Abstract
Eutrophication due to increased nitrogen concentrations is known to alter species composition and threaten sensitive habitat types. The contribution of atmospheric nitrogen deposition to eutrophication is often difficult to determine. Various deposition models have been developed to estimate the amount of nitrogen deposited for both entire regions and different landscape surface types. The question arises whether the resulting deposition maps allow direct conclusions about the risk of eutrophication-related changes in the understory vegetation composition and diversity in nitrogen-sensitive forest ecosystems. We combined vegetation and soil data recorded across eutrophication gradients in ten oligo-mesotrophic forest types in southwest Germany with datasets from two different deposition models specifically fitted for forests in our study region. Altogether, 153 forest stands, with three sampling replicates each, were examined. Linear mixed-effect models and NMDS analyses revealed that other site factors, in particular the soil C/N ratio, soil pH and canopy cover, played a greater role in explaining vegetation gradients than nitrogen deposition. The latter only rarely had effects on species richness (positive), nitrophyte cover (positive or negative) and the cover of sensitive character species (negative). These effects varied depending on the deposition model used and the forest types examined. No effects of nitrogen deposition on average Ellenberg N values were found. The results reflect the complex situation in forests where nitrogen availability is not only influenced by deposition but also by nitrogen mineralization and retention which depend on soil type, pH and (micro)climate. This context dependency must be regarded when evaluating the effects of nitrogen deposition.
Highlights
Plant growth and vegetation composition are closely related to N availability in many terrestrial ecosystems
By examining gradients in the vegetation composition, represented by the Ellenberg CWM N value, the cover of N-sensitive character species and nitrophytes, species richness and evenness, we aimed to answer our research question whether vegetation composition was influenced by atmospheric N deposition
The eutrophication gradient was reflected in the Non-metric multidimensional scaling (NMDS) ordinations where plots were grouped (Figure S4, Table 2)
Summary
Plant growth and vegetation composition are closely related to N availability in many terrestrial ecosystems. Plant species in oligotrophic ecosystems are, mostly adapted to low N levels and cannot invest N as rapidly in growth as generalists. This results in a disadvantage in the competition for light which is a limiting factor in forest understories. A tool often used in vegetation ecology to summarize vegetation responses to environmental factors are Ellenberg indicator values (Ellenberg and others 2001) These values rate the preferences of individual species for nutrients (N), light (L), soil acidity (R) and moisture (F) among others on a nine-point ordinal scale based on an expert assessment. In case of the Nvalue, for example, 1 represents the most N-sensitive species and 9 indicates plant species with a preference for highly N-enriched habitats
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