Your search keyword '"Uta Friedrich"' showing total 6 results

1. Bryophytes and Organic layers Control Uptake of Airborne Nitrogen in Low-N Environments

Author

Andreas Fichtner, Goddert von Oheimb, Werner Härdtle, Alexandra Bähring, and Uta Friedrich

Subjects

0106 biological sciences, Denitrification, 010504 meteorology & atmospheric sciences, ved/biology.organism_classification_rank.species, chemistry.chemical_element, Plant Science, heathland, lcsh:Plant culture, 010603 evolutionary biology, 01 natural sciences, Shrub, Sink (geography), nitrogen retention, nitrogen cycling, nitrogen saturation, Ecosystem, lcsh:SB1-1110, Biology, Nitrogen cycle, 0105 earth and related environmental sciences, Original Research, geography, Critical load, geography.geographical_feature_category, biology, critical load, Nitrogen saturation, ved/biology, Calluna vulgaris, biology.organism_classification, Moss, Nitrogen, Nitrogen retention, chemistry, Environmental chemistry, Soil horizon, Environmental science, Heathland, Nitrogen cycling

Abstract

The effects of atmospheric nitrogen (N) deposition on ecosystem functioning largely depend on the retention of N in different ecosystem compartments, but accumulation and partitioning processes have rarely been quantified in long-term field experiments. In the present study we analysed for the first time decadal-scale flows and allocation patterns of N in a heathland ecosystem that has been subject to airborne N inputs over decades. Using a long-term 15N tracer experiment, we quantified N retention and flows to and between ecosystem compartments (above-ground/below-ground vascular biomass, moss layer, soil horizons, leachate). After 9 years, about 60% of the added 15N-tracer remained in the N cycle of the ecosystem. The moss layer proved to be a crucial link between incoming N and its allocation to different ecosystem compartments (in terms of a short-term capture, but long-term release function). However, about 50% of the 15N captured and released by the moss layer was not compensated for by a corresponding increase in recovery rates in any other compartment, probably due to denitrification losses from the moss layer in the case of water saturation after rain events. The O-horizon proved to be the most important long-term sink for added 15N, as reflected by an increase in recovery rates from 18 to 40% within 8 years. Less than 2.1% of 15N were recovered in the podzol-B-horizon, suggesting that only negligible amounts of N were withdrawn from the N cycle of the ecosystem. Moreover, 15N recovery was low in the dwarf shrub above-ground biomass (

Published

2017

2. Nitrogen deposition and drought events have non-additive effects on plant growth – Evidence from greenhouse experiments

Author

Werner Härdtle, G. von Oheimb, Uta Friedrich, Maren Meyer-Grünefeldt, and M. Klotz

Subjects

Calluna, Greenhouse, chemistry.chemical_element, interaction effects, Plant Science, Interaction, Nutrient, Ecosystem, Biology, Ecology, Evolution, Behavior and Systematics, Biomass (ecology), biology, Phosphorus, fungi, food and beverages, Calluna vulgaris, biology.organism_classification, climate change, Ecosystems Research, chemistry, Agronomy, Shoot, Environmental science, biomass allocation

Abstract

Climate change and nitrogen deposition affect biodiversity and ecosystem functioning, but interactive effects of these global change drivers are poorly understood. We analysed single and interactive effects of nitrogen (N) fertilisation and drought on the growth performance of Calluna vulgaris. We measured biomass production and allocation, tissue nutrient (N, phosphorus (P) and carbon (C)) concentrations, N allocation patterns (using 15N tracer) and plant's water status (using δ 13C signatures) as response variables in a 2-year greenhouse experiment. N fertilisation increased biomass production and biomass shoot:root ratios. 15N allocation patterns indicated an increasing aboveground N allocation following N fertilisation. Tissue δ 13C signatures were higher in N-fertilised plants. Plant responses to drought were weak. We found strong antagonistic interaction effects of N fertilisation and drought for biomass production. δ 13C values peaked when N-fertilised plants were subjected to drought, indicating that N fertilisation increased the evaporative demands of Calluna plants, likely due to increased biomass shoot:root ratios, which in turn resulted in higher drought susceptibility. As an important consequence, even slight drought events may weaken the competitiveness of Calluna when interacting with enhanced airborne N loads. Single-factor studies, thus, need to be complemented by multi-factor analyses to assess conceivable impacts of co-occurring global change drivers.

Published

2013

3. Fate of airborne nitrogen in heathland ecosystems: a 15N tracer study

Author

Goddert von Oheimb, Hartmut Meyer, Uta Friedrich, Thorben Marquardt, Werner Härdtle, Kirsten Falk, Thomas Niemeyer, Enno Bahlmann, and Siegfried Schemmel

Subjects

Calluna, Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, biology, biology.organism_classification, Sink (geography), Podzol, Environmental chemistry, TRACER, Botany, Environmental Chemistry, Soil horizon, Environmental science, Ecosystem, Cycling, Nitrogen cycle, General Environmental Science

Abstract

In the present study, we analyze the fate of airborne nitrogen in heathland ecosystems (NW Germany) by means of a 15N tracer experiment. Our objective was to quantify N sequestration and N allocation patterns in an ecosystem that is naturally limited by N, but that has been exposed to airborne N inputs exceeding critical loads for more than 3 decades. We hypothesized that the system has a tendency towards N saturation, which should be indicated by low N sequestration and high N leaching. We analyzed 15N partitioning (aboveground biomass and soil horizons) and investigated 15N leaching over 2 years following a 15N tracer pulse addition. 15N tracer recovery was 90% and 76% in the first and second year, respectively. Contrary to our expectations, more than 99% of the tracer recovered was sequestered in the biomass and soil, while leaching losses were

Published

2010

4. Mechanisms of purple moor-grass (Molinia caerulea) encroachment in dry heathland ecosystems with chronic nitrogen inputs

Author

Werner Härdtle, Christoph Dziedek, Uta Friedrich, Katharina Selbmann, Wolf-Ulrich Kriebitzsch, and Goddert von Oheimb

Subjects

Calluna, Nitrogen, Health, Toxicology and Mutagenesis, media_common.quotation_subject, Poaceae, Toxicology, N deposition, Competition (biology), Soil, Biomass allocation, Botany, Dominance (ecology), Biomass, Fertilizers, Nitrogen cycle, Biology, Ecosystem, media_common, Nutrient sequestration, Biomass (ecology), Competition, biology, Calluna vulgaris, Molinia caerulea, General Medicine, biology.organism_classification, Pollution, Ecosystems Research, Monoculture, Caerulea

Abstract

We analysed growth strategies (biomass allocation, nutrient sequestration and allocation) of heather(Calluna vulgaris) and purple moor-grass (Molinia caerulea) seedlings in monocultures and mixtures inrelation to N, P, and N þ P fertilisation in a greenhouse experiment in order to simulate a heath’s pioneerphase under high airborne nitrogen (N) loads. N fertilisation increased the total biomass of both speciesin monocultures. In mixtures, M. caerulea sequestered about 65% of the N applied, while C. vulgarissuffered from N shortage (halving of the total biomass). Thus, in mixtures only M. caerulea will benefitfrom airborne N loads, and competition will become increasingly asymmetric with increasing N availability.Our results demonstrate that the heath’s pioneer phase is the crucial tipping point at which thecompetitive vigour of M. caerulea (high belowground allocation, efficient use of belowground resources,shortened reproductive cycles) induces a shift to dominance of grasses under increased N availability.

Published

2011

5. Molinia caerulea responses to N and P fertilisation in a dry heathland ecosystem (NW-Germany)

Author

Goddert von Oheimb, Werner Härdtle, Uta Friedrich, Kirsten Falk, Konrad Merkle, Kerstin Mischke, and Hartmut Meyer

Subjects

Canopy, Biomass (ecology), Ecology, biology, Biodiversity, Molinia caerulea, Plant Science, biology.organism_classification, P ratio [N], Plant ecology, Nutrient, Agronomy, Productivity (ecology), Ecosystems Research, Biomass allocation, Nutrient limitation, Phosphorous supply, Ecosystem, Biology, Productivity

Abstract

In the present study we analysed whether airborne N pollution may constitute one important driver for the encroachment of Molinia caerulea in dry heathland ecosystems. Based on full-factorial field experiments (in 2006 and 2008) and complementary greenhouse experiments (in 2008), we quantified growth responses of Molinia caerulea to N and P fertilisation (50 kg N ha(-1) year(-1), 20 kg P ha(-1) year(-1)). Aboveground biomass production of Molinia caerulea was limited by P in 2006, but by N in both experiments in 2008. In the greenhouse experiment, N addition caused a sixfold increase of the biomass of vegetative tillers, and in all experiments the biomass and numbers of flowering tillers showed a significant increase due to fertilisation. Our experiments indicated that growth of Molinia caerulea was primarily limited by N, but in dry heaths the kind of nutrient limitation may be mediated by other factors such as water availability during the vegetative period. Shifts in biomass allocation patterns resulting from N fertilisation showed that Molinia caerulea encroachment in dry heaths is not only attributable to increased leaf biomass, but also due to higher investments in reproductive tissue that allow for increased seed production and thus accelerated encroachment of seedlings in places where the dwarf shrub canopy has been opened after disturbance.

Published

2010

6. N:P Ratio and the Nature of Nutrient Limitation in Calluna-Dominated Heathlands

Author

Abdelmenam Mohamed, Goddert von Oheimb, Werner Härdtle, Angelika Krug, Nora Boschatzke, Uta Friedrich, Sally A. Power, and Kirsten Falk

Subjects

Calluna, Limiting factor, chemistry.chemical_element, Phosphorus limitation, Nitrogen deposition, Nutrient, Environmental Chemistry, Ecosystem, Biology, Ecology, Evolution, Behavior and Systematics, Plant growth, Ecology, biology, Nitrogen saturation, Phosphorus, Calluna vulgaris, biology.organism_classification, chemistry, Agronomy, Ecosystems Research, Ericaceae, Shoot, Terrestrial ecosystem, Fertilization experiment

Abstract

There is growing evidence from different sources that prolonged high N deposition causes a shift from nitrogen (N) limitation to nitrogen and phosphorus (P) co-limitation or even P limitation in many terrestrial ecosystems. However, the number of ecosystems where the type of limitation has been directly tested by longer-term full-factorial field experiments is very limited. We conducted a 5-year fertilization experiment with N and P in the Lüneburger Heide (NW Germany) to test the hypothesis that, following decades of elevated atmospheric N inputs, plant growth in dry lowland heaths may have shifted from N to N-P co-limitation or P limitation. We also tested whether the plant tissue N:P ratio reflects the type of nutrient limitation in a continental lowland heathland. Experimental plots dominated by Calluna vulgaris received regular additions of N (50 kg N ha -1 y -1), P (20 kg P ha -1 y -1), a combination of both, or water only (control) from 2004 to 2008. Over the whole study period, a highly significant positive N effect on shoot length was found, thus indicating N limitation. We conclude that a clear shift from N limitation to N-P co-limitation or P limitation has not yet occurred. Tissue N:P ratios showed a high temporal variability and no relationship between tissue N:P ratio and the shoot length response of Calluna to nutrient addition was found. The N:P tool is thus of limited use at the local scale and within the range of N:P ratio observed in this study, and should only be used as a rough indicator for the prediction of the type of nutrient limitation in lowland heathland on a larger geographical scale with a broader interval of N:P ratio.

Published

2010