Your search keyword '"Corcket, Emmanuel"' showing total 10 results

1. Changes in species composition of European acid grasslands observed along a gradient of nitrogen deposition

Author

Stevens, Carly, Duprè, Cecilia, Gaudnik, Cassandre, Dorland, Edu, Dise, Nancy, Gowing, David, Bleeker, Albert, Alard, Didier, Bobbink, Roland, Fowler, David, Vandvik, Vigdis, Corcket, Emmanuel, Mountford, J. Owen, Aarrestad, Per Arild, Muller, Serge, and Diekmann, Martin

Published

2011

2. Nitrogen deposition and climate change have increased vascular plant species richness and altered the composition of grazed subalpine grasslands.

Author

Boutin, Marion, Corcket, Emmanuel, Alard, Didier, Villar, Luis, Jiménez, Juan‐José, Blaix, Cian, Lemaire, Cédric, Corriol, Gilles, Lamaze, Thierry, Pornon, André, and Avolio, Meghan

Subjects

*CLIMATE change, *NITROGEN fixation, *VASCULAR plants, *PLANT species diversity, *GRASSLANDS

Abstract

Atmospheric nitrogen ( N) deposition and climate warming are two major components of global change that drive species richness and composition in plant communities. However, their combined effects have been insufficiently investigated across large spatial and temporal scales particularly in high-elevation, nutrient-limited ecosystems., We examine whether and how N deposition and climate warming have altered the plant richness and the composition of subalpine semi-natural, extensively grazed grasslands of the Pyrenees, using two complementary approaches: (i) analysis of 553 relevés to explore vegetation changes across large ecological gradients including temperature and N deposition (spatial approach) and (ii) a re-sampling of a subset of 40 sites among the 553 sites to assess temporal changes over the past decades (temporal approach)., Both approaches showed that the vascular plant species richness increased when temperature and cumulative N deposition increase, shifting the species composition towards more thermophilic and eutrophic communities., Synthesis. We hypothesize that the release from abiotic constraints (milder temperature and higher nitrogen availability) due to global changes and long-standing extensive grazing counteracting the negative effects of nitrogen deposition have been responsible for the diversity and compositional changes of plant communities over the last decades in the Pyrenees. Thus, in contrast with other grasslands, high-elevation grazed grasslands may increase in species diversity with nitrogen deposition under climate warming. [ABSTRACT FROM AUTHOR]

Published

2017

3. Limiting processes for perennial plant reintroduction to restore dry grasslands.

Author

Buisson, Elise, Corcket, Emmanuel, and Dutoit, Thierry

Subjects

*PLANT reintroduction, *GRASSLANDS, *BIOMASS, *THYMUS, *GRAZING

Abstract

In restored grasslands of southern Europe, perennial plants remain highly underrepresented compared with the reference ecosystems. We tested various treatments to reintroduce common perennial plant species ( Brachypodium retusum, Poaceae, and Thymus vulgaris, Lamiaceae), which are usually not or poorly reintroduced via soil and hay transfer. Treatments included microenvironmental manipulations (rock cover and plant interactions) and two grazing intensities. Target perennial species were transplanted in 2002 in the reference grassland ecosystem (intact grassland area used as a control) and in two abandoned fields. Survival was assessed in June 2003 and June 2004. Target species shoot and root biomass were measured in June 2004. Grazing greatly reduced the survival and biomass of both target species and its effects were reinforced by summer drought: plants that did not establish well enough during the autumn and spring did not survive summer. The restored rock cover had a mild positive effect, particularly on B. retusum. There were no negative or positive plant neighbor interactions in the steppe, while there was competition in both abandoned fields. Competition was particularly intense in the abandoned melon field, composed of a dense sward of annual grasses ( Bromus sp.). In order to reintroduce perennial species to dry grasslands, the ideal combination of treatments is to exclude or reduce grazing during the first year to allow seedlings to establish and to recreate adequate microenvironmental conditions. Reducing competition from arable weeds may help but is not essential in such dry grasslands. [ABSTRACT FROM AUTHOR]

Published

2015

4. Soil phosphorus constrains biodiversity across European grasslands.

Author

Ceulemans, Tobias, Stevens, Carly J., Duchateau, Luc, Jacquemyn, Hans, Gowing, David J. G., Merckx, Roel, Wallace, Hilary, Rooijen, Nils, Goethem, Thomas, Bobbink, Roland, Dorland, Edu, Gaudnik, Cassandre, Alard, Didier, Corcket, Emmanuel, Muller, Serge, Dise, Nancy B., Dupré, Cecilia, Diekmann, Martin, and Honnay, Olivier

Subjects

PHOSPHORUS in soils, EFFECT of phosphorus on plants, GRASSLANDS, BIODIVERSITY conservation, PLANT diversity

Abstract

Nutrient pollution presents a serious threat to biodiversity conservation. In terrestrial ecosystems, the deleterious effects of nitrogen pollution are increasingly understood and several mitigating environmental policies have been developed. Compared to nitrogen, the effects of increased phosphorus have received far less attention, although some studies have indicated that phosphorus pollution may be detrimental for biodiversity as well. On the basis of a dataset covering 501 grassland plots throughout Europe, we demonstrate that, independent of the level of atmospheric nitrogen deposition and soil acidity, plant species richness was consistently negatively related to soil phosphorus. We also identified thresholds in soil phosphorus above which biodiversity appears to remain at a constant low level. Our results indicate that nutrient management policies biased toward reducing nitrogen pollution will fail to preserve biodiversity. As soil phosphorus is known to be extremely persistent and we found no evidence for a critical threshold below which no environmental harm is expected, we suggest that agro-environmental schemes should include grasslands that are permanently free from phosphorus fertilization. [ABSTRACT FROM AUTHOR]

Published

2014

5. Differential Effects of Oxidised and Reduced Nitrogen on Vegetation and Soil Chemistry of Species-Rich Acidic Grasslands.

Author

Dorland, Edu, Stevens, Carly, Gaudnik, Cassandre, Corcket, Emmanuel, Rotthier, Suzanne, Wotherspoon, Katherine, Jokerud, Mari, Vandvik, Vigdis, Soons, Merel, Hefting, Mariet, Aarrestad, Per, Alard, Didier, Diekmann, Martin, Duprè, Cecilia, Dise, Nancy, Gowing, David, and Bobbink, Roland

Subjects

NITROGEN cycle, PLANT diversity, ATMOSPHERIC nitrogen, LIFE zones, GRASSLANDS

Abstract

Emissions and deposition of ammonia and nitrogen oxides have strongly increased since the 1950s. This has led to significant changes in the nitrogen (N) cycle, vegetation composition and plant diversity in many ecosystems of high conservation value in Europe. As a consequence of different regional pollution levels and of the increased importance of reduced N in the near future, determining the effect of different forms of N is an important task for understanding the consequences of atmospheric N inputs. We have initiated three replicated N addition experiments in species-rich, acidic grasslands spanning a climatic gradient in the Atlantic biogeographic region of Europe in Norway, Wales and France at sites with low levels of pollution. N was added in two doses (0 and 70 kg N ha year above background) and in three forms (oxidised N, reduced N and a 50-50 combination). After 2.5 years of N additions, the effects of these treatments on plant biomass, plant nutritional status, soil pH and soil nutrient availability were determined. Impacts of the N additions were observed within the 2.5-year research period. In some cases, the first signs of differential effects of N form could also be demonstrated. In the French site, for example, grass biomass was significantly increased by the oxidised N treatments but decreased by the reduced N treatments. In the Norwegian site, the reduced N treatments significantly reduced soil pH, whereas oxidised N did not. Effects on nutrient availability were also observed. These experiments will be continued to elucidate the longer term impacts of N deposition on these grasslands. [ABSTRACT FROM AUTHOR]

Published

2013

6. Detecting the footprint of changing atmospheric nitrogen deposition loads on acid grasslands in the context of climate change.

Author

Gaudnik, Cassandre, Corcket, Emmanuel, Clément, Bernard, Delmas, Chloé E. L., Gombert-Courvoisier, Sandrine, Muller, Serge, Stevens, Carly J., and Alard, Didier

Subjects

*NITROGEN, *CLIMATE change, *GRASSLANDS, *VEGETATION & climate, *ATMOSPHERIC temperature, *WATER

Abstract

Although atmospheric nitrogen ( N) deposition and climate changes are both recognized as major components of global change, their interaction at ecosystem level is less well understood. A stratified resampling approach was used to investigate the potential impact of changing levels of atmospheric nitrogen deposition and climate change on species composition of nutrient-poor acid grasslands within the French Atlantic Domain ( FAD). The study was based on a comparison, over a period of 25 years, of 162 past and present vegetation records assigned to the species-rich Nardus grasslands and distributed in regional community types ( CTs). Similarly, the characterization of N deposition and climate was stratified according to (i) past (1980-1990) and present (1995-2005) periods, and (ii) FAD and CT scales. Despite the relatively short time span between sampling periods, significant N deposition and climate changes were detected as well as vegetation changes. Correspondence analysis showed that the relative importance of N deposition and climate in explaining vegetation changes depended on the spatial scale of investigation ( FAD vs. local CTs) and the CT. At the FAD scale, the increase of annual mean temperature and decrease of water availability were clearly related to the changes in floristic composition. At the local scale, the most stable CT experienced no significant climate change and a stable load of N deposition, whereas the CTs characterized by the largest floristic changes were associated with dramatic climate changes and moderate loads in both oxidized and reduced N deposition. Despite the narrow gradient of deposition investigated, N deposition was related to significant grassland community changes, depending on the region, i.e. climate context, and on whether N deposition was in the oxidized or reduced form. Our results suggest that N deposition drives grassland composition at the local scale, in interaction with climate, whereas climate changes remain the predominant driver at the FAD scale. [ABSTRACT FROM AUTHOR]

Published

2011

7. The impact of nitrogen deposition on acid grasslands in the Atlantic region of Europe.

Author

Stevens, Carly J., Duprè, Cecilia, Dorland, Edu, Gaudnik, Cassandre, Gowing, David J.G., Bleeker, Albert, Diekmann, Martin, Alard, Didier, Bobbink, Roland, Fowler, David, Corcket, Emmanuel, Mountford, J. Owen, Vandvik, Vigdis, Aarrestad, Per Arild, Muller, Serge, and Dise, Nancy B.

Subjects

ECOLOGY, GRASSLANDS, ATMOSPHERIC deposition -- Environmental aspects, ATMOSPHERIC nitrogen compounds, NITROGEN & the environment, GRASSLAND plants, EFFECT of nitrogen on plants

Abstract

A survey of 153 acid grasslands from the Atlantic biogeographic region of Europe indicates that chronic nitrogen deposition is changing plant species composition and soil and plant-tissue chemistry. Across the deposition gradient (2–44 kg N ha−1 yr−1) grass richness as a proportion of total species richness increased whereas forb richness decreased. Soil C:N ratio increased, but soil extractable nitrate and ammonium concentrations did not show any relationship with nitrogen deposition. The above-ground tissue nitrogen contents of three plant species were examined: Agrostis capillaris (grass), Galium saxatile (forb) and Rhytidiadelphus squarrosus (bryophyte). The tissue nitrogen content of neither vascular plant species showed any relationship with nitrogen deposition, but there was a weak positive relationship between R. squarrosus nitrogen content and nitrogen deposition. None of the species showed strong relationships between above-ground tissue N:P or C:N and nitrogen deposition, indicating that they are not good indicators of deposition rate. [Copyright &y& Elsevier]

Published

2011

8. Nitrogen deposition threatens species richness of grasslands across Europe.

Author

Stevens, Carly J., Duprè, Cecilia, Dorland, Edu, Gaudnik, Cassandre, Gowing, David J.G., Bleeker, Albert, Diekmann, Martin, Alard, Didier, Bobbink, Roland, Fowler, David, Corcket, Emmanuel, Mountford, J. Owen, Vandvik, Vigdis, Aarrestad, Per Arild, Muller, Serge, and Dise, Nancy B.

Subjects

PHYSIOLOGICAL effects of atmospheric deposition, EFFECT of nitrogen on plants, SPECIES diversity, GRASSLANDS, SOIL acidity, HYDROGEN-ion concentration

Abstract

Evidence from an international survey in the Atlantic biogeographic region of Europe indicates that chronic nitrogen deposition is reducing plant species richness in acid grasslands. Across the deposition gradient in this region (2–44 kg N ha−1 yr−1) species richness showed a curvilinear response, with greatest reductions in species richness when deposition increased from low levels. This has important implications for conservation policies, suggesting that to protect the most sensitive grasslands resources should be focussed where deposition is currently low. Soil pH is also an important driver of species richness indicating that the acidifying effect of nitrogen deposition may be contributing to species richness reductions. The results of this survey suggest that the impacts of nitrogen deposition can be observed over a large geographical range. [Copyright &y& Elsevier]

Published

2010

9. Reintroduction of Nassella pulchra to California coastal grasslands: Effects of topsoil removal, plant neighbour removal and grazing.

Author

Buisson, Elise, Anderson, Sean, Holl, Karen D., Corcket, Emmanuel, Hayes, Grey F., Peeters, Alain, and Dutoit, Thierry

Subjects

GRASSLANDS, ECOLOGY, BRASSICA, FORAGE plants, RANGE management, AGRICULTURE

Abstract

Question: What is the most appropriate combination of treatments to reintroduce Nassella pulchra, a perennial bunchgrass, into degraded mediterranean coastal grasslands? Location: Central coast of California, USA. Methods: N. pulchra was sown from seeds and transplanted into a degraded grassland in a multi-factorial experiment testing the effects of (1) two grazing intensities (lightly grazed by native mammal species or ungrazed); (2) topsoil removal and (3) reduction of plant neighbours. The experiment was carried out on two types of surrounding vegetation (exotic annual grasses and exotic forbs). Results: Topsoil removal greatly enhanced establishment from seeds and transplant survival, mainly because it reduced the exotic vegetation and thus reduced competition. While removing neighbours was essential when topsoil was left intact, it had a negative effect on N. pulchra when surrounding species included exotic forbs ( Brassica spec, and Asteraceae) at low density (after topsoil removal). Moderate grazing by native mammals (deer, rabbits and gophers) did not affect N. pulchra. Conclusion: Our results suggest that seeding after topsoil has been removed is a promising method to reintroduce N. pulchra to highly degraded sites where there is little to no native seed bank. [ABSTRACT FROM AUTHOR]

Published

2008

10. Long-term changes in calcareous grassland vegetation in North-western Germany – No decline in species richness, but a shift in species composition.

Author

Diekmann, Martin, Jandt, Ute, Alard, Didier, Bleeker, Albert, Corcket, Emmanuel, Gowing, David J.G., Stevens, Carly J., and Duprè, Cecilia

Subjects

*GRASSLANDS, *CALCAREA, *PLANT ecology, *SPECIES diversity

Abstract

Highlights: [•] We studied the change in dry calcareous grassland vegetation over the past 70years. [•] We compiled 1186 plots from the sub-oceanic regions in North-western Germany. [•] Plot species richness did not, or only marginally change, over time. [•] Species composition changed, with typical dry grassland species decreasing. [•] Atmospheric nitrogen deposition did not show clear effects on the vegetation. [ABSTRACT FROM AUTHOR]

Published

2014