Micromet Methods for Determining Fluxes of Nitrogen Species Tilden P. Meyers NOAA/ARL Atmospheric Turbulence and Diffusion Division Oak Ridge, TN
Presentation Objectives Discuss various methodologies to measure NH 3 exchange Highlight specific sampling considerations and guidelines for each method Present results from various field experiments
All micrometeorological methods are constrained by: 1. Fluxes don't vary in X,Y plane in the flux “footprint” 2. The exchange at the surface is same as that at sensor height
For NH 3, we often are interested in characterizing deposition as well as emission Emission sources of NH 3 generally are characterized by small areas that have spatial scales less than a typical flux footprint (swine lagoons, poultry farms, etc.) Deposition targets are vegetation (grasslands, forests, crops, soil) that can have considerable spatial extent, but are often located in areas that have small NH 3 concentrations
For characterizing NH 3 emissions Integrated Mass Balance Average emission rate = what is advected past tower
Flux = Similarly, inverse Lagrangian methods have been used to estimate the mean source area emission strength from measurements of NH3 concentrations downwind of the source area. (Flesch et al, 1995, J. Applied Meteorology) (Kljun, et al., 2002, Boundary-Layer Meteorology)
The application of micromet methods is not limited by the micromet state of the art but by the current methods used to measure the trace gas of interest (NH 3 ). Fast time response (> 1 Hz) eddy covariance Slow but accurate gradient methods (AM,MBR) Accumulation methods (conditional sampling (REA)
Emission flux+ w+,c+, w-,c-, + Deposition flux- w-,c+, w+,c-, - Eddy covariance is inherently a noise rejection method as the high number of samples in an averaging period (30 min – 60 min) will average out if errors are random with a mean of 0. Useful results can be obtained even with low signal/noise ratios. Eddy covariance
Advantages of Eddy Covariance Good time resolution Inherently a noise rejection method > many samples Consideration s Usually requires major power for pumps, etc. Usually not “all” weather instrumentation If using sampling tubes, tubes, and inlet losses
Measure the flux (eddy covariance) and vertical gradient of constituent (heat, water vapour, CO 2 ) over specified height. Compute effective transfer coefficient (flux/gradient) Measure vertical gradient of NH 3 over same height interval and apply computed transfer coefficient to obtain a measure of the flux Gradient (Modified Bowen Ratio Method)
Water vapor and CO 2 gradients To remove bias error, use same analyzer for both heights, switching at 30 sec to 5 min intervals and allowing for representative sampling. Relative error For T c = 60 s, s, = 10%
Advantages of MBR Good for slow response trace gas sensors Adequate time resolution (30 min -> hour) Considerations Bias tests on surrogate scalars Bias test on trace gas gradient systems Sampling tube and inlet losses
Conditional Sampling Relaxed Eddy Accumulation For sampling gases and aerosols in accumulation devices like annular denuders, filterpacks, etc. Flux = w (C up - C dn ) empirical coefficient, 0.6 w = standard deviation vertical velocity C up, C dn = average concentration of updrafts, downdrafts
What constitutes an updraft, etc.? Separate “w” into three bins deadband +/ m/s dead accumulator updraft > 0.1 m/s up accumulator downdraft < -0.1 m/s down accumulator
Updraft Downdraft Deadband (mid)
Ammonia Fluxes (REA) ● USDA/ARS-BARC J. Meisinger ● NOAA/ARL W. Luke 20 l/min flow cyclone/impactor 2.5 m cut-point citric acid (phosphoric) coated denuders 3-4 hour sample intervals
These plants could use a drink mmh
Average Loss 1.5 kg N/ha/day
Advantages of REA When used with denuders and filterpacks, can sample several species at once (NH 3, NH 4, SO 2, | SO 4, HNO 3, NO 3 ) Consideration s Very manual intensive with denuders (cleaning, coating, exposing, extracting, IC analysis Sample flows and extraction volumes need to be measured very accurately