In the studies of fate and transport of air emissions from animal feeding operations, Gaussian based dispersion models have been commonly used to predict downwind pollutant concentrations through forward modeling approach, or to derive emission rates and emission factors through inverse dispersion modeling approach. In the Gaussian dispersion modeling process, downwind sampling location and sampling height could generate significant impact on accuracy of the model validation, or inverse modeling results based upon field measurements. This study theoretically analyzed the impact of downwind locations and sampling height on Gaussian dispersion modeling. It was discovered that the field sampling needs to be conducted at the locations beyond the plume touching-ground distance, at a downwind distance as short as 5 m for the case scenario with zero rise of emission plume under the atmospheric stability class C, or as long as 297 m for the case scenario with 15 m rise of emission plume under the atmospheric stability class F. In order to measure the PM concentrations of the dispersion plume, the minimum sampling height at the locations within the plume touching-ground distance varied from ground level to as high as almost 14 m, whereas for the locations beyond the plume touching-ground distance, a sampling height of ground level would be acceptable.

animal feeding operations, Gaussian dispersion modeling, downwind distance, downwind sampling location, downwind sampling height

EPA. Ohio’s largest egg producer agrees to dramatic air pollution reductions from three giant facilities. Environmental Protection Agency. Release date: Feb. 23, 2014. Available at http://yosemite.epa.gov/opa/admpress.nsf/ b1ab9f485b098972852562e7004dc686/508199b8068c24a585256e43007e1230!OpenDocument.

EPA. Air Quality Compliance Agreement for Animal Feeding Operations. 2005. Available at http://www.epa.gov/ compliance/resources/agreements/caa/cafo-agr-0501.html. Access on July 14, 2011.

National Research Council. Air emissions from animal feeding operations: Current knowledge, future needs. The National Academies Press, Washington DC, 2003.

O’Shaughnessy P T, Altmaier R. Use of AERMOD to determine a hydrogen sulfide emission factor for swine operations by inverse modeling. Atmospheric Enviornment, 2011; 45(27): 4617-4625.

Hoff S J, Bundy D S, Harmon J D. Modeling receptor odor exposure from swine production sources using CAM. Applied Engineering in Agriculture, 2008; 24: 821-837.

Guo H, Jacobson L D, Schmidt D R, Nicolai R E, Janni K A. Comparison of five models for setback distance determination from livestock sites. Canadian Biosystems Engineering, 2004; 46: 6.17-6.25.

Flesch T K, Harper L A, Powell J M, Wilson J D. Inverse dispersion calculation of ammonia emissions from Wisconsin dairy farms. Transactions of the ASABE, 2009; 52: 253-265.

Hensen A, Loubet B, Mosquera J, van den Bulk W C M, Erisman J W, Dämmgen U, et al. Estimation of NH3 emissions from a naturally ventilated livestock farm using local-scale atmospheric dispersion modeling. Biogeosciences Discussions, 2009; 6: 2847-2860.

Faulkner W B, Lange J M, Powell J J, Shaw B W, Parnell C B. Sampler placement to determine emission factors from ground level area sources. Paper No. 074103, 2007 ASABE annual international meeting. Minneapolis, Minnesota, June 17-20, 2007.

Cooper C D, Alley F C. Air pollution control: A design approach. Waveland Press, Prospect Heights, III. 2002.