TY - JOUR
T1 - Driving factors behind the eutrophication signal in understorey plant communities of deciduous temperate forests
AU - Verheyen, Kris
AU - Baeten, Lander
AU - De Frenne, Pieter
AU - Bernhardt-Römermann, Markus
AU - Brunet, Jörg
AU - Cornelis, Johnny
AU - Decocq, Guillaume
AU - Dierschke, Hartmut
AU - Eriksson, Ove
AU - Hédl, Radim
AU - Heinken, Thilo
AU - Hermy, Martin
AU - Hommel, Patrick
AU - Kirby, Keith
AU - Naaf, Tobias
AU - Peterken, George
AU - Petřík, Petr
AU - Pfadenhauer, Jörg
AU - Van Calster, Hans
AU - Walther, Gian Reto
AU - Wulf, Monika
AU - Verstraeten, Gorik
PY - 2012/3
Y1 - 2012/3
N2 - Atmospheric nitrogen (N) deposition is expected to change forest understorey plant community composition and diversity, but results of experimental addition studies and observational studies are not yet conclusive. A shortcoming of observational studies, which are generally based on resurveys or sampling along large deposition gradients, is the occurrence of temporal or spatial confounding factors. We were able to assess the contribution of N deposition versus other ecological drivers on forest understorey plant communities by combining a temporal and spatial approach. Data from 1205 (semi-)permanent vegetation plots taken from 23 rigorously selected understorey resurvey studies along a large deposition gradient across deciduous temperate forest in Europe were compiled and related to various local and regional driving factors, including the rate of atmospheric N deposition, the change in large herbivore densities and the change in canopy cover and composition. Although no directional change in species richness occurred, there was considerable floristic turnover in the understorey plant community and a shift in species composition towards more shade-tolerant and nutrient-demanding species. However, atmospheric N deposition was not important in explaining the observed eutrophication signal. This signal seemed mainly related to a shift towards a denser canopy cover and a changed canopy species composition with a higher share of species with more easily decomposed litter. Synthesis. Our multi-site approach clearly demonstrates that one should be cautious when drawing conclusions about the impact of atmospheric N deposition based on the interpretation of plant community shifts in single sites or regions due to other, concurrent, ecological changes. Even though the effects of chronically increased N deposition on the forest plant communities are apparently obscured by the effects of canopy changes, the accumulated N might still have a significant impact. However, more research is needed to assess whether this N time bomb will indeed explode when canopies will open up again.
AB - Atmospheric nitrogen (N) deposition is expected to change forest understorey plant community composition and diversity, but results of experimental addition studies and observational studies are not yet conclusive. A shortcoming of observational studies, which are generally based on resurveys or sampling along large deposition gradients, is the occurrence of temporal or spatial confounding factors. We were able to assess the contribution of N deposition versus other ecological drivers on forest understorey plant communities by combining a temporal and spatial approach. Data from 1205 (semi-)permanent vegetation plots taken from 23 rigorously selected understorey resurvey studies along a large deposition gradient across deciduous temperate forest in Europe were compiled and related to various local and regional driving factors, including the rate of atmospheric N deposition, the change in large herbivore densities and the change in canopy cover and composition. Although no directional change in species richness occurred, there was considerable floristic turnover in the understorey plant community and a shift in species composition towards more shade-tolerant and nutrient-demanding species. However, atmospheric N deposition was not important in explaining the observed eutrophication signal. This signal seemed mainly related to a shift towards a denser canopy cover and a changed canopy species composition with a higher share of species with more easily decomposed litter. Synthesis. Our multi-site approach clearly demonstrates that one should be cautious when drawing conclusions about the impact of atmospheric N deposition based on the interpretation of plant community shifts in single sites or regions due to other, concurrent, ecological changes. Even though the effects of chronically increased N deposition on the forest plant communities are apparently obscured by the effects of canopy changes, the accumulated N might still have a significant impact. However, more research is needed to assess whether this N time bomb will indeed explode when canopies will open up again.
KW - (semi-)permanent plots
KW - Atmospheric deposition
KW - Determinants of plant community diversity and structure
KW - Ellenberg indicator values
KW - Forest herbs
KW - Forest management
KW - Large herbivores
KW - North-western Europe
KW - Resurveys
UR - http://www.scopus.com/inward/record.url?scp=84856865306&partnerID=8YFLogxK
U2 - 10.1111/j.1365-2745.2011.01928.x
DO - 10.1111/j.1365-2745.2011.01928.x
M3 - Article
AN - SCOPUS:84856865306
SN - 0022-0477
VL - 100
SP - 352
EP - 365
JO - Journal of Ecology
JF - Journal of Ecology
IS - 2
ER -