in European boreal forests by developing natural disturbance regimes. Journal of Vegetation Science, 9:593–602.Search in Google Scholar

5Aragón, G., Abuja, L., Belinchón, R., Martínez, I., 2015: Edge type determines the intensity of forest edge effect on epiphytic communities. European Journal of Forest Research, 134:443–451.Search in Google Scholar

6Assmann, E., 1970: The principles of forest yield study: Studies in the organic production, structure, increment, and yield of forest stands. Oxford, Pergamon Press, 520 p.Search in Google Scholar

7Bauhus, J., Puettmann, K., Messier, C., 2009: Silviculture for old-growth attributes. Forest Ecology and Management, 258:525–537.Search in Google Scholar

8Bengtsson, J., Nilsson, S. G., Franc, A., Menozzi, P., 2000: Biodiversity, disturbances, ecosystem function and management of European forests. Forest Ecology and Management, 132:39–50.Search in Google Scholar

9Bernhardt-Römermann, M., Kudernatsch, T., Pfadenhauer, J., Kirchner, M., Jakobi, G., Fischer, A., 2007: Long-term effects of nitrogen deposition on vegetation in a deciduous forest near Munich, Germany. Applied Vegetation Science, 10:399–406.Search in Google Scholar

10Blaser, S., Prati, D., Senn-Irlet, B., Fischer, M., 2013: Effects of forest management on the diversity of deadwood-inhabiting fungi in Central European forests. Forest Ecology and Management, 304:42–48.Search in Google Scholar

11Bobbink, R., Hicks, K., Galloway, J., Spranger, T., Alke-made, R., Ashmore, M. et al., 2010: Global assessment of nitrogen deposition effects on terrestrial plant diversity: a synthesis. Ecological Applications : A Publication of the Ecological Society of America, 20:30–59.Search in Google Scholar

12Bollmann, K., Kraus, D., Paillet, Y., Jonsson, B. G., Gustafsson, L., Mergner, U. et al., 2020: Unifying framework for the conservation of biodiversity in multi-functional European forests. In: Krumm, F., Schuck, A., Rigling, A. (eds.): How to balance forestry and biodiversity conservation A view across Europe. Birmensdorf, Swiss Federal Institute for Forest, Snow and Landscape Research (WSL), p. 27–45.Search in Google Scholar

13Bowditch, E., Santopuoli, G., Binder, F., del Río, M., La Porta, N., Kluvankova, T. et al., 2020: What is Climate-Smart Forestry? A definition from a multinational collaborative process focused on mountain regions of Europe. Ecosystem Services, 43:101113.Search in Google Scholar

14Brazee, N. J., Lindner, D. L., D’Amato, A. W., Fraver, S., Forrester, J. A., Mladenoff, D. J. 2014: Disturbance and diversity of wood-inhabiting fungi: Effects of canopy gaps and downed woody debris. Biodiversity and Conservation, 23:2155–2172.Search in Google Scholar

15Brockerhoff, E. G., Barbaro, L., Castagneyrol, B., Forrester, D. I., Gardiner, B., González-Olabarria, J. R. et al., 2017: Forest biodiversity, ecosystem functioning and the provision of ecosystem services. Biodiversity and Conservation, 26:3005–3035.Search in Google Scholar

16Buma, B., Schultz, C., 2020: Disturbances as opportunities: Learning from disturbance-response parallels in social and ecological systems to better adapt to climate change. Journal of Applied Ecology, 57:1113–1123.Search in Google Scholar

17Burrascano, S., de Andrade, R. B., Paillet, Y., Ódor, P., Antonini, G., Bouget, C. et al., 2018: Congruence across taxa and spatial scales: Are we asking too much of species data? Global Ecology and Biogeography, 27:980–990.Search in Google Scholar

18Callaway, R. M., Walker, L. R., 1997: Competition and Facilitation: A Synthetic Approach to Interactions in Plant Communities. Ecology, 78:1958.Search in Google Scholar

19Chamagne, J., Paine, C. E. T., Schoolmaster, D. R., Stejskal, R., Volařík, D., Šebesta, J. et al., 2016: Do the rich get richer? Varying effects of tree species identity and diversity on the richness of understory taxa. Ecology, 97:2364–2373.Search in Google Scholar

20Chaudhary, A., Burivalova, Z., Koh, L. P., Hellweg, S., 2016: Impact of Forest Management on Species Richness: Global Meta-Analysis and Economic Trade-Offs. Scientific Reports, 6:23954.Search in Google Scholar

21D’Amato, A. W., Bradford, J. B., Fraver, S., Palik, B. J., 2011: Forest management for mitigation and adaptation to climate change: Insights from long-term silviculture experiments. Forest Ecology and Management, 262:803–816.Search in Google Scholar

22De Frenne, P., Lenoir, J., Luoto, M., Scheffers, B. R., Zellweger, F., Aalto, J. et al., 2021: Forest microcli-mates and climate change: Importance, drivers and future research agenda. Global Change Biology, 27:2279–2297.Search in Google Scholar

23Delgado-Baquerizo, M., Reich, P. B., Trivedi, C., Eldridge, D. J., Abades, S., Alfaro, F. D. et al., 2020: Multiple elements of soil biodiversity drive ecosystem functions across biomes. Nature Ecology & Evolution, 4:210–220.Search in Google Scholar

24Diaci, J., Kerr, G., O’Hara, K., 2011: Twenty-first century forestry: integrating ecologically based, uneven-aged silviculture with increased demands on forests. Forestry: An International Journal of Forest Research, 84:463–465.Search in Google Scholar

25Díaz, S., Hector, A., Wardle, D. A., 2009: Biodiversity in forest carbon sequestration initiatives: not just a side benefit. Current Opinion in Environmental Sustainability, 1:55–60.Search in Google Scholar

26Dirnböck, T., Grandin, U., Bernhardt-Römermann, M., Beudert, B., Canullo, R., Forsius, M. et al., 2014: Forest floor vegetation response to nitrogen deposition in Europe. Global Change Biology, 20:429–440.Search in Google Scholar

27Dittrich, S., Jacob, M., Bade, C., Leuschner, C., Hauck, M., 2014: The significance of deadwood for total bryophyte, lichen, and vascular plant diversity in an old-growth spruce forest. Plant Ecology, 215:1123–1137. Doerfler, I., Müller, J., Gossner, M. M., Hofner, B., Weisser, W. W., 2017: Success of a deadwood enrichment strategy in production forests depends on stand type and management intensity. Forest Ecology and Management, 400:607–620.Search in Google Scholar

28Drössler, L., Agestam, E., Bielak, K., Dudzinska, M., Koricheva, J., Liziniewicz, M. et al., 2018: Over- and Underyielding in Time and Space in Experiments with Mixed Stands of Scots Pine and Norway Spruce. Forests, 9:495.Search in Google Scholar

29Duguid, M. C., Ashton, M. S., 2013: A meta-analysis of the effect of forest management for timber on under-story plant species diversity in temperate forests. Forest Ecology and Management, 303:81–90.Search in Google Scholar

30Elek, Z., Kovács, B., Aszalós, R., Boros, G., Samu, F., Tinya, F. et al., 2018: Taxon-specific responses to different forestry treatments in a temperate forest. Scientific Reports, 8:16990.Search in Google Scholar

31Fabrika, M., Pretzsch, H., 2011: Analýza a modelovanie lesných ekosystémov. Zvolen Technická Univerzita vo Zvolene, 599 p. (In Slovak).Search in Google Scholar

32Falster, D. S., Brännström, Å., Westoby, M., Dieckmann, U., 2017: Multitrait successional forest dynamics enable diverse competitive coexistence. Proceedings of the National Academy of Sciences of the United States of America, 114:E2719–E2728.Search in Google Scholar

33Fedrowitz, K., Koricheva, J., Baker, S. C., Linden-mayer, D. B., Palik, B., Rosenvald, R. et al., 2014: REVIEW: Can retention forestry help conserve biodiversity? A meta-analysis. Journal of Applied Ecology, 51:1669–1679.Search in Google Scholar

34Fischer, J., Lindenmayer, D. B., Manning, A. D., 2006: Biodiversity, ecosystem function, and resilience: ten guiding principles for commodity production landscapes. Frontiers in Ecology and Environment, 4:80–86.Search in Google Scholar

35Forbes, E. S., Cushman, J. H., Burkepile, D. E., Young, T. P., Klope, M., Young, H. S., 2019: Synthesizing the effects of large, wild herbivore exclusion on ecosystem function. Functional Ecology, 33:1597–1610.Search in Google Scholar

36Fridley, J. D., 2001: The influence of species diversity on ecosystem productivity: How, where, and why? Oikos, 93:514–526.Search in Google Scholar

37Fuller, R. J., 2000: Influence of treefall gaps on distributions of breeding birds within interior old-growth stands in Bialowieza forest, Poland. Condor, 102:267–274.Search in Google Scholar

38Garfitt, J. E., 1995: Natural management of woods: continuous cover forestry. Taunton, Research Studies Press, 152 p.Search in Google Scholar

39Gasperini, C., Carrari, E., Govaert, S., Meeussen, C., De Pauw, K., Plue, J. et al., 2021: Edge effects on the realised soil seed bank along microclimatic gradients in temperate European forests. Science of the Total Environment, 798:149373.Search in Google Scholar

40Gilliam, F. S., Roberts, M. R., 1995: Impacts of Forest Management on Plant Diversity. Ecological Applications, 5:911–912.Search in Google Scholar

41Gilliam, F. S., Welch, N. T., Phillips, A. H., Billmyer, J. H., Peterjohn, W. T., Fowler, Z. K. et al., 2016: Twenty-five-year response of the herbaceous layer of a temperate hardwood forest to elevated nitrogen deposition. Ecosphere, 7:e01250.Search in Google Scholar

42Groombridge, B., Jenkins, M. D., 2002: World Atlas of Biodiversity. Earth’s Living Resources in the 21^st Century. London, University of California Press, 340 p.Search in Google Scholar

43Gonzalez, A., Germain, R. M., Srivastava, D. S., Filotas, E., Dee, L. E., Gravel, D. et al., 2020: Scaling-up biodiversity-ecosystem functioning research. Ecology Letters, 23:757–776.Search in Google Scholar

44Guo, Q., 2003: Temporal species richness-biomass relationships along successional gradients. Journal of Vegetation Science, 14:121–128.Search in Google Scholar

45Gustafsson, L., Baker, S. C., Bauhus, J., Beese, W. J., Brodie, A., Kouki, J. et al., 2012: Retention Forestry to Maintain Multifunctional Forests: A World Perspective. BioScience, 62:633–645.Search in Google Scholar

46Gutzat, F., Dormann, C. F., 2018: Decaying trees improve nesting opportunities for cavity-nesting birds in temperate and boreal forests: A meta-analysis and implications for retention forestry. International Journal of Business Innovation and Research, 17:8616–8626.Search in Google Scholar

47Hassan, R. M., Scholes, R., Ash, N., 2005: Ecosystems and Human Well-being - Current State and Trends: Findings of the Condition and Trends Working Group of the Millennium Ecosystem Assessment. The Millennium Ecosystem Assessment Series (v. 1) xxi. Washington, DC, Island Press, 917 p.Search in Google Scholar

48Heinken, T., Diekmann, M., Liira, J., Orczewska, A., Schmidt, M., Brunet, J. et al., 2022: The European Forest Plant Species List (EuForPlant): Concept and applications. Journal of Vegetation Science, 33:e13132.Search in Google Scholar

49Hobbs, R. J., Huenneke, L. F., 1992: Disturbance, Diversity, and Invasion: Implications for Conservation. Conservation Biology, 6:324–337.Search in Google Scholar

50Hodgson, J. A., Moilanen, A., Wintle, B. A., Thomas, C. D., 2011: Habitat area quality and connectivity: striking the balance for efficient conservation. Journal of Applied Ecology, 48:148–152.Search in Google Scholar

51Hofmeister, J., Hošek, J., Brabec, M., Hédl, R., Modrý, M., 2013: Strong influence of long-distance edge effect on herb-layer vegetation in forest fragments in an agricultural landscape. Perspectives in Plant Ecology, Evolution and Systematics, 15:293–303.Search in Google Scholar

52Hofmeister, J., Hošek, J., Malíček, J., Palice, Z., Syrovátková, L., Steinová, J. et al., 2016: Large beech (Fagus sylvatica) trees as ‘lifeboats’ for lichen diversity in central European forests. Biodiversity and Conservation, 25:1073–1090.Search in Google Scholar

53Holdridge, L. R., 1947: Determination of world plant formations from simple climatic data. Science 105:367–8.Search in Google Scholar

54Hooper, D. U., Chapin, F. S., Ewel, J. J., Hector, A., Inchausti, P., Lavorel, S. et al., 2005: Effects of biodiversity on ecosystem functioning: A consensus of current knowledge. Ecological Monographs, 75:3–35.Search in Google Scholar

55Horvat, V., Heras, P., García-Mijangos, I., Biurrun, I., 2017: Intensive forest management affects bryophyte diversity in the western Pyrenean silver fir-beech forests. Biological Conservation, 215:81–91.Search in Google Scholar

56Jenkins, M., 2003: Prospects for Biodiversity. Science, 302:1175–1177.Search in Google Scholar

57Jose, S., Williams, R., Zamora, D., 2006: Belowground ecological interactions in mixed-species forest plantations. Forest Ecology and Management, 233:231–239.Search in Google Scholar

58Kaufmann, S., Hauck, M., Leuschner, C., 2018: Effects of natural forest dynamics on vascular plant, bryophyte, and lichen diversity in primeval Fagus sylvatica forests and comparison with production forests. Journal of Ecology, 106:2421–2434.Search in Google Scholar

59Kenderes, K., Král, K., Vrška, T., Standovár, T., 2009: Natural gap dynamics in a Central European mixed beech–spruce–fir old-growth forest. Écoscience, 16:39–47.Search in Google Scholar

60Kenderes, K., Standovár, T., 2003: The impact of forest management on forest floor vegetation evaluated by species traits. Community Ecology, 4:51–62.Search in Google Scholar

61Kleidon, A., Mooney, H. A., 2000: A global distribution of biodiversity inferred from climatic constraints: results from a process-based modelling study. Global Change Biology, 6:507–523.Search in Google Scholar

62Klein, J., Thor, G., Low, M., Sjögren, J., Lindberg, E., Eggers, S., 2020: What is good for birds is not always good for lichens: Interactions between forest structure and species richness in managed boreal forests. Forest Ecology and Management, 473:118327.Search in Google Scholar

63Knoke, T., Kindu, M., Schneider, T., Gobakken, T., 2021: Inventory of Forest Attributes to Support the Integration of Non-provisioning Ecosystem Services and Biodiversity into Forest Planning–from Collecting Data to Providing Information. Current Forestry Reports, 7:38–58.Search in Google Scholar

64Koerner, S. E., Smith, M. D., Burkepile, D. E., Hanan, N. P., Avolio, M. L., Collins, S. L. et al., 2018: Change in dominance determines herbivore effects on plant bio-diversity. Nature Ecology & Evolution, 2:1925–1932.Search in Google Scholar

65Korpel, Š., 1995: Die Urwälder der Westkarpaten. Stuttgart, Jena, New York: Gustav Fischer Verlag, 310 p. (In German).Search in Google Scholar

66Koutecký, T., Ujházy, K., Volařík, D., Ujházyová, M., Máliš, F., Gömöryová, E. et al., 2022: Disturbance history drives current compositional and diversity patterns of primary Picea abies [L.] Karst. forest vegetation. Forest Ecology and Management, 520:120387.Search in Google Scholar

67Konôpka, B., Šebeň, V., Pajtík, J., Shipley, L. A., 2021: Excluding Large Wild Herbivores Reduced Norway Spruce Dominance and Supported Tree Species Richness in a Young, Naturally Regenerated Stand. Forests, 12:737.Search in Google Scholar

68Kovac, M., Hladnik, D., Kutnar, L., 2018: Biodiversity in (the Natura 2000) forest habitats is not static: its conservation calls for an active management approach. Journal for Nature Conservation, 43:250–260.Search in Google Scholar

69Krumm, F., Schuck, A., Rigling, A., 2020: How to balance forestry and biodiversity conservation a view across Europe. Birmensdorf, European Forest Institute (EFI), Swiss Federal Institute for Forest, Snow and Landscape Research (WSL), 640 p.Search in Google Scholar

70Kucbel, S., Jaloviar, P., Saniga, M., Vencurik, J., Klimaš, V., 2010: Canopy gaps in an old-growth fir-beech forest remnant of Western Carpathians. European Journal of Forest Research, 129:249–259.Search in Google Scholar

71Laurance, W. F., Nascimento, H. E. M., Laurance, S. G., Andrade, A., Ewers, R. M., Harms, K. E. et al., 2007: Habitat fragmentation, variable edge effects, and the landscape-divergence hypothesis. PLoS ONE, 2:e1017.Search in Google Scholar

72Leibundgut, H., 1978: Über die Dynamik europäischer Urwälder. Allgemeine Forst und Jagdzeitung, 33:686–690. (In German).Search in Google Scholar

73Leibundgut, H., 1993: Europäische Urwälder. Wegweiser zur naturnahen Waldwirtschaft. Bern, Stuttgart und Wien, 260 p. (In German).Search in Google Scholar

74Lelli, C., Bruun, H. H., Chiarucci, A., Donati, D., Frascaroli, F., Fritz, Ö. et al., 2019: Biodiversity response to forest structure and management: Comparing species richness, conservation relevant species and functional diversity as metrics in forest conservation. Forest Ecology and Management, 432:707–717.Search in Google Scholar

75Levin, S. A., Paine, R. T., 1974: Disturbance, patch formation, and community structure. Proceedings of the National Academy of Sciences of the United States of America, 71:2744–2747.Search in Google Scholar

76Liang, J., Crowther, T. W., Picard, N., Wiser, S., Zhou, M., Alberti, G. et al., 2016: Positive biodiversity-productivity relationship predominant in global forests. Science, 354:aaf8957.Search in Google Scholar

77Loreau, M., Barbier, M., Filotas, E., Gravel, D., Isbell, F., Miller, S. J. et al., 2021: Biodiversity as insurance: from concept to measurement and application. Biological Reviews, 96:2333–2354.Search in Google Scholar

78Lövei, G. L., Magura, T., Tóthmérész, B., Ködöböcz, V., 2006: The influence of matrix and edges on species richness patterns of ground beetles (Coleoptera: Carabidae) in habitat islands. Global Ecology and Biogeography, 15:283–289.Search in Google Scholar

79Lukac, M., 2017: Soil biodiversity and environmental change in European forests. Central European Forestry Journal, 63:59–65.Search in Google Scholar

80Máliš, F., Bobek, P., Hédl, R., Chudomelová, M., Petřík, P., Ujházy, K. et al., 2021a: Historical charcoal burning and coppicing suppressed beech and increased forest vegetation heterogeneity. Journal of Vegetation Science, 32:e12923.Search in Google Scholar

81Máliš, F., Konôpka, B., Šebeň, V., Pajtík, J., Merganičová, K., 2021b: Short-Term Dynamics of Vegetation Diversity and Aboveground Biomass of Picea abies [L.] H. Karst. Forests after Heavy Windstorm Disturbance. Forests, 12:97.Search in Google Scholar

82Meinen, C., Hertel, D., Leuschner, C., 2009: Biomass and morphology of fine roots in temperate broad-leaved forests differing in tree species diversity: Is there evidence of below-ground overyielding? Oecologia, 161:99–111.Search in Google Scholar

83Mensah, S., Veldtman, R., Assogbadjo, A. E., Glèlè Kakaï, R., Seifert, T., 2016: Tree species diversity promotes aboveground carbon storage through functional diversity and functional dominance. Ecology and Evolution, 6:7546–7557.Search in Google Scholar

84Mercier, P., Aas, G., Dengler, J., 2019: Effects of skid trails on understory vegetation in forests: A case study from Northern Bavaria (Germany). Forest Ecology and Management, 453:117579.Search in Google Scholar

85Miklín, J., Čížek, L., 2014: Erasing a European biodiversity hot-spot: Open woodlands, veteran trees and mature forests succumb to forestry intensification, succession, and logging in a UNESCO Biosphere Reserve. Journal for Nature Conservation, 22:35–41.Search in Google Scholar

86Mölder, A., Bernhardt-Römermann, M., Schmidt, W., 2008: Herb-layer diversity in deciduous forests: Raised by tree richness or beaten by beech? Forest Ecology and Management, 256:272–281.Search in Google Scholar

87Mölder, A., Streit, M., Schmidt, W., 2014: When beech strikes back: How strict nature conservation reduces herb-layer diversity and productivity in Central European deciduous forests. Forest Ecology and Management, 319:51–61.Search in Google Scholar

88Moning, C., Müller, J., 2009: Critical forest age thresholds for the diversity of lichens, molluscs and birds in beech (Fagus sylvatica L.) dominated forests. Ecological Indicators, 9:922–932.Search in Google Scholar

89Mori, A. S., Furukawa, T., Sasaki, T., 2013: Response diversity determines the resilience of ecosystems to environmental change. Biological Reviews, 88:349–364.Search in Google Scholar

90Mortelliti, A., Fagiani, S., Battisti, C., Capizzi, D., Boitani, L., 2010: Independent effects of habitat loss, habitat fragmentation and structural connectivity on forest-dependent birds. Diversity and Distributions, 16:941–951.Search in Google Scholar

91Mutke, J., Sommer, J. H., Kreft, H., Kier, G., Barthlott, W. et al., 2011: Vascular Plant Diversity in a Changing World: Global Centres and Biome-Specific Patterns. In: Zachos, F., Habel, J. (eds): Biodiversity Hotspots. Berlin, Heidelberg, Springer, p. 83–96.Search in Google Scholar

92Nolet, P., Kneeshaw, D., Messier, C., Béland, M., 2018: Comparing the effects of even- and uneven-aged silviculture on ecological diversity and processes: A review. Ecology and Evolution, 8:1217–1226.Search in Google Scholar

93Oliver, T. H., Heard, M. S., Isaac, N. J. B., Roy, D. B., Procter, D., Eigenbrod, F. et al., 2015: Biodiversity and Resilience of Ecosystem Functions. Trends in Ecology & Evolution, 30:673–684.Search in Google Scholar

94Overpeck, J. T., Rind, D., Goldberg, R., 1990: Climate-induced changes in forest disturbance and vegetation. Nature, 343:51–53.Search in Google Scholar

95Picard, M., Chevalier, R., Barrier, R., Boscardin, Y., Baltzinger, C., 2016: Functional traits of seeds dispersed through endozoochory by native forest ungulates. Journal of Vegetation Science, 27:987–998.Search in Google Scholar

96Plesník, P., 2004: Všeobecná biogeografia. Bratislava, Univerzita Komenského, 425 p. (In Slovak). Pretzsch, H., 2022: Facilitation and competition reduction in tree species mixtures in Central Europe: Consequences for growth modeling and forest management. Ecological Modelling, 464:109812.Search in Google Scholar

97Pretzsch, H., del Río, M., Ammer, C., Avdagic, A., Barbeito, I., Bielak, K. et al., 2015: Growth and yield of mixed versus pure stands of Scots pine (Pinus sylvestris L.) and European beech (Fagus sylvatica L.) analysed along a productivity gradient through Europe. European Journal of Forest Research, 134:927–947.Search in Google Scholar

98Pretzsch, H., Schütze, G., 2009: Transgressive overyielding in mixed compared with pure stands of Norway spruce and European beech in Central Europe: Evidence on stand level and explanation on individual tree level. European Journal of Forest Research, 128:183–204.Search in Google Scholar

99Pretzsch, H., Steckel, M., Heym, M., Biber, P., Ammer, C., Ehbrecht, M. et al., 2020: Stand growth and structure of mixed-species and monospecific stands of Scots pine (Pinus sylvestris L.) and oak (Q. robur L., Quercus petraea [Matt.] Liebl.) analysed along a productivity gradient through Europe. European Journal of Forest Research, 139:349–367.Search in Google Scholar

100Prieto-Benítez, S., Méndez, M., 2011: Effects of land management on the abundance and richness of spiders (Araneae): A meta-analysis. Biological Conservation, 144:683–691.Search in Google Scholar

101Purahong, W., Kapturska, D., Pecyna, M. J., Jariyavidyanont, K., Kaunzner, J., Juncheed, K. et al., 2015: Effects of Forest Management Practices in Temperate Beech Forests on Bacterial and Fungal Communities Involved in Leaf Litter Degradation. Microbial Ecology, 69:905–913.Search in Google Scholar

102Ram, D., Axelsson, A. L., Green, M., Smith, H. G., Lind-ström, Å., 2017: What drives current population trends in forest birds – forest quantity, quality or climate? A large-scale analysis from northern Europe. Forest Ecology and Management, 385:177–188.Search in Google Scholar

103Ranius, T., Johansson, P., Berg, N., Niklasson, M., 2008: The influence of tree age and microhabitat quality on the occurrence of crustose lichens associated with old oaks. Journal of Vegetation Science, 19:653–662.Search in Google Scholar

104Regnery, B., Couvet, D., Kubarek, L., Julien, J. F., Kerbiriou, C., 2013: Tree microhabitats as indicators of bird and bat communities in Mediterranean forests. Ecological Indicators, 34:221–230.Search in Google Scholar

105Ritter, E., Dalsgaard, L., Einhorn, K. S., 2005: Light, temperature and soil moisture regimes following gap formation in a semi-natural beech-dominated forest in Denmark. Forest Ecology and Management, 206:15–33.Search in Google Scholar

106Romano, A., Costa, A., Posillico, M., Carabinieri, R., Castel, B., Sangro, D. et al., 2016: Forest management and amphibians: Focus on the genus Salamandrina. Italian Journal of Agronomy, 11:131–134.Search in Google Scholar

107Runkle, J. R., 1985: Disturbance Regimes in Temperate Forests. In: Pickett, S. T. A., White, P. S. (ed.): The Ecology of Natural Disturbance and Patch Dynamics, Academic Press, p. 17–33.Search in Google Scholar

108Sabatini, F. M., de Andrade, R. B., Paillet, Y., Ódor, P., Bouget, C., Campagnaro, T. et al., 2019: Trade-offs between carbon stocks and biodiversity in European temperate forests. Global Change Biology, 25:536–548.Search in Google Scholar

109Sandström, J., Bernes, C., Junninen, K., Lõhmus, A., Macdonald, E., Müller, J. et al., 2019: Impacts of dead wood manipulation on the biodiversity of temperate and boreal forests. A systematic review. Journal of Applied Ecology, 56:1770–1781.Search in Google Scholar

110Schall, P., Gossner, M. M., Heinrichs, S., Fischer, M., Boch, S., Prati, D. et al., 2018: The impact of even-aged and uneven-aged forest management on regional biodiversity of multiple taxa in European beech forests. Journal of Applied Ecology, 55:267–278.Search in Google Scholar

111Schall, P., Heinrichs, S., Ammer, C., Ayasse, M., Boch, S., Buscot, F. et al., 2020: Can multi-taxa diversity in European beech forest landscapes be increased by combining different management systems? Journal of Applied Ecology, 57:1363–1375.Search in Google Scholar

112Scheuermann, C. M., Nave, L. E., Fahey, R. T., Nadelhoffer, K. J., Gough, C. M., 2018: Effects of canopy structure and species diversity on primary production in upper Great Lakes forests. Oecologia, 188:405–415.Search in Google Scholar

113Schlegel, J., 2022: Butterflies benefit from forest edge improvements in Western European lowland forests, irrespective of adjacent meadows’ use intensity. Forest Ecology and Management, 521:120413.Search in Google Scholar

114Schütz, J.-P., 2011: Výběrné hospodářství a jeho různé formy: skripta k přednáškám Pěstění lesa II a Pěstění lesa IV. Kostelec nad Černými lesy, Lesnická Práce, 159 p. (In Czech).Search in Google Scholar

115Sousa, W. P., 2003: The Role of Disturbance in Natural Communities. Annual Review of Ecology and Systematics, 15:353–391.Search in Google Scholar

116Slezák, M., Hrivnák, R., 2019: How do environmental variables shape plant species diversity and composition in beech forests of Central Slovakia? Biologia, 74:1295–1301.Search in Google Scholar

117Staude, I. R., Waller, D. M., Bernhardt-Römermann, M., Bjorkman, A. D., Brunet, J., De Frenne, P. et al., 2020: Replacements of small- by large-ranged species scale up to diversity loss in Europe’s temperate forest biome. Nature Ecology & Evolution, 4:802–808.Search in Google Scholar

118Storch, F., Boch, S., Gossner, M. M., Feldhaar, H., Ammer, C., Schall, P. et al., 2023: Linking structure and species richness to support forest biodiversity monitoring at large scales. Annals of Forest Science, 80:1–17.Search in Google Scholar

119Taylor, A. R., Gao, B., Chen, H. Y. H., 2020: The effect of species diversity on tree growth varies during forest succession in the boreal forest of central Canada. Forest Ecology and Management, 455:117641.Search in Google Scholar

120Tilman, D., 1985: The resource-ratio hypothesis of plant succession. American Naturalist, 125:827–852.Search in Google Scholar

121Tilman, D., Lehman, C. L., Thomson, K. T., 1997: Plant diversity and ecosystem productivity: theoretical considerations. Proceedings of the national academy of sciences, 94:1857–1861.Search in Google Scholar

122Tinya, F., Kovács, B., Bidló, A., Dima, B., Király, I., Kutszegi, G. et al., 2021: Environmental drivers of forest biodiversity in temperate mixed forests – A multi-taxon approach. Science of The Total Environment, 795:148720.Search in Google Scholar

123Tomao, A., Antonio Bonet, J., Castaño, C., de-Miguel, S., 2020: How does forest management affect fungal diversity and community composition? Current knowledge and future perspectives for the conservation of forest fungi. Forest Ecology and Management, 457:117678.Search in Google Scholar

124Ujházy, K., Hederová, L., Máliš, F., Ujházyová, M., Bosela, M., Čiliak, M., 2017: Overstorey dynamics controls plant diversity in age-class temperate forests. Forest Ecology and Management, 391:96–105.Search in Google Scholar

125Vacek, Z., 2017: Structure and dynamics of spruce-beech-fir forests in Nature Reserves of the Orlické hory Mts. in relation to ungulate game. Central European Forestry Journal, 63:23–34.Search in Google Scholar

126Verheyen, K., Baeten, L., De Frenne, P., Bernhardt-Rö Mermann, M., Rg Brunet, J. et al., 2011: Driving factors behind the eutrophication signal in under-storey plant communities of deciduous temperate forests. British Ecological Society Journal of Ecology, 100:352–365.Search in Google Scholar

127Večeřa, M., Divíšek, J., Lenoir, J., Jiménez-Alfaro, B., Biurrun, I., Knollová, I. et al., 2019: Alpha diversity of vascular plants in European forests. Journal of Bio-geography, 46:1919–1935.Search in Google Scholar

128Vilà, M., Vayreda, J., Comas, L., Ibáñez, J. J., Mata, T., Obón, B., 2007: Species richness and wood production: a positive association in Mediterranean forests. Ecology Letters, 10:241–250.Search in Google Scholar

129Villar, N., Medici, E. P., 2021: Large wild herbivores slow down the rapid decline of plant diversity in a tropical forest biodiversity hotspot. Journal of Applied Ecology, 58:2361–2370.Search in Google Scholar

130Wales, S. B., Kreider, M. R., Atkins, J., Hulshof, C. M., Fahey, R. T., Nave, L. E. et al., 2020: Stand age, disturbance history and the temporal stability of forest production. Forest Ecology and Management, 460:117865.Search in Google Scholar

131Watt, A. S., 1947: Pattern and Process in the Plant Community. Journal of Ecology, 35:1–22.Search in Google Scholar

132Wei, L., Archaux, F., Hulin, F., Bilger, I., Gosselin, F., 2020: Stand attributes or soil micro-environment exert greater influence than management type on understory plant diversity in even-aged oak high forests. Forest Ecology and Management, 460:117897.Search in Google Scholar

133Yachi, S., Loreau, M., 1999: Biodiversity and ecosystem productivity in a fluctuating environment: The insurance hypothesis. Proceedings of the National Academy of Sciences, 96:1463–1468.Search in Google Scholar

134Zellweger, F., Coomes, D., Lenoir, J., Depauw, L., Maes, S. L., Wulf, M. et al., 2019: Seasonal drivers of under-storey temperature buffering in temperate deciduous forests across Europe. Global Ecology and Biogeography, 28:1774–1786.Search in Google Scholar

135Zhang, Y., Chen, H. Y. H., Reich, P. B., 2012: Forest productivity increases with evenness, species richness and trait variation: a global meta-analysis. Journal of Ecology, 100:742–749.Search in Google Scholar