Your search keyword '"Leon J.L. van den Berg"' showing total 12 results

1. Patterns of long-term vegetation change vary between different types of semi-natural grasslands in Western and Central Europe

Author

Miriam Fanigliulo, Volker Blüml, Annett Hahn, Christian Andres, Stefanie Luka, Jonathan Bennie, Heike Culmsee, James M. Bullock, Thomas Becker, Martin Diekmann, Karsten Wesche, Josef Müller, Justus Meißner, Philippine Vergeer, Christoph Leuschner, Gert Rosenthal, Thilo Heinken, Cord Peppler-Lisbach, Leon J.L. van den Berg, and Adrian C. Newton

Subjects

0106 biological sciences, homogenization, Plant Ecology and Nature Conservation, Plant Science, Generalist and specialist species, 010603 evolutionary biology, 01 natural sciences, complex mixtures, Grassland, Ecology and Environment, quasi-permanent plot, re-survey, fragmentation, ddc:570, natural sciences, species richness, Institut für Biochemie und Biologie, 2. Zero hunger, Nature reserve, geography, geography.geographical_feature_category, Ecology, wet grasslands, food and beverages, Edaphic, 15. Life on land, PE&RC, dry grasslands, meta-analysis, nitrogen deposition, Habitat, Plantenecologie en Natuurbeheer, Environmental science, Indicator value, Species richness, management, 010606 plant biology & botany, Global biodiversity

Abstract

Questions: Has plant species richness in semi‐natural grasslands changed over recent decades? Do the temporal trends of habitat specialists differ from those of habitat generalists? Has there been a homogenization of the grassland vegetation? Location: Different regions in Germany and the UK. Methods: We conducted a formal meta‐analysis of re‐survey vegetation studies of semi‐natural grasslands. In total, 23 data sets were compiled, spanning up to 75 years between the surveys, including 13 data sets from wet grasslands, six from dry grasslands and four from other grassland types. Edaphic conditions were assessed using mean Ellenberg indicator values for soil moisture, nitrogen and pH. Changes in species richness and environmental variables were evaluated using response ratios. Results: In most wet grasslands, total species richness declined over time, while habitat specialists almost completely vanished. The number of species losses increased with increasing time between the surveys and were associated with a strong decrease in soil moisture and higher soil nutrient contents. Wet grasslands in nature reserves showed no such changes or even opposite trends. In dry grasslands and other grassland types, total species richness did not consistently change, but the number or proportions of habitat specialists declined. There were also considerable changes in species composition, especially in wet grasslands that often have been converted into intensively managed, highly productive meadows or pastures. We did not find a general homogenization of the vegetation in any of the grassland types. Conclusions: The results document the widespread deterioration of semi‐natural grasslands, especially of those types that can easily be transformed to high production grasslands. The main causes for the loss of grassland specialists are changed management in combination with increased fertilization and nitrogen deposition. Dry grasslands are most resistant to change, but also show a long‐term trend towards an increase in more mesotrophic species.

Published

2019

2. Inertia in an ombrotrophic bog ecosystem in response to 9 years' realistic perturbation by wet deposition of nitrogen, separated by form

Author

A. Crossley, Leon J.L. van den Berg, Ian D. Leith, Sanna K. Kivimaki, David Fowler, David Leaver, Lucy J. Sheppard, Toshie Mizunuma, Simon M. Smart, Sarah Leeson, Chris Field, Mark A. Sutton, J. Neil Cape, and Netty van Dijk

Subjects

Nitrogen, Ombrotrophic, chemistry.chemical_element, Context (language use), Sphagnum capillifolium, Ecology and Environment, Soil, Ammonia, chemistry.chemical_compound, Nitrate, Botany, Environmental Chemistry, Ammonium, Bog, Ecosystem, General Environmental Science, Air Pollutants, Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, biology, Aquatic Ecology, Biodiversity, Hydrogen-Ion Concentration, biology.organism_classification, Scotland, chemistry, Wetlands, Environmental chemistry, Seasons

Abstract

Wet deposition of nitrogen (N) occurs in oxidized (nitrate) and reduced (ammonium) forms. Whether one form drives vegetation change more than the other is widely debated, as field evidence has been lacking. We are manipulating N form in wet deposition to an ombrotrophic bog, Whim (Scottish Borders), and here report nine years of results. Ammonium and nitrate were provided in rainwater spray as NH4 Cl or NaNO3 at 8, 24 or 56 kg N ha(-1) yr(-1) , plus a rainwater only control, via an automated system coupled to site meteorology. Detrimental N effects were observed in sensitive nonvascular plant species, with higher cumulative N loads leading to more damage at lower annual doses. Cover responses to N addition, both in relation to form and dose, were species specific and mostly dependent on N dose. Some species were generally indifferent to N form and dose, while others were dose sensitive. Calluna vulgaris showed a preference for higher N doses as ammonium N and Hypnum jutlandicum for nitrate N. However, after 9 years, the magnitude of change from wet deposited N on overall species cover is small, indicating only a slow decline in key species. Nitrogen treatment effects on soil N availability were likewise small and rarely correlated with species cover. Ammonium caused most N accumulation and damage to sensitive species at lower N loads, but toxic effects also occurred with nitrate. However, because different species respond differently to N form, setting of ecosystem level critical loads by N form is challenging. We recommend implementing the lowest value of the critical load range where communities include sensitive nonvascular plants and where ammonium dominates wet deposition chemistry. In the context of parallel assessment at the same site, N treatments for wet deposition showed overall much smaller effects than corresponding inputs of dry deposition as ammonia.

Published

2013

3. Direct and indirect effects of nitrogen deposition on species composition change in calcareous grasslands

Author

Simon M. Smart, Mike Ashmore, Dan Guest, Leon J.L. van den Berg, Tim C. G. Rich, and Philippine Vergeer

Subjects

0106 biological sciences, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Ecology, Calcareous grassland, Biodiversity, Species diversity, 15. Life on land, Biology, 010603 evolutionary biology, 01 natural sciences, Environmental Chemistry, Species evenness, Species richness, Quadrat, Deposition (chemistry), Calcareous, 0105 earth and related environmental sciences, General Environmental Science

Abstract

Atmospheric nitrogen (N) deposition has been identified as a major threat to biodiversity, but field surveys of its effects have rarely focussed on sites which are actively managed to maintain characteristic species. We analysed permanent quadrat data from 106 plots in nature reserves on calcareous grassland sites in the United Kingdom collected during a survey between 1990 and 1993 and compared the data with the results from resurvey of 48 of these plots between 2006 and 2009. N deposition showed no significant spatial association with species richness, species diversity, or the frequency of species adapted to low nutrient conditions in the 1990–1993 dataset. However, temporal analysis showed that N deposition was significantly associated with changes in Shannon diversity and evenness. In plots with high rates of N deposition, there was a decrease in species diversity and evenness, a decline in the frequency of characteristic calcareous grassland species, and a lower number of rare and scarce species. As all sites had active management to maintain a high diversity and characteristic species, our results imply that even focussed management on nature conservation objectives cannot prevent adverse effects of high rates of N deposition. Structural equation modelling was used to compare different causal mechanisms to explain the observed effects. For change in Shannon diversity, direct effects of N deposition were the dominant mechanism and there was an independent effect of change in grazing intensity. In contrast, for change in herb species number, indirect effects on soil acidity, linked to both N and S deposition, were more important than direct effects of N deposition.

Published

2010

4. Evidence for differential effects of reduced and oxidised nitrogen deposition on vegetation independent of nitrogen load

Author

Laurence Jones, Mike Ashmore, Roland Bobbink, Simon M. Smart, Leon J.L. van den Berg, Nancy B. Dise, and Lucy J. Sheppard

Subjects

010504 meteorology & atmospheric sciences, Nitrogen, Climate, Health, Toxicology and Mutagenesis, Soil acidification, 010501 environmental sciences, Poaceae, Toxicology, 01 natural sciences, Ecology and Environment, Grassland, Soil, Air Pollution, Soil Pollutants, Ecosystem, Bog, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Ecology, Aquatic Ecology, Biodiversity, General Medicine, Vegetation, Pollution, Forb, Environmental science, Nitrogen Oxides, Species richness, Deposition (chemistry), Sulfur, Environmental Monitoring

Abstract

Nitrogen (N) deposition impacts natural and semi-natural ecosystems globally. The responses of vegetation to N deposition may, however, differ strongly between habitats and may be mediated by the form of N. Although much attention has been focused on the impact of total N deposition, the effects of reduced and oxidised N, independent of the total N deposition, have received less attention. In this paper, we present new analyses of national monitoring data in the UK to provide an extensive evaluation of whether there are differences in the effects of reduced and oxidised N deposition across eight habitat types (acid, calcareous and mesotrophic grasslands, upland and lowland heaths, bogs and mires, base-rich mires, woodlands). We analysed data from 6860 plots in the British Countryside Survey 2007 for effects of total N deposition and N form on species richness, Ellenberg N values and grass:forb ratio. Our results provide clear evidence that that N deposition affects species richness in all habitats except base-rich mires, after factoring out correlated explanatory variables (climate and sulphur deposition). In addition, the form of N in deposition appears important for the biodiversity of grasslands and woodlands but not mires and heaths. Ellenberg N increased more in relation to NHx deposition than NOy deposition in all but one habitat type. Relationships between species richness and N form were habitat-specific: acid and mesotrophic grasslands appear more sensitive to NHx deposition while calcareous grasslands and woodlands appeared more responsive to NOy deposition. These relationships are likely driven by the preferences of the component plant species for oxidised or reduced forms of N, rather than by soil acidification.

Published

2016

5. Coexistence and niche differentiation at large spatial scale in a West-European softwater plant community

Author

Alfons J. P. Smolders, Floris Vanderhaeghe, Maurice Hoffmann, Jan G. M. Roelofs, Leon J.L. van den Berg, and Sofie Ruysschaert

Subjects

0106 biological sciences, Ecological niche, Ecology, Range (biology), 010604 marine biology & hydrobiology, Niche differentiation, Aquatic Ecology, Niche segregation, Plant community, Plant Science, Biology, 010603 evolutionary biology, 01 natural sciences, Environmental niche modelling, Abundance (ecology), Spatial ecology

Abstract

There is growing evidence that species are able to coexist in communities through niche separation, and that consistent community structuring can take place at the biogeographical scale, as the same biotic interactions can determine species’ fate at large scales. In this study, we document niche differentiation at a larger scale within a specific plant community of softwater lakes in Western Europe. Five species were selected for their relative frequency and wide geographical distribution within the dataset that we collected. Their niches were modelled both from presence–absence data and from ordinal abundance data, using mixed regression techniques (generalized linear mixed models and proportional odds mixed models, respectively). The modelled realized niches differed among the species on the West-European scale, although strict separation was not shown and geographical coverage is not complete. Plant strategy characterization of the species supported the assumption that functional traits underpin the niche differentiation among the species through fitness trade-offs. Mechanistic experimental research at a range of spatial scales is needed to test the importance of different community structuring mechanisms at the biogeographical scale, such as biotic interactions and environmental filtering.

Published

2016

6. Territory selection by the Dartford warbler (Sylvia undata) in Dorset, England: the role of vegetation type, habitat fragmentation and population size

Author

Ralph T. Clarke, Rob Rose, James M. Bullock, Leon J.L. van den Berg, and Rowena H. W. Langston

Subjects

education.field_of_study, Habitat fragmentation, biology, Ecology, Population, Sylvia undata, Vegetation, Woodland, biology.organism_classification, Warbler, Geography, Habitat, Vegetation type, education, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

The Dartford warbler (Sylvia undata) is of conservation concern throughout western Europe. In the UK conservation is centred on management of the warbler's lowland heath habitat. This study analysed the warbler's habitat requirements in Dorset, its UK population centre. Maps of breeding territories from 1974, 1984 and 1994 were linked to maps of heathland vegetation and adjacent land use from 1978, 1987 and 1996. Logistic regression showed territories were positively associated with the area of dry/humid heath, mature Ulex europaeus, bare soil, and more rarely with wet heath, young U. europaeus, U. gallii and Pinus scrub. There were negative responses to fragmentation (isolation and area of a heath), and the proximity of woodland, urban areas and intensive agriculture. Sub-optimal habitat was used in years of high population size. Habitat management for this species should consider not only heathland vegetation but also landscape factors such as fragmentation and the proximity of avoided land use types.

Published

2001

7. Sphagnum mosses

Author

Theo J. T. M. Elzenga, Leon P. M. Lamers, Christian Fritz, Leon J.L. van den Berg, Muhammad Riaz, and Elzenga lab

Subjects

Time Factors, Peat, Ecophysiology, BLANKET PEAT, lcsh:Medicine, Plant Science, NITRATE REDUCTASE-ACTIVITY, Sphagnum, chemistry.chemical_compound, Global Change Ecology, Ammonium Compounds, lcsh:Science, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), Bog, COSTA-RICA, Freshwater Ecology, Multidisciplinary, geography.geographical_feature_category, Plant Stems, Ecology, biology, Plant Biochemistry, Sphagnopsida, Plants, Biogeochemistry, Adaptation, Physiological, Sphagnum magellanicum, Environmental chemistry, Research Article, CARBON ACCUMULATION, Nitrogen, Ombrotrophic, Models, Biological, Ecosystems, Plant-Environment Interactions, Botany, Ammonium, Biology, OMBROTROPHIC BOGS, geography, Plant Ecology, lcsh:R, Aquatic Ecology, AMMONIUM, biology.organism_classification, Moss, PHYSIOLOGICAL-RESPONSES, WATER-TABLE, Kinetics, Geochemistry, chemistry, Linear Models, Earth Sciences, lcsh:Q, VASCULAR PLANTS, ATMOSPHERIC NITROGEN DEPOSITION, Ecosystem Modeling

Abstract

Peat forming Sphagnum mosses are able to prevent the dominance of vascular plants under ombrotrophic conditions by efficiently scavenging atmospherically deposited nitrogen (N). N-uptake kinetics of these mosses are therefore expected to play a key role in differential N availability, plant competition, and carbon sequestration in Sphagnum peatlands. The interacting effects of rain N concentration and exposure time on moss N-uptake rates are, however, poorlyunderstood. We investigated the effects of N-concentration (1, 5, 10, 50, 100, 500 mM), N-form (15N - ammonium or nitrate) and exposure time (0.5, 2, 72 h) on uptake kinetics for Sphagnum magellanicum from a pristine bog in Patagonia(Argentina) and from a Dutch bog exposed to decades of N-pollution. Uptake rates for ammonium were higher than for nitrate, and N-binding at adsorption sites was negligible. During the first 0.5 h, N-uptake followed saturation kineticsrevealing a high affinity (Km 3.5–6.5 mM). Ammonium was taken up 8 times faster than nitrate, whereas over 72 hours this was only 2 times. Uptake rates decreased drastically with increasing exposure times, which implies that many short-term Nuptake experiments in literature may well have overestimated long-term uptake rates and ecosystem retention. Sphagnum from the polluted site (i.e. long-term N exposure) showed lower uptake rates than mosses from the pristine site, indicating an adaptive response. Sphagnum therefore appears to be highly efficient in using short N pulses (e.g. rainfall in pristine areas). This strategy has important ecological and evolutionary implications: at high N input rates, the risk of N-toxicity seems to be reduced by lower uptake rates of Sphagnum, at the expense of its long-term filter capacity and relatedcompetitive advantage over vascular plants. As shown by our conceptual model, interacting effects of N-deposition and climate change (changes in rainfall) will seriously alter the functioning of Sphagnum peatlands.

Published

2014

8. Aboveground persistence of vascular plants in relationship to the levels of airborne nutrient deposition

Author

Joop H.J. Schaminée, Leon J.L. van den Berg, Erik Noordijk, Jan M. Van Groenendael, Wim A. Ozinga, and Rob J. J. Hendriks

Subjects

media_common.quotation_subject, Bos- en Landschapsecologie, Plant Ecology and Nature Conservation, Plant Science, Biology, Competition (biology), Persistence (computer science), Nutrient, Grazing, Forest and Landscape Ecology, Vegetatie, media_common, Herbivore, Vegetation, Ecology, Plant Ecology, Aquatic Ecology, PE&RC, nitrogen deposition, Plant ecology, Agronomy, impact, Plantenecologie en Natuurbeheer, Vegetatie, Bos- en Landschapsecologie, Vegetation, Forest and Landscape Ecology, constraints, Eutrophication, Deposition (chemistry)

Abstract

This paper examines whether high atmospheric nitrogen deposition affects aboveground persistence of vascular plants. We combined information on local aboveground persistence of vascular plants in 245 permanent plots in the Netherlands with estimated level of nitrogen deposition at the time of recording. Aboveground persistence of vascular plants was studied using two types of survival statistic technique: Kaplan–Meier analysis and Cox’ regression. We expected a link between nitrogen deposition and loss of plant species due to intensified herbivory or other forms of tissue loss that would lead to diminishing local aboveground persistence. This could not be detected. In contrast, a positive relation was found between local aboveground persistence of plants and high levels of ammonia deposition. This result is considered to be an indication of lower colonization access, for example due to limited space (e.g. the chance of successful establishment of individuals from new species is lower). The results are discussed in relation to the extremely high levels of nitrogen deposition in the studied plots. This study provides an indication that management practices aiming for restoration of colonization access (e.g. mowing, grazing and sod cutting) are vital under heavily eutrophied conditions.

Published

2014

9. Nitrogen as a threat to European terrestrial biodiversity

Author

Jan Willem Erisman, Till Spranger, Leon J.L. van den Berg, Nancy B. Dise, Mike Ashmore, Roland Bobbink, Albert Bleeker, Carly J. Stevens, Salim Belyazid, and Wim de Vries

Subjects

geography, Convention on Biological Diversity, geography.geographical_feature_category, Environmental protection, Ecology, Aquatic biodiversity research, Biodiversity, Environmental science, Ecosystem, Wetland, Natura 2000, Bog, Grassland

Published

2011

10. Ecosystem responses to reduced and oxidised nitrogen inputs in european terrestrial habitats

Author

Juul Limpens, Leon P. M. Lamers, Maaike C. C. De Graaf, A.W. Boxman, María Arróniz-Crespo, Leon J.L. van den Berg, Roland Bobbink, Carly J. Stevens, Peter Manning, Edu Dorland, Albert Bleeker, Philippine Vergeer, and G.W. Wieger Wamelink

Subjects

throughfall deposition, Nitrogen, Health, Toxicology and Mutagenesis, Soil acidification, pinus-sylvestris l, chemistry.chemical_element, Plant Ecology and Nature Conservation, Toxicology, acidic grasslands, Soil pH, Soil Pollutants, spruce picea-abies, Ecosystem, Wageningen Environmental Research, vascular plants, species richness, Nitrogen Compounds, Nitrogen cycle, Environmental Restoration and Remediation, soil solution chemistry, WIMEK, CL - Ecological Models and Monitoring, Ecology, Plant Ecology, atmospheric ammonia, intracellular ph, Aquatic Ecology, General Medicine, Plants, Pollution, nitrate reduction, Europe, chemistry, Environmental chemistry, CL - Ecologische Modellen en Monitoring, Soil water, WIAS, Plantenecologie en Natuurbeheer, Environmental science, Nitrogen Oxides, Nitrification, Species richness, Oxidation-Reduction

Abstract

While it is well established that ecosystems display strong responses to elevated nitrogen deposition, the importance of the ratio between the dominant forms of deposited nitrogen (NH(x) and NO(y)) in determining ecosystem response is poorly understood. As large changes in the ratio of oxidised and reduced nitrogen inputs are occurring, this oversight requires attention. One reason for this knowledge gap is that plants experience a different NH(x):NO(y) ratio in soil to that seen in atmospheric deposits because atmospheric inputs are modified by soil transformations, mediated by soil pH. Consequently species of neutral and alkaline habitats are less likely to encounter high NH(4)(+) concentrations than species from acid soils. We suggest that the response of vascular plant species to changing ratios of NH(x):NO(y) deposits will be driven primarily by a combination of soil pH and nitrification rates. Testing this hypothesis requires a combination of experimental and survey work in a range of systems.

Published

2011

11. Atmospheric nitrogen deposition explains patterns of plant species loss

Author

Mike Ashmore, Leon J.L. van den Berg, Colin J. McClean, and Christopher D. Preston

Subjects

Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, Aquatic Ecology, Pasture, Agronomy, Habitat, Grazing, Environmental Chemistry, Environmental science, Land use, land-use change and forestry, Species richness, Arable land, Eutrophication, Deposition (chemistry), General Environmental Science

Abstract

Atmospheric nitrogen (N) deposition across Europe increased substantially from the 1950s to the 1990s. Targeted surveys suggest a negative correlation between N deposition and species richness within quadrats in sensitive habitats. However, it remains unclear whether plant species losses at national recording scales are correlated with nitrogen deposition. We relate plant species losses before 1987 in Great Britain to reduced and oxidized N deposition, land use change and climate change. The mean Ellenberg fertility (N) indices of plant species lost in each 100 km2 cell before 1987 was compared with those of species that were recorded between 1987 and 1999. In 45% of squares, indices of species lost were significantly lower than those for species present after 1986. For 17%, primarily upland, squares, the opposite effect was found. A generalized least squares regression model, with difference in the mean Ellenberg N index between samples as the dependent variable, showed that higher deposition of reduced N was significantly associated with selective loss of species with a lower index. Arable land use and change in arable land use also demonstrated this positive relationship. Rough grazing, change in rough grazing, change in pasture and change in annual precipitation showed negative effects. Difference in Ellenberg R index was highly correlated with difference in Ellenberg N and was negatively correlated with oxidized N deposition, suggesting that the lack of a significant effect of oxidized N deposition on Ellenberg N was because it had effects through both acidification and eutrophication, while the effect of reduced N deposition was primarily through eutrophication. Our results suggest that N deposition, along with land use and precipitation changes, has been a significant driver of local plant extinctions. With N deposition increasing in many parts of the world, local extinctions of plant species may be experienced in other regions.

Published

2011

12. Catchment liming to restore degraded, acidified heathlands and moorland pools

Author

Emiel Brouwer, Roland Bobbink, Leon J.L. van den Berg, Edu Dorland, and Jan G. M. Roelofs

Subjects

geography, geography.geographical_feature_category, Ecology, Drainage basin, Aquatic Ecology, Vegetation, complex mixtures, Macrophyte, Hydrology (agriculture), Habitat, Agronomy, Abundance (ecology), Moorland, Environmental science, Ecosystem, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Current restoration measures of degraded, acidified heathland ecosystems have not always been successful in the Netherlands. Positive effects of a restored hydrology are often counteracted by acidification of the soil and the local groundwater system. Liming of the heathlands in the catchment of moorland pools might contribute to the restoration of both habitats. Experimental catchment liming was carried out in two degraded Dutch heathlands, with doses varying between 2 and 6 tons/ha. Catchment liming resulted in increased pH and base cation concentrations in the highest elevated limed parts, as well as in the lower situated, nonlimed heath areas and moorland pools. Generally, catchment liming created suitable conditions for the return of heathland target species, and the positive effects lasted for at least 6 years. The response of the heathland vegetation to the liming has, however, been slow because only a small number of endangered plant species increased in abundance. In contrast, four Red List soft-water macrophytes strongly increased in abundance in the moorland pool. Our results show that, even with the slow return of Red List plant species, catchment liming can be a successful management tool for the restoration of the acidified heathland landscape.

Published

2005