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ARS Home » Southeast Area » Florence, South Carolina » Coastal Plain Soil, Water and Plant Conservation Research » Research » Publications at this Location » Publication #281263

Title: Validity of using backward Lagrangian Stochastic technique in measuring trace gas emission from treatment lagoon

Author
item Ro, Kyoung
item Johnson, Melvin - Mel
item Stone, Kenneth - Ken
item Hunt, Patrick
item Todd, Richard
item FLESCH, T - University Of Alberta

Submitted to: American Society of Agronomy Abstracts
Publication Type: Abstract Only
Publication Acceptance Date: 6/17/2011
Publication Date: 10/16/2011
Citation: Ro, K.S., Johnson, M.H., Stone, K.C., Hunt, P.G., Todd, R.W., Flesch, T. 2011. Validity of using backward Lagrangian Stochastic technique in measuring trace gas emission from treatment lagoon [abstract]. In: Proceedings of the American Society of Agronomy-Crop Science Society of America-Soil Science Society of America Annual Meeting, October 16-19, 2011, San Antonio, Texas.

Interpretive Summary:

Technical Abstract: This study evaluates the accuracy of measuring trace gas emission from treatment lagoons using backward Lagrangian stochastic (bLs) technique. The bLs technique was originally developed for relatively homogeneous terrains without any obstacles causing significant windflow disturbance. The errors associated with using the bLs technique for emission sources with obstacles such as fences or building can be minimized by collecting downwind concentration data far away from the obstacles. Because treatment lagoons in the Southeast region area are usually surrounded by tree lines, it may not be possible to obtain downwind concentration data with enough fetch. Instead, we assume that the microclimate condition within the treatment lagoon boundary can be isolated and its wind turbulence adequately characterized by a 3-dimensional sonic anemometer installed within the treatment lagoons. This assumption allows us to use the bLs technique; however, its accuracy in this type of application is not known at this time. In this study, we compared the emission rate of methane estimated using the WindTrax, a computer based bLs technique, with known mass rates released through a 47-meter by 47-meter floating pipe network on a 65-meter by 65-meter reservoir. Tunable diode laser absorption spectrometers (TDL) were used to collect path integrate concentration (PICs) data. Experimental variables include laser height and location, berm height, and release rate. The experiments are still on-going and the results will be presented at the meeting.