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Your search keyword '"Garabet Kazanjian"' showing total 5 results
Start Over Author "Garabet Kazanjian" Topic environmental science
5 results on '"Garabet Kazanjian"'

2. Cross continental increase in methane ebullition under climate change

Author

Mandy Velthuis, Sabine Hilt, Edwin T. H. M. Peeters, Dedmer B. Van de Waal, J. Wilkinson, Leon P. M. Lamers, Garabet Kazanjian, Nathan Barros, Sarian Kosten, Martin Wik, Susanne Stephan, Jan G. M. Roelofs, Thijs Frenken, Tonya DelSontro, Ellen Van Donk, Brett F. Thornton, Lisette N. de Senerpont Domis, Ralf Aben, Aquatic Ecology (AqE), and AKWA

Subjects
Aquatic Ecology and Water Quality Management, 010504 meteorology & atmospheric sciences, Science, General Physics and Astronomy, Climate change, 010501 environmental sciences, 01 natural sciences, Freshwater ecosystem, Article, General Biochemistry, Genetics and Molecular Biology, Methane, Mesocosm, chemistry.chemical_compound, medicine, Life Science, Organic matter, Ecosystem, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), 0105 earth and related environmental sciences, chemistry.chemical_classification, Multidisciplinary, Global warming, Aquatic Ecology, General Chemistry, Seasonality, Aquatische Ecologie en Waterkwaliteitsbeheer, medicine.disease, Oceanography, chemistry, 13. Climate action, international, Environmental science
Abstract

Methane (CH4) strongly contributes to observed global warming. As natural CH4 emissions mainly originate from wet ecosystems, it is important to unravel how climate change may affect these emissions. This is especially true for ebullition (bubble flux from sediments), a pathway that has long been underestimated but generally dominates emissions. Here we show a remarkably strong relationship between CH4 ebullition and temperature across a wide range of freshwater ecosystems on different continents using multi-seasonal CH4 ebullition data from the literature. As these temperature–ebullition relationships may have been affected by seasonal variation in organic matter availability, we also conducted a controlled year-round mesocosm experiment. Here 4 °C warming led to 51% higher total annual CH4 ebullition, while diffusion was not affected. Our combined findings suggest that global warming will strongly enhance freshwater CH4 emissions through a disproportional increase in ebullition (6–20% per 1 °C increase), contributing to global warming., The impacts of climate change on natural methane (CH4) emissions via ebullition are unclear. Here, using published and experimental multi-seasonal CH4 ebullition data, the authors find a strong relationship between CH4 ebullition and temperature across a wide range of freshwater ecosystems globally.

Published
2017
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3. Warming enhances sedimentation and decomposition of organic carbon in shallow macrophyte-dominated systems with zero net effect on carbon burial

Author

Ralf Aben, Mandy Velthuis, Edwin T. H. M. Peeters, Sarian Kosten, Sabine Hilt, Garabet Kazanjian, Ellen Van Donk, Elisabeth S. Bakker, and Aquatic Ecology (AqE)

Subjects
0106 biological sciences, Carbon Sequestration, Aquatic Ecology and Water Quality Management, decomposition, sedimentation, mineralization, phenology, carbon cycle, submerged aquatic plant, primary production, global warming, 010504 meteorology & atmospheric sciences, Biomass, chemistry.chemical_element, Fresh Water, 01 natural sciences, Carbon cycle, Dissolved organic carbon, Environmental Chemistry, Organic matter, Saxifragales, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, Total organic carbon, chemistry.chemical_classification, Global and Planetary Change, Detritus, WIMEK, Ecology, 010604 marine biology & hydrobiology, fungi, Temperature, Aquatic Ecology, Aquatische Ecologie en Waterkwaliteitsbeheer, Carbon, chemistry, international, Greenhouse gas, Environmental chemistry, Environmental science, Seasons
Abstract

Contains fulltext : 195210.pdf (Publisher’s version ) (Open Access) Abstract Temperatures have been rising throughout recent decades and are predicted to rise further in the coming century. Global warming affects carbon cycling in freshwater ecosystems, which both emit and bury substantial amounts of carbon on a global scale. Currently, most studies focus on the effect of warming on overall carbon emissions from freshwater ecosystems, while net effects on carbon budgets may strongly depend on burial in sediments. Here, we tested whether year-round warming increases the production, sedimentation, or decomposition of particulate organic carbon and eventually alters the carbon burial in a typical shallow freshwater system. We performed an indoor experiment in eight mesocosms dominated by the common submerged aquatic plant Myriophyllum spicatum testing two temperature treatments: a temperate seasonal temperature control and a warmed (+4°C) treatment (n = 4). During a full experimental year, the carbon stock in plant biomass, dissolved organic carbon in the water column, sedimented organic matter, and decomposition of plant detritus were measured. Our results showed that year-round warming nearly doubled the final carbon stock in plant biomass from 6.9 ± 1.1 g C in the control treatment to 12.8 ± 0.6 g C (mean ± SE), mainly due to a prolonged growing season in autumn. DOC concentrations did not differ between the treatments, but organic carbon sedimentation increased by 60% from 96 ± 9.6 to 152 ± 16 g C m?2 yaer?1 (mean ± SE) from control to warm treatments. Enhanced decomposition of plant detritus in the warm treatment, however, compensated for the increased sedimentation. As a result, net carbon burial was 40 ± 5.7 g C m?2 year?1 in both temperature treatments when fluxes were combined into a carbon budget model. These results indicate that warming can increase the turnover of organic carbon in shallow macrophyte-dominated systems, while not necessarily affecting net carbon burial on a system scale.

Published
2018

5. Primary production in nutrient-rich kettle holes and consequences for nutrient and carbon cycling

Author

Jan Köhler, Katrin Attermeyer, Katrin Premke, Sabine Flury, Andreas Kleeberg, Thomas Kalettka, Garabet Kazanjian, and Sabine Hilt

Subjects
0106 biological sciences, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Macrophytes, Anoxia, Ponds, Periphyton, Depressional wetlands, Gross primary production, Phosphorus, Potholes, 010604 marine biology & hydrobiology, Sediment, Primary production, Aquatic Science, 01 natural sciences, Freshwater ecosystem, Carbon cycle, Macrophyte, Kettle (landform), Nutrient, Environmental science, 0105 earth and related environmental sciences
Abstract

Kettle holes are often abundant within agriculturally used moraine landscapes. They are highly enriched with nutrients and considered hotspots of carbon turnover. However, data on their primary productivity remain rare. We analysed two kettle holes typical to Germany with common aquatic plant communities during one year. We hypothesised that gross primary production (GPP) rates would be high compared to other temperate freshwater ecosystems, leading to high sediment deposition. Summer GPP rates (4.5–5.1 g C m−2 day−1) were higher than those of most temperate freshwater systems, but GPP rates were reduced by 90% in winter. Macrophytes dominated GPP from May to September with emergent macrophytes accounting for half of the GPP. Periphyton contributed to most of the system GPP throughout the rest of the year. Sediment deposition rates were high and correlated with GPP in one kettle hole. In contrast, due to prolonged periods of anoxia, aerobic sediment mineralisation was low while sediment phosphorus release was significant. Our results suggest that kettle holes have a high potential for carbon burial, provided they do not fully dry up during warm years. Due to their unique features, they should not be automatically grouped with ponds and shallow lakes in global carbon budget estimates.

Published
2017

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