@article{MTMT:2497627,
	title = {Biogas utilization and its environmental benefits in Hungary},
	url = {https://m2.mtmt.hu/api/publication/2497627},
	author = {Fazekas, István and Szabó, György Emőd and Szabó, Szilárd and Paládi, Mónika and Szabó, Gergely and Buday, Tamás and Túri, Zoltán and Kerényi, Attila},
	doi = {10.1556/IRASE.4.2013.2.6},
	journal-iso = {INT REV APPL SCI ENG},
	journal = {INTERNATIONAL REVIEW OF APPLIED SCIENCES AND ENGINEERING},
	volume = {4},
	unique-id = {2497627},
	issn = {2062-0810},
	abstract = {The aim of our report is to refer on the actual state of small biogas power plants in Hungary summarising the increase in their number and capacity and their effects on climatic change. The above is based on the CO 2 emission of the energetic utilization of biogas and the calculation of its ecological footprint that were compared to the environmental effects of natural gas energetic utilization. The aim of this paper does not include the complete life cycle analysis therefore the environmental benefits of the energetic utilization of biogas produced from various raw material are presented via only the direct CO 2 emission of the production process.},
	year = {2013},
	eissn = {2063-4269},
	pages = {129-135},
	orcid-numbers = {Fazekas, István/0000-0001-7973-9454; Szabó, Szilárd/0000-0002-2670-7384}
}

@article{MTMT:1406277,
	title = {Estimation of nitrous oxide emission from Hungarian semi-arid sandy and loess grasslands; effect of soil parameters, grazing, irrigation and use of fertilizer},
	url = {https://m2.mtmt.hu/api/publication/1406277},
	author = {Horváth, László and Grosz, Balázs Péter and Machon, Attila and Tuba, Zoltán and Nagy, Zoltán and Czóbel, Szilárd and Balogh, János and Péli, Evelin Ramóna and Fóti, Szilvia and Weidinger, Tamás and Pintér, Krisztina and Führer, Ernő},
	doi = {10.1016/j.agee.2010.08.011},
	journal-iso = {AGR ECOSYST ENVIRON},
	journal = {AGRICULTURE ECOSYSTEMS & ENVIRONMENT},
	volume = {139},
	unique-id = {1406277},
	issn = {0167-8809},
	abstract = {Nitrous oxide (N2O) is emitted into the atmosphere in substantial quantities as an intermediate product of mainly denitrification processes and soil nitrification. N2O emission from Hungarian sandy and loess type soils has been measured between August 2002 and December 2004. The effects of soil parameters and different farming activities (grazing exclusion, irrigation and mineral fertilization) on the rate of emission were investigated. Soil N2O efflux was determined by measuring the accumulation of N2O in 10 parallel small (V = 400 cm3, A = 80 cm2) static chambers. Samples were taken with evacuated tubes followed by gas chromatography–mass spectrometry analysis. Emission from sandy grassland under extensive farming proved to be negligible below soil temperature of 5 °C, the mean fluxes at tsoil > 10 °C and tsoil < 10 °C were differing significantly (15.4 and 1.7 μg N m−2 h−1, respectively). N2O efflux was linked to temperatures up to tsoil = 20 °C, while at higher soil temperatures a decrease of efflux was observed. The optimum soil wetness (WFPS, water-filled pore space) for N2O production was between 40 and 50% for this sandy soil. The annual sum of efflux for control plots in dry (2003) and wet (2004) years was almost the same (0.80 and 0.74 kg N ha−1 yr−1, respectively), probably due to the fact that in dry year soil wetness is lower than the optimum, and vice versa, in a wet year the high WFPS did not favoured N2O production. Grazing (50–80 cows per km2) enhanced emission by 4–18% in dry and wet years, respectively. Around 6% of total atmospheric deposition (13.8 kg N ha−1 yr−1) was transformed into N2O and emitted into the atmosphere from the sandy soil. A two-year fertilization experiment above loess soil (August 2002–July 2004, with regular precipitation amount during the period) resulted in an emission factor of 0.26% as a consequence of applying 100 kg N ha−1 yr−1 ammonium nitrate mineral fertilizer in April, each year. Average fluxes were 1.13 and 0.90 kg N ha−1 yr−1 above fertilized and control plots, respectively. Monoliths from loess soil were used to study the effect of irrigation on N2O fluxes. In contrast to sandy soil there were detectable soil fluxes below 5 °C. N2O production increases with soil temperature until 15–20 °C above which lower emissions were detected. The optimum wetness for N2O production in loess soil was around 30–40 WFPS but above 70–80% (up to saturation) other, yet unexplained maximum was observed. Irrigation enhanced the soil flux by 70% in the dry year (2003), when measured fluxes were 1.56 and 0.92 kg N ha−1 yr−1 on irrigated and control plots, respectively.
		
		Research highlights
		▶ The optimum soil wetness for N2O production was between 40 and 50% for sandy soil. ▶ N2O flux for sandy soil in dry and wet years were 0.80 and 0.74 kg N ha−1 yr−1. ▶ Grazing (sandy soil, 50–80 cows/km2) enhanced emission by 4–18% in dry–wet years. ▶ Above loess soil 100 kg N ha−1 yr−1 fertilizer results in emission factor of 0.26%. ▶ Irrigation of loess soil enhanced the soil N2O flux by 70% in dry year.},
	year = {2010},
	eissn = {1873-2305},
	pages = {255-263},
	orcid-numbers = {Grosz, Balázs Péter/0000-0003-4138-4840; Machon, Attila/0000-0001-7941-0253; Nagy, Zoltán/0000-0003-2839-522X; Balogh, János/0000-0003-3211-5120; Péli, Evelin Ramóna/0000-0003-4211-5108; Weidinger, Tamás/0000-0001-7500-6579}
}