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Variations of methane emissions within and between three hydroelectric reservoirs in Brazil / Variationen av metanemissioner inom och mellan tre hydroelektriska vattendammarGrandin, Karin January 2012 (has links)
Hydroelectricity is an energy resource which for a long time has been consideredenvironmentally neutral regarding greenhouse gas emission. During the last years this viewhas changed. Studies have shown that reservoirs connected to hydroelectric power plants emitmethane (CH4) and other greenhouse gases to the atmosphere, especially in the tropicalregions where the emission level of CH4 is the highest. The purpose of this thesis was toinvestigate the variations of CH4 emissions in Funil reservoir, Santo Antônio reservoir andTrês Marias reservoir and to identify variables that increase the CH4 emissions.The CH4 emissions were measured by floating static chambers positioned on the surface atseveral locations within each reservoir. A gas sample was collected after 10, 20 and 30minutes from each chamber. The samples were analyzed through gas chromatography toobtain the concentration of CH4 in each sample. Calculations of the change in CH4concentration over time were used to establish the flux of CH4 at each location.The obtained result from Funil reservoir showed CH4 fluxes in the range of -0.04 to 13.16mmol/m2/day with significantly different fluxes between sites (p < 0.05). The CH4 fluxes inSanto Antonio reservoir were within the range of -0.33 to 72.21 mmol/m2/day. In thisreservoir fluxes were not significantly different between sites (p <0.05). The results obtainedfrom Três Marias showed CH4 fluxes in the range of -0.31 to 0.56 mmol/m2/day withsignificantly different fluxes between sites (p < 0.05). The highest fluxes were found in SantoAntônio which were significantly different from the CH4 fluxes in Três Marias (p <0.05).The CH4 flux was positively correlated with CO2 and dissolved organic carbon (DOC) andnegatively correlated with O2 and depth in Santo Antônio. The same correlations were evidentfor the whole data set. In total the measured fluxes from the three reservoirs ranged from -0.33 to 72. 21 mmol/m2/day and the mean flux was 2.31 mmol/m2/day. These fluxes are lowcompared to earlier results. The variation in CH4 flux within and between the reservoirs wassignificantly different in a major part of the comparisons. Even though the majority of thefluxes were different, variables that increase the CH4 emission rate were illuminated. A lowdepth and low O2 concentration increase the CH4 emission rate. A high concentration of DOCand CO2 indicates that a high amount of organic carbon was available for the production ofCH4, leading to an increased CH4 emission rate. / BALCAR (Balanço de Carbono)
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Impact of Phosphorus and Trace Elements on Methane Oxidation in LakesLundqvist, Lexa, Unnerfelt, Saga January 2024 (has links)
Methane (CH4) is a potent greenhouse gas contributing to the warming of Earth's atmosphere. Lakes are a natural source of CH4, where CH4 generally is produced in oxygen depleted sediments. Ebullitive CH4 is regulated naturally in the oxic-anoxic interface of lakes by methane oxidizing bacteria, methanotrophs uses CH4 as a substrate when O2 is present. Lakes in boreal regions are among the largest sources of CH4 emissions, CH4 oxidation can mitigate some of the CH4 emissions from lakes. Gaps in knowledge and data remain regarding net fluxes of CH4, indicating that there are processes unaccounted for. Previous research highlights the variability of CH4 emissions and oxidations rates in lakes, there is lacking knowledge on what drives the variability of oxidation rates and total emissions. It’s been suggested that availability of phosphorus (P) has a positive relationship with increased oxidation rates. Moreover, availability of trace elements has been suggested to affect aerobic CH4 oxidation, but there is a lack of knowledge on these factors in natural lake waters. In this study incubations with lake water from two different lakes, Gårasjön and Kisasjön, were prepared with different treatments of P and/or trace elements. We investigate how this can affect the rate of CH4 oxidation when incubated in specific conditions. Our results indicate that treatments with added P had a greater tendency to exhibit higher rates of methane oxidation in both lakes, while treatments with trace elements and P had varied oxidation rates depending on the lake. This suggests that when there are no limitations of the substrates CH4 and O2, the oxidations rates in lakes might be limited by the availability of P and the specific lake conditions can influence CH4 oxidation.
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Trace gas fluxes from soils and tree stems of rainforests and cacao agroforests in the Congo Basin, CameroonIddris, Najeeb Al-Amin 26 May 2020 (has links)
No description available.
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Short-Time Temporal Changes of CH4 Fluxes in Different Tropical Tree Species : In-situ research regarding methane emissions from inundation-adapted Amazonian tree species in Jardim Botânico do Rio de Janeiro.Athley, Emelie January 2023 (has links)
Methane (CH4) is guaranteed to affect climate change and is essential in rising temperatures. Scientists have known for over two decades that wetlands emit CH4 to such an extent that it affects our climate. Tropical trees that grow in wetlands tend to emit or act as a conduit of CH4, to the extent that it has a negative environmental impact. However, until this study, no one has examined whether wetland species growing in another environment have the same effects. Hence, this thesis aimed to collect data from wetland-adapted tropical trees in a non-wetland environment, namely the Botanical Garden in Rio de Janeiro. The results showed a difference in the sampling height of the stem, namely that a decrease in emission is seen with an increased height. All the species except one (Pseudobombax munguba) showed both assimilation and emission from the day-to-day measurements of CH4, which speaks for the trees acting both as a sink and a source of CH4. This suggests that the species are more robust than the environmental stressors in a non-wetland environment. Previous studies have found that increased CH4 emissions can be seen with different meteorological parameters. The results presented in this thesis show the opposite, that some species tend to emit less or assimilate more CH4 during days with increased rainfall, humidity, and temperature.
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