Scientific Communique: Mitigation of Greenhouse Effect by Reduction of the Methane Emissions
Justyna Kujawska
Lublin University of Technology Lublin, Environmental Engineering Faculty, Poland (Poland)
Wojciech Cel
Lublin University of Technology Lublin, Environmental Engineering Faculty, Poland (Poland)
Abstract
Since climate change in the most cases will affect the poorest people of the future generations to mitigate this effect in negative way the sustainable approach it is necessary require to undertake measures. The methods of mitigations which is based on utilization of biological process are the most sustainable.
Keywords:
mitigation of the climate change, methane emissionsReferences
BANURI T., OPSCHOOR H., 2007, Climate change and sustainable development, DESA Working Paper No. 56 ST/ESA/2007/DWP/56.
Google Scholar
BARFORD C.C., 2001, Factors controlling long – and short – term sequestration of atmospheric CO2 in a mid-latitude forest, in: Science, 294, p. 1696.
Google Scholar
BIBLER C., MARSHALL J. S., PILCHER R.C., 2014, Status of worldwide coal mine methane emissions and use, in: International Journal of Coal Geology, vol. 35, no 1-4, p. 283-310.
Google Scholar
BOGNER J., PIPATTI R., HASHIMOTO S., DIAZ C., MMARECKOVA K., DIAZ L., KJELDSEN P., MONNI S., FAAIJ A., GAO Q., ZHANG T., AHMED M.A., SUTAMIHARDJA R.T., GREGORY R., 2008, Mitigation of global greenhouse gas emissions from waste: conclusion and strategies from the Intergovernmental Panel on Climate Change (IPCC) Fourth Assessment Report, in: Waste Management Resource, vol. 26, no. 7, p. 11-32.
Google Scholar
CAO Y., PIECUCH I., 2012, The Role of State in Achieving Sustainable Development in Human Capital, Technology and Environmental Protection, in: Rocznik Ochrona Środowiska/ Annual Set Environment Protection, vol. 14, p. 314-328.
Google Scholar
CHEAH Y.W., SHOWB L.P., CHANG J-S, LINGA C.T., JUAN J.C., 2015, Biosequestration of atmospheric CO2 and flue gas-containing CO2 by microalgae, in: Bioresource Technology, vol. 184, p. 190-201
Google Scholar
CHEFURKA P., 2010, World Energy to 2005 Forty years of decline, http://www.paulchefurka.ca/WEAP2/WEAP2.html (1.04.2016).
Google Scholar
CHOLEWA T., PAWŁOWSKI A., 2009, Sustainable use of energy in the communal sector, in: Rocznik Ochrona Środowiska/Annual Set Environment Protection, vol. 11, no 2, p. 1165-1177.
Google Scholar
EPA, 2010, Global Anthropogenic Emissions of Non-CO2 Greenhouse Gases, EPA Report 430-R-06-003.
Google Scholar
GAWŁOWSKI S., LISTOWSKA-GAWŁOWSKA R., PIECUCH T., 2010, Uwarunkowania i prognoza bezpieczeństwa energetycznego Polski na lata 2010-2110, in: Rocznik Ochrona Środowiska/Annual Set Environment Protection, vol. 12, 127-176.
Google Scholar
GLADWIN T.N., KENNELLY J.J., KRAUSE T.S., 1995, Shifting Paradigms for Sustainable Development: Implications for Management Theory and Research, in: The Academy of Management Review, vol. 20, no 4, p. 874-907.
Google Scholar
GLASBY G., 2002, Sustainable development: the need for a new paradigm, in: Environmental, Development and Sustainability, vol. 4, 10, p. 333-345.
Google Scholar
HOWARTH R.W., INGRAFFEA R.S., 2011, Methane and the greenhouse-gas footprint of natural gas from shale formations, in: Climate Change, vol. 106, p. 679-690.
Google Scholar
HOOIJER A., PAGE S., CANADELL J.G., SILVIUS M., KWADIJK J., WÖSTEN, H., JAUHIAINEN J., 2010), Current and future CO2 emissions from drained peatlands in Southeast Asia, in: Biogeosciences 7, p. 1505-1514, www.biogeosciences.net/7/1505/2010/ doi.:10.5194/bg-7-1505-2010 (1.04.2016).
Google Scholar
HOOIJER A., PAGE S., JAUHIAINEN J., LEE W.A., LU X., IDRIS A., ANSHARI G., 2012, Subsidence and carbon loss in drained tropical peatlands, in: Biogeosciences 9, 1053-1071, http://www.biogeosciences.net/9/1053/2012/ (1.04.2016).
Google Scholar
IPCC, 2007, Fourth Assessment Report: Climate Change 2007. The dual relationship between climate change of sustainable development.
Google Scholar
JOHNSON K., HUYLER M., WESTBERG H., LAMB B., ZIMMERMAN P., 1994, Measurement of methane emissions from ruminant livestock using a SF6 tracer technique, in: Environmental Science Technology, vol. 28, p. 359-362.
Google Scholar
JOHNSON K., JOHNSON E.D., 2010, Methane emissions from cattle, in: Journal of Animal Science, vol. 13, no 8, p. 2483-2492
Google Scholar
KRÜGER P. J., LEIFELD J., GLATZEL S., SZIDAT S., ALEWELL C., 2015, Biogeochemical indicators of peatland degradation – a case study of a temperate bog in northern Germany, in: Biogeosciences 12, p. 2861-2871,
Google Scholar
http://www.biogeosciences.net/12/2861/2015/ (1.04.2016).
Google Scholar
MALLAYA H., 2016, Oil and gas methane emissions mitigation – opportunities and coasts in North America, ICF International, Washington.
Google Scholar
MONTUSIEWICZ A., LEBIOCKA M., PAWŁOWSKA M., 2008, Characterization of the biomethanization process in selected waste mixtures, in: Archives of Environmental Protection, vol. 34, no. 3, p. 49-61.
Google Scholar
OLKIEWICZ M., BOBER B., MAJCHRZAK-ŁEPCZYK J., 2015, Instrumenty zarządzania w ochronie środowiskowej, in: Rocznik Ochrona Środowiska/Annual Set Environment Protection, vol. 17, p. 710-725.
Google Scholar
OREN R., ELLSWORTH S.D., JOHNSEN H. K., PHILLIPS N., EWERS E.B., MAIER C., SCHÄFER V.R.K., McCARTHY H., HENDREY G., McNULTY G.S., KATUL G.G., 2001, Soil fertility limits carbon sequestration by forest ecosystems in a CO2-enriched atmosphere, in: Nature, vol. 411, p. 469-472.
Google Scholar
PAWŁOWSKI A., 2008, How many dimensions does sustainable development have?, in: Sustainable Development vol. 16 no 2, p. 71-72.
Google Scholar
PAWŁOWSKI A., 2009, Theoretical aspects of sustainable development concept, in: Rocznik Ochrona Środowiska/ Annual Set Environment Protection, vol. 11, no 2, p. 985-994.
Google Scholar
SMITH P., MARTINO D., CAI Z., GWARY D., JANZEN H., KUMAR P., McCARL B., OGLE S., O'MARA F., RICE C., SCHOLES B., SIROTENKO O., HOWDEN M., McALLISTER T., PAN G., ROMANENKOV V., SCHNEIDER U., TOWPRAYOON S., WATTENBACH M., SMITH J., 2007, Greenhouse gas mitigation in agriculture, in: Philosophical Transactions B, The Royal Society Publishing, vol. 363, no 1492, p. 789-813.
Google Scholar
STASZEWSKA E., PAWŁOWSKA M., 2011, Characteristics of emissions from municipal waste landfill, in: Environmental Protection Engineering, vol. 37, no. 4, p. 119-130.
Google Scholar
STĘPNIEWSKI W., PAWŁOWSKA M., 1996, A possibility to reduce methane emission from landfills by its oxidation in the soil cover, in: Chemistry for the Protection of the Environment 2, Environmental Science Research, vol. 51, Plenum Press, New York, 75-92
Google Scholar
YOHE G.W., LASCO R.D., AHMAD Q.K., ARNELL N.W., COHEN S.J., HOPE C., JANETOS A.C., PEREZ R.T., 2007, Perspectives on climate change and sustainability, Climate change 2007: Impacts, adaption and vulnerability, in: Contribution of working group II to the fourth assessment report of the intergovernmental panel on climate change, eds. Parry M.L., Canziani O.F., Palutikof J.P., van der Lindeken P.J., Hanson C.E., Cambridge University Press, Cambridge, p. 811-841.
Google Scholar
Authors
Justyna KujawskaLublin University of Technology Lublin, Environmental Engineering Faculty, Poland Poland
Authors
Wojciech CelLublin University of Technology Lublin, Environmental Engineering Faculty, Poland Poland
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