Open AccessAmmonia and hydrogen sulphide flux and dry deposition velocity estimates using vertical gradient method at a commercial beef cattle feedlot
Author(s) -
Bok H. Baek,
Richard W. Todd,
N. A. Cole,
Jacek A. Koziel
Publication year - 2006
Publication title -
international journal of global environmental issues
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.16
H-Index - 22
eISSN - 1741-5136
pISSN - 1466-6650
DOI - 10.1504/ijgenvi.2006.010154
Subject(s) - daytime , flux (metallurgy) , ammonia , beef cattle , deposition (geology) , temperature gradient , diurnal temperature variation , evaporation , hydrogen sulfide , atmospheric sciences , chemistry , feedlot , hydrogen , zoology , environmental science , meteorology , sulfur , geology , paleontology , physics , organic chemistry , sediment , biology
Ammonia and hydrogen sulphide flux and dry deposition velocity were estimated using micrometeorological vertical gradient flux method at a commercial cattle feedyard of approximately 50,000 head of beef cattle and average 14.4 m²/head (150 ft²/head) stocking density. Ammonia-N and H2S-S loss had general diurnal patterns with the highest fluxes in daytime and lowest fluxes in nighttime that correlated to temperature changes and active evaporation process during daytime. The highest average deposition velocities also occurred during daytime with unstable atmospheric conditions and the lowest during nighttime with very stable conditions. There are exponential relationship between NH3-N flux and ambient temperature with R² = 0.57 for NH3 (NH3-N flux = – 1.46 + 7.96e0.077*Temperature) and R² = 0.22 for H2S-S (H2S-S flux = – 0.75 + 0.8e-0.013*Temperature).
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