Abstract
The soil seedbank of long living seeds of herbs, graminoids and shrubs can survive several decades in the soil and germinate after disturbances like windthrow or clearcutting. The main goal of this study was to evaluate the risk of weeds, which may limit the success of conversions of secondary pure spruce stands (Picea abies) to mixed species stands. In a first step, germination experiments were performed in the greenhouse on soil samples collected under adjacent pure spruce and mixed species stands (mainly mixtures of spruce and beech –Fagus sylvatica) on two different soil substrates (Flysch: nutrient rich, basic soil; Molasse: nutrient poor, acidic soil). Seedling density and species richness were higher on the nutrient rich soil on Flysch. Comparisons between seedlings that emerged from soil samples collected at the end of the vegetation period and in spring justify the statement of the hypothesis that mixed spruce-beech stands advance the transient seed bank while pure spruce stands stimulate the persistent seed bank. In a second step, the seed banks of different soil horizons down to 35 cm soil depth were studied in a multivariate statistical design for the most dominant species J. effusus, C. pallescens and R. idaeus, which are known to form long-term persistent seeds. Effects of bedrock material (Flysch, Molasse), species composition (pure spruce, mixed species) and treatment (control, nitrate) were tested. The total sum of these three species was significantly higher on Flysch than on Molasse. However, species composition indicated no significant differences, although there was a trend of higher amounts of germinating seeds under pure spruce. Nitrate treatments did not promote germination of viable buried seeds, indicating that the number of emerged seedlings is a realistic indicator of the seed bank density for the studied stands. It is concluded that overstorey tree species composition is not an important controlling factor for seed germination of the studied species after disturbances. The majority of emergents are the graminoids J. effusus and C. pallescens which were not present at all in the aboveground vegetation. Viable seeds were found down to 35 cm soil depth, although most seeds were concentrated in the upper 10 cm soil. Hence, care should be taken if management strategies create conditions that are generally favorable to germination. The success of forest regeneration or a conversion of pure spruce to mixed species stands could be endangered by any disturbance, which causes an immediate increase of light levels.
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References
Archibold O W 1989 Seed banks and vegetation processes in coniferous forests. In Ecology of Soil Seed Banks. Eds. M A Leck, V T Parker and R L Simpson. pp. 107–122. Academic Press, Inc., San Diego.
Ashton P M S, Harris P G and Thadani R 1998 Soil seed bank dynamics in relation to topographic position of a mixed-deciduous forest in southern New England, USA. For. Ecol. Manage. 111, 15–22.
Auchmoody L R 1979 Nitrogen fertilization stimulates germination of dormant pin cherry seed. Can. J. For. Res. 9, 514–516.
Augusto L, Dupouey J-L, Picard J-F and Ranger J 2001 Potential contribution of the seed bank in coniferous plantations to the restoration of native deciduous forest vegetation. Acta Oecologica 22, 87–98.
Backhaus K, Erichson B, Plinke W and Weiber R 1994 Multivariate Analysemethoden, eine anwendungsorientierte Einführung. Springer-Verlag, Berlin Heidelberg, 594 pp.
Berger T W 2001 Impact of species composition on forest soil properties of secondary spruce and mixed spruce-beech stands. Cbl. Ges. Forstw. 118, 193–216.
Berger T W and Hager H 2000 Physical top soil properties in pure stands of Norway spruce (Picea abies) and mixed species stands in Austria. For. Ecol. Manage. 136, 159–172.
Berger T W, Neubauer C and Glatzel G 2002 Factors controlling soil carbon and nitrogen stores in pure stands of Norway spruce (Picea abies) and mixed species stands in Austria. For. Ecol. Manage. 159, 3–14.
Berger T W, Köllensperger G and Wimmer R 2004 Plant-soil feedback in spruce (Picea abies) and mixed spruce-beech (Fagus sylvatica) stands as indicated by dendrochemistry. Plant Soil, 264, 69–83.
Bigwood D W and Inouye D W 1987 Spatial pattern analysis of seed banks: An improved method and optimized sampling. Ecology 69, 497–507.
Bormann F H and Likens G E 1994 Pattern and Process in a Forested Ecosystem. Springer Verlag, New York, 253 pp.
Braun-Blanquet J 1964 Pflanzensoziologie-Grundzüge der Vegetationskunde. Springer, Vienna, New York. 865 pp.
Brown A H F, Oosterhuis L 1981 The role of buried seed in coppicewoods. Biol. Conserv. 21, 19–38.
Buckley G P, Howell R and Anderson M A 1997 Vegetation succession following ridge edge management in lowland plantations and woods. 2. The seed bank resource. Biol. Conserv. 82, 305–316.
Cavers P B and Benoit D L 1989 Seed banks in arable land. In Ecology of Soil Seed Banks. Eds. M A Leck, V T Parker and R L Simpson. pp. 309–328. Academic Press, Inc., San Diego.
DeGraaf R M, Hestbeck J B and Yamasaki M 1998 Associations between breeding bird abundance and stand structure in the White Mountains, New Hampshire and Maine, USA. For. Ecol. Manage. 103, 217–233.
Edwards C A and Bohlen P J 1996 Biology and Ecology of Earthworms. Chapman and Hall, New York, 426 pp.
Encke F, Buchheim G and Seybold S 1994 ZANDER Handbuch der Pflanzennamen. Ulmer, Stuttgart, 810 pp.
FBVA 1998 Österreichische Waldinventur (CD-ROM). Forstliche Bundesversuchsanstalt, Vienna.
Fischer A 1987 Untersuchungen zur Populationsdynamik am Beginn von Sekundärsukzessionen-Die Bedeutung von Samenbank und Samenniederschlag für die Wiederbesiedlung vegetationsfreier Flächen in Wald-und Grünlandgesellschaften. Diss. Bot. 110, Cramer, Berlin, Stuttgart, 234 pp.
Grabner R E and Thompson D F 1978 Seeds in the Organic Layers and Soil of Four Beech-Birch-Maple Stands. U.S.D.A., Broomall, PA. Cited in F Kostel-Hughes, T P Young and M J McDonnell 1998 The soil seed bank and its relationship to the aboveground vegetation in deciduous forests in New York City. Urban Ecosyst. 2, 43–59.
Hager H and Weinmeister W 2001 Stand Climate and Forest Hydrology and their Alterations by Measures of Forest Ecosystem Restoration. In Special Research Program on Forest Ecosystem Restoration, Final Report, Project Part F008-003. pp. 80–93. Univ. f. Bodenkultur, Vienna.
Hendricks S B and Taylorson R B 1974 Promotion of seed germination by nitrate, nitrite, hydrozylamine, and ammonium salts. Plant Physiol. 54, 304–309.
Hilhorst H W M and Karssen C M 2000 Effect of chemical environment on seed germination. In Seeds: The ecology of regeneration in plant communities. Ed. M Fenner. pp. 293–309. CABI publishing, Oxon, UK.
Honnay O, Bossuyt B, Verheyen K, Butaye J and Jacquemyn H 2002 Ecological perspectives for the restoration of plant communities in European temperate forests. Biodivers. Conserv. 11, 213–2421.
Johnson D W, Walker R F and Ball J T 1995 Lessons from lysimeters: Soil N release from disturbance compromises controlled environmental study. Ecol. Applic. 5, 395–400.
Kellmann M 1970 The viable seed content of some forest soils in coastal British Columbia. Can. J. Bot. 48, 1383–1385.
Kostel-Hughes F, Young T P and McDonnell M J 1998 The soil seed bank and its relationship to the aboveground vegetation in deciduous forests in New York City. Urb. Ecosyst. 2, 43–59.
Louda S M 1989 Predation in the dynamics of seed regeneration. In Ecology of Soil Seed Banks. Eds. M A Leck, V T Parker and R L Simpson. pp. 25–51. Academic Press, Inc., San Diego.
Ludemann T 1994 Zum Samenvorrat von Waldböden im Feldberggebiet. Carolinea 52, 45–60.
Mayer H 1974 Wälder des Ostalpenraumes. Gustav Fischer Verlag, Stuttgart. 344 pp.
Millbacher E 1987 Blattflächen-und Biomassenentwicklung sowie Nährstoffhaushalt einer Vergrasung mit Calamagrostis epigeios in einer Fichtenaufforstung auf Pseudogley. Diplomarbeit, Univ. f. Bodenkultur, Vienna, 89 pp.
Millbacher E 1992 Der Einfluss einer Vergrasung auf den Wasserhaushalt von Fichtenkulturen. Forstliche Schriftenreihe der Univ. f. Bodenkultur, Band 6, Österr. Ges. f. Waldökosystemforschung und experimentelle Baumforschung, Vienna, 142 pp.
Moore J M and Wein R W 1977 Viable seed populations by soil depth and potential site recolonization after disturbance. Can. J. Bot. 66, 169–172.
Mucina L, Grabherr G and Ellmauer T 1993 Die Pflanzengesellschaften Österreichs. Teil 3: Wälder und Gebüsche. Gustav-Fischer, Jena, Stuttgart, New York, 353 pp.
Neirynck J, Mirtcheva S, Sioen G and Lust N 2000 Impact of Tilia platyphyllos Scop., Fraxinus excelsior L., Acer pseudo-platanus L., Quercus robur L. and Fagus sylvatica L. on earthworm biomass and physico-chemical properties of a loamy topsoil. For. Ecol. Manage. 133, 275–286.
Neubauer C 2002 Einfluss der Baumartenmischung auf Bodenzustand und Nährstoffflüsse. Ph.D. Dissertation, Univ. f. Bodenkultur, Vienna. 110 pp.
Onaindia M and Amezaga I 2000 Seasonal variation in the seed banks of native woodland and coniferous plantations in Northern Spain. For. Ecol. Manage. 126, 163–172.
Pickett S T A and McDonnell M J 1989 Seed bank dynamics in temperate deciduous forest. In Ecology of Soil Seed Banks. Eds. M A Leck, V T Parker and R L Simpson. pp. 123–148. Academic Press, Inc., San Diego.
Romagosa M A and Robison D J 2003 Biological constraints on the growth of hardwood regeneration in upland Piedmont forests. For. Ecol. Manage. 175, 545–561.
Rothe A, Kreutzer K and Küchenhoff K 2002 Influence of tree species composition on soil and soil solution properties in two mixed spruce-beech stands with contrasting history in Southern Germany. Plant Soil 240, 47–56.
Rottmann M 1989 Wind-und Sturmschäden im Wald: Beiträge zur Beurteilung der Bruchgefährdung, zur Schadensvorbeugung und zur Behandlung sturmgeschädigter Nadelholzbestände. Sauerländer Verlag, Frankfurt (Main). 128 pp.
Scheffer F and Schachtschabel P 1998 Lehrbuch der Bodenkunde. Ferdinand Enke Verlag, Stuttgart. 494 pp.
Schmidt I and Kazda M 2001 Vertical distribution and radial growth of coarse roots in pure and mixed stands of Fagus sylvatica and Picea abies. Can. J. For. Res. 31, 539–548.
Schmidt-Vogt H 1986 Die Fichte-Band II/1-Wachstum, Züchtung, Boden, Umwelt, Holz. Paul Parey, Hamburg und Berlin. 563 pp.
Schreiner M, Bauer E-M and Kollmann J 2000 Reducing predation of confier seeds by clear-cutting Rubus fruticosus agg. in two montane forest stands. For. Ecol. Manage. 126, 281–290.
Schwerdtfeger F 1981 Die Waldkrankheiten. Paul Parey, Hamburg, Berlin. 486 p.
Simpson R L, Leck M A and Parker V T 1989 Seed banks: general concepts and methodological issues. In Ecology of Soil Seed Banks. Eds. M A Leck, V T Parker and R L Simpson. pp. 3–8. Academic Press, Inc., San Diego.
Sun B 2000 Qualitative and Quantitative Composition of Soil Seed Banks in Viennese Grasslands. Ph.D. Dissertation, Univ. f. Bodenkultur, Vienna, 130 pp.
Thompson K 2000 The functional ecology of soil seed banks. In Seeds: The Ecology of Regeneration in Plant Communities. Ed. M Fenner. pp. 215–235. CAB International, Oxon, UK.
Thompson K, Bakker J and Bekker R 1997 The Soil Seed Banks of North West Europe: Methodology, Density and Longevity. Cambridge University Press, Cambridge, 276 pp.
Van der Valk A G and Pederson R L 1989 Seed banks and the management and restoration of natural vegetation. In Ecology of Soil Seed Banks. Eds. M A Leck, V T Parker and R L Simpson. pp. 329–346. Academic Press, Inc., San Diego.
Vegis A 1964 Dormancy in higher plants. Annu. Rev. Plant Physiol. 15, 185–224.
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Berger, T.W., Sun, B. & Glatzel, G. Soil seed banks of pure spruce (Picea abies) and adjacent mixed species stands. Plant Soil 264, 53–67 (2004). https://doi.org/10.1023/B:PLSO.0000047753.36424.41
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DOI: https://doi.org/10.1023/B:PLSO.0000047753.36424.41