14 results on '"Fisher, R.E."'
Search Results
2. Methane emissions in Kuwait: Plume identification, isotopic characterisation and inventory verification
- Author
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Al-Shalan, A., Lowry, D., Fisher, R.E., Nisbet, E.G., Zazzeri, G., Al-Sarawi, M., and France, J.L.
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- 2022
- Full Text
- View/download PDF
Catalog
3. Observations of molecular hydrogen mixing ratio and stable isotopic composition at the Cabauw tall tower in the Netherlands
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Batenburg, A.M., Popa, M.E., Vermeulen, A.T., van den Bulk, W.C.M., Jongejan, P.A.C., Fisher, R.E., Lowry, D., Nisbet, E.G., and Röckmann, T.
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- 2016
- Full Text
- View/download PDF
4. Plume mapping and isotopic characterisation of anthropogenic methane sources
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Zazzeri, G., Lowry, D., Fisher, R.E., France, J.L., Lanoisellé, M., and Nisbet, E.G.
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- 2015
- Full Text
- View/download PDF
5. Is the destruction or removal of atmospheric methane a worthwhile option?
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Nisbet-Jones, P.B.R., Fernandez, J.M., Fisher, R.E., France, J.L., Lowry, D., Waltham, D.A., Woolley Maisch, C.A., Nisbet, E.G., Nisbet-Jones, P.B.R., Fernandez, J.M., Fisher, R.E., France, J.L., Lowry, D., Waltham, D.A., Woolley Maisch, C.A., and Nisbet, E.G. more...
- Abstract
Removing methane from the air is possible, but do the costs outweigh the benefits? This note explores the question of whether removing methane from the atmosphere is justifiable. Destruction of methane by oxidation to CO2 eliminates 97% of the warming impact on a 100-yr time scale. Methane can be oxidized by a variety of methods including thermal or ultraviolet photocatalysis and various processes of physical, chemical or biological oxidizers. Each removal method has energy costs (with the risk of causing embedded CO2 emission that cancel the global warming gain), but in specific circumstances, including settings where air with high methane is habitually present, removal may be competitive with direct efforts to cut fugitive methane leaks. In all cases however, great care must be taken to ensure that the destruction has a net positive impact on the total global warming, and that the resources required would not be better used for stopping the methane from being emitted. more...
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- 2022
6. Airborne quantification of net methane and carbon dioxide fluxes from European Arctic wetlands in Summer 2019
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Barker, P.A., Allen, G., Pitt, J.R., Bauguitte, S.J.-B., Pasternak, D., Cliff, S., France, J.L., Fisher, R.E., Lee, J.D., Bowler, K.N., Nisbet, E.G., Barker, P.A., Allen, G., Pitt, J.R., Bauguitte, S.J.-B., Pasternak, D., Cliff, S., France, J.L., Fisher, R.E., Lee, J.D., Bowler, K.N., and Nisbet, E.G. more...
- Abstract
Arctic wetlands and surrounding ecosystems are both a significant source of methane (CH4) and a sink of carbon dioxide (CO2) during summer months. However, precise quantification of this regional CH4 source and CO2 sink remains poorly characterized. A research flight using the UK Facility for Airborne Atmospheric Measurement was conducted in July 2019 over an area (approx. 78 000 km2) of mixed peatland and forest in northern Sweden and Finland. Area-averaged fluxes of CH4 and carbon dioxide were calculated using an aircraft mass balance approach. Net CH4 fluxes normalized to wetland area ranged between 5.93 ± 1.87 mg m−2 h−1 and 4.44 ± 0.64 mg m−2 h−1 (largest to smallest) over the region with a meridional gradient across three discrete areas enclosed by the flight survey. From largest to smallest, net CO2 sinks ranged between −513 ± 74 mg m−2 h−1 and −284 ± 89 mg m−2 h−1 and result from net uptake of CO2 by vegetation and soils in the biosphere. A clear gradient of decreasing bulk and area-averaged CH4 flux was identified from north to south across the study region, correlated with decreasing peat bog land area from north to south identified from CORINE land cover classifications. While N2O mole fraction was measured, no discernible gradient was measured over the flight track, but a minimum flux threshold using this mass balance method was calculated. Bulk (total area) CH4 fluxes determined via mass balance were compared with area-weighted upscaled chamber fluxes from the same study area and were found to agree well within measurement uncertainty. The mass balance CH4 fluxes were found to be significantly higher than the CH4 fluxes reported by many land-surface process models compiled as part of the Global Carbon Project. There was high variability in both flux distribution and magnitude between the individual models. This further supports previous studies that suggest that land-surface models are currently ill-equipped to accurately capture carbon fluxes inthe reg more...
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- 2022
7. Identification of potential methane source regions in Europe using δ13 CCH4 measurements and trajectory modeling
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Varga, T., Fisher, R.E., France, J.L., Haszpra, L., Jull, A.J.T., Lowry, D., Major, I., Molnár, M., Nisbet, E. G., László, E., Varga, T., Fisher, R.E., France, J.L., Haszpra, L., Jull, A.J.T., Lowry, D., Major, I., Molnár, M., Nisbet, E. G., and László, E. more...
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The methane emissions from the Hungarian Pannonian Basin are not well qualified, due to a lack of measurements of CH4 mole fraction and δ13CCH4 in the air. This study reports methane measurements in air samples from Hungary, placing them in the context of regional and global background data, to investigate the inputs to the methane burden in Central Europe. CH4 mole fraction and δ13CCH4 from the Hungarian tall tower station, Hegyhátsál, and additional data from Mace Head (Ireland) and Zeppelin (Svalbard) are used with back-trajectory modeling to identify central European source areas and their seasonal variation between the summer vegetation and winter heating periods. Methane measurements in air masses sampled in the European interior, have significantly higher maxima and seasonal amplitudes than at the Mace Head and Zeppelin European background sites. The mean CH4 mole fraction value is about 80 ppb higher than the comparable marine background, and values above 2000 ppb were frequently observed between February 2013 and December 2015. The mean δ13CCH4 value -47.5±0.3 ‰ (2σ) was comparable to values at all three monitoring sites, but specific pollution events were detected at Hegyhátsál. Concentration weighted trajectory modeling, meteorological parameters, stable carbon isotopic composition (δ13CCH4), and Miller-Tans analysis show that the main factors influencing CH4 at the Hegyhátsál, apart from diurnal and seasonal changes in the Planetary Boundary Layer, are emissions from residential heating and industrial CH4 emissions during the winter. more...
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- 2021
8. Carbon isotopic characterisation and oxidation of UK landfill methane emissions by atmospheric measurements
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Bakkaloglu, S., Lowry, D., Fisher, R.E., France, J.L., Nisbet, E.G., Bakkaloglu, S., Lowry, D., Fisher, R.E., France, J.L., and Nisbet, E.G.
- Abstract
Biological oxidation of methane in landfill cover material can be calculated from the carbon isotopic signature (δ13CCH4) of emitted CH4. Enhanced microbial consumption of methane in the aerobic portion of the landfill cover is indicated by a shift to heavier (less depleted) isotopic values in the residual methane emitted to air. This study was conducted at four landfill sites in southwest England. Measurement of CH4 using a mobile vehicle mounted instrument at the four sites was coupled with Flexfoil bag sampling of ambient air for high-precision isotope analysis. Gas well collection systems were sampled to estimate landfill oxidised proportion. Closed or active status, seasonal variation, cap stripping and site closure impact on landfill isotopic signature were also assessed. The δ13CCH4 values ranged from −60 to −54‰, with an average value of −57 ± 2‰. Methane emissions from active cells are more depleted in 13C than closed sites. Methane oxidation, estimated from the isotope fractionation, ranged from 2.6 to 38.2%, with mean values of 9.5% for active and 16.2% for closed landfills, indicating that oxidised proportion is highly site specific. more...
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- 2021
9. Quantification of methane emissions from UK biogas plants
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Bakkaloglu, S., Lowry, D., Fisher, R.E., France, J.L., Brunner, D., Chen, H., Nisbet, E.G., Bakkaloglu, S., Lowry, D., Fisher, R.E., France, J.L., Brunner, D., Chen, H., and Nisbet, E.G.
- Abstract
The rising number of operational biogas plants in the UK brings a new emissions category to consider for methane monitoring, quantification and reduction. Minimising methane losses from biogas plants to the atmosphere is critical not only because of their contribution of methane to global warming but also with respect to the sustainability of renewable energy production. Mobile greenhouse gas surveys were conducted to detect plumes of methane emissions from the biogas plants in southern England that varied in their size, waste feed input materials and biogas utilization. Gaussian plume modelling was used to estimate total emissions of methane from ten biogas plants based on repeat passes through the plumes. Methane emission rates ranged from 0.1 to 58.7 kg CH4 hr-1, and the percentage of losses relative to the calculated production rate varied between 0.02 and 8.1%. The average emission rate was 15.9 kg CH4 hr-1, and the average loss was 3.7%. In general, methane emission rates from smaller farm biogas plants were higher than from larger food waste biogas plants. We also suggest that biogas methane emissions may account for between 0.4 and 3.8%, with an average being 1.9% of the total methane emissions in the UK excluding the sewage sludge biogas plants. more...
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- 2021
10. Recommendations for environmental baseline monitoring in areas of shale gas development
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Ward, R.S., Rivett, M.O., Smedley, P.L., Allen, G., Lewis, A., Purvis, R.M., Jordan, C.J., Taylor-Curran, H., Daraktchieva, Z., Baptie, B.J., Horleston, A., Bateson, L., Novellino, A., Lowry, D., Fisher, R.E., Ward, R.S., Rivett, M.O., Smedley, P.L., Allen, G., Lewis, A., Purvis, R.M., Jordan, C.J., Taylor-Curran, H., Daraktchieva, Z., Baptie, B.J., Horleston, A., Bateson, L., Novellino, A., Lowry, D., and Fisher, R.E. more...
- Abstract
Environmental monitoring plays a key role in risk assessment and management of industrial operations where there is the potential for the release of contaminants to the environment (i.e. air and water) or for structural damage (i.e. seismicity). The shale-gas industry is one such industry. It is also new to the UK and so specific environmental regulation and other controls have been introduced only recently. Associated with this is a need to carry out monitoring to demonstrate that the management measures to minimise the risk to the environment are being effective. While much of the monitoring required is common to other industries and potentially polluting activities, there are a number of requirements specific to shale gas and to what is a new and undeveloped industry. This report presents recommendations for environmental monitoring associated with shale-gas activities and in particular the monitoring required to inform risk assessment and establish the pre-existing environmental conditions at a site and surrounding area. This baseline monitoring is essential to provide robust data and criteria for detecting any future adverse environmental changes caused by the shale-gas operations. Monitoring is therefore required throughout the lifecycle of a shale gas operation. During this lifecycle, the objectives of the monitoring will change, from baseline characterisation to operational and post-operational monitoring. Monitoring requirements will also change. This report focusses on good practice in baseline monitoring and places it in the context of the longer-term environmental monitoring programme, recognising the need to transition from the baseline condition and to establish criteria for detecting any changes within the regulatory framework. The core suite of environmental monitoring activities currently required to support regulatory compliance, i.e. meet environmental and other permit conditions, encompasses monitoring of seismicity, water quality (groundwater an more...
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- 2020
11. Preliminary assessment of the environmental baseline in the Fylde, Lancashire
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Ward, R.S., Allen, G., Baptie, B.J., Bateson, L., Bell, R.A., Butcher, A.S., Daraktchieva, Z., Dunmore, R., Fisher, R.E., Horleston, A., Howarth, C.H., Jones, D.G., Jordan, C.J., Kendall, M., Lewis, A., Lowry, D., Miller, C.A., Milne, C.J., Novellino, A., Pitt, J., Purvis, R.M., Smedley, P.L., Wasikiewicz, J.M., Ward, R.S., Allen, G., Baptie, B.J., Bateson, L., Bell, R.A., Butcher, A.S., Daraktchieva, Z., Dunmore, R., Fisher, R.E., Horleston, A., Howarth, C.H., Jones, D.G., Jordan, C.J., Kendall, M., Lewis, A., Lowry, D., Miller, C.A., Milne, C.J., Novellino, A., Pitt, J., Purvis, R.M., Smedley, P.L., and Wasikiewicz, J.M. more...
- Abstract
This report presents the collated preliminary results from the British Geological Survey (BGS) led project Science-based environmental baseline monitoring associated with shale gas development in the Fylde, Lancashire. The project has been funded by a combination of BGS National Capability funding, in-kind contributions from project partners and a grant awarded by the Department of Business Energy and Investment Strategy (BEIS). It complements an on-going project, in which similar activities are being carried out, in the Vale of Pickering, North Yorkshire. Further information on the projects can be found on the BGS website: www.bgs.ac.uk. The project has initiated a wide-ranging environmental baseline monitoring programme that includes water quality (groundwater and surface water), seismicity, ground motion, atmospheric composition (greenhouse gases and air quality), soil gas and radon in air (indoors and outdoors). The motivation behind the project(s) was to establish independent monitoring in the area around the proposed shale gas hydraulic fracturing sites in the Fylde, Lancashire (Cuadrilla Resources Ltd) before any shale gas operations take place. As part of the project, instrumentation has been deployed to measure, in real-time or near real-time, a range of environmental variables (water quality, seismicity, atmospheric composition). These data are being displayed on the project’s web site (www.bgs.ac.uk/lancashire). Additional survey, sampling and monitoring has also been carried out through a co-ordinated programme of fieldwork and laboratory analysis, which has included installation of new monitoring infrastructure, to allow compilation of one of the most comprehensive environmental datasets in the UK. The monitoring programme is continuing. However, there are already some very important findings emerging from the limited datasets which should be taken into account when developing future monitoring strategy, policy and regulation. The information is not onl more...
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- 2018
12. Measurements of δ13C in CH4 and using particle dispersion modeling to characterize sources of Arctic methane within an air mass
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France, J.L., Cain, M., Fisher, R.E., Lowry, D., Allen, G., O'Shea, S.J., Illingworth, S., Pyle, J., Warwick, N., Jones, B.T., Gallagher, M.W., Bower, K., Le Breton, M., Percival, C., Muller, J., Welpott, A., Bauguitte, S., George, C., Hayman, G.D., Manning, A.J., Myhre, C. Lund, Lanoisellé, M., Nisbet, E.G., France, J.L., Cain, M., Fisher, R.E., Lowry, D., Allen, G., O'Shea, S.J., Illingworth, S., Pyle, J., Warwick, N., Jones, B.T., Gallagher, M.W., Bower, K., Le Breton, M., Percival, C., Muller, J., Welpott, A., Bauguitte, S., George, C., Hayman, G.D., Manning, A.J., Myhre, C. Lund, Lanoisellé, M., and Nisbet, E.G. more...
- Abstract
A stratified air mass enriched in methane (CH4) was sampled at ~600 m to ~2000 m altitude, between the north coast of Norway and Svalbard as part of the Methane in the Arctic: Measurements and Modelling campaign on board the UK's BAe-146-301 Atmospheric Research Aircraft. The approach used here, which combines interpretation of multiple tracers with transport modeling, enables better understanding of the emission sources that contribute to the background mixing ratios of CH4 in the Arctic. Importantly, it allows constraints to be placed on the location and isotopic bulk signature of the emission source(s). Measurements of δ13C in CH4 in whole air samples taken while traversing the air mass identified that the source(s) had a strongly depleted bulk δ13C CH4 isotopic signature of −70 (±2.1)‰. Combined Numerical Atmospheric-dispersion Modeling Environment and inventory analysis indicates that the air mass was recently in the planetary boundary layer over northwest Russia and the Barents Sea, with the likely dominant source of methane being from wetlands in that region. more...
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- 2016
13. Observations of molecular hydrogen mixing ratio and stable isotopic composition at the Cabauw tall tower in the Netherlands
- Author
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Sub Atmospheric physics and chemistry, Afd Marine and Atmospheric Research, Marine and Atmospheric Research, Batenburg, A.m., Popa, M.e., Vermeulen, A.t., Van Den Bulk, W.c.m., Jongejan, P.a.c., Fisher, R.e., Lowry, D., Nisbet, E.g., Röckmann, T., Sub Atmospheric physics and chemistry, Afd Marine and Atmospheric Research, Marine and Atmospheric Research, Batenburg, A.m., Popa, M.e., Vermeulen, A.t., Van Den Bulk, W.c.m., Jongejan, P.a.c., Fisher, R.e., Lowry, D., Nisbet, E.g., and Röckmann, T. more...
- Published
- 2016
14. Evaluation of the boundary layer dynamics of the TM5 model over Europe
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Koffi, E.N., Bergamaschi, P., Karstens, U., Krol, M., Segers, A., Schmidt, M., Levin, I., Vermeulen, A.T., Fisher, R.E., Kazan, V., Klein Baltink, H., Lowry, D., Manca, G., Meijer, H.A.J., Moncrieff, J., Pal, S., Ramonet, M., Scheeren, H.A., Williams, A.G., Koffi, E.N., Bergamaschi, P., Karstens, U., Krol, M., Segers, A., Schmidt, M., Levin, I., Vermeulen, A.T., Fisher, R.E., Kazan, V., Klein Baltink, H., Lowry, D., Manca, G., Meijer, H.A.J., Moncrieff, J., Pal, S., Ramonet, M., Scheeren, H.A., and Williams, A.G. more...
- Abstract
We evaluate the capability of the global atmospheric transport model TM5 to simulate the boundary layer dynamics and associated variability of trace gases close to the surface, using radon (222Rn). Focusing on the European scale, we compare the boundary layer height (BLH) in the TM5 model with observations from the National Oceanic and Atmospheric Admnistration (NOAA) Integrated Global Radiosonde Archive (IGRA) and also with ceilometer and lidar (light detection and ranging) BLH retrievals at two stations. Furthermore, we compare TM5 simulations of 222Rn activity concentrations, using a novel, process-based 222Rn flux map over Europe (Karstens et al., 2015), with harmonised 222Rn measurements at 10 stations. The TM5 model reproduces relatively well the daytime BLH (within 10-20% for most of the stations), except for coastal sites, for which differences are usually larger due to model representation errors. During night, however, TM5 overestimates the shallow nocturnal BLHs, especially for the very low observed BLHs (<100m) during summer. The 222Rn activity concentration simulations based on the new 222Rn flux map show significant improvements especially regarding the average seasonal variability, compared to simulations using constant 222Rn fluxes. Nevertheless, the (relative) differences between simulated and observed daytime minimum 222Rn activity concentrations are larger for several stations (on the order of 50%) than the (relative) differences between simulated and observed BLH at noon. Although the nocturnal BLH is often higher in the model than observed, simulated 222Rn nighttime maxima are actually larger at several continental stations. This counterintuitive behaviour points to potential deficiencies of TM5 to correctly simulate the vertical gradients within the nocturnal boundary layer, limitations of the 222Rn flux map, or issues related to the definition of the nocturnal BLH. At several stations the simulated decrease of 222Rn activity concentrations in more...
- Published
- 2016
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