Abstract
The theory, applications, strengths and weaknesses of approaches commonly used for measuring trace gas fluxes are reviewed. Chambers, representing the smallest scale (∼1 m2), are the most common tools. Their operating principle is simple, they can be highly sensitive, the cost can be low and field requirements small. Problems include leaks, stickiness of some gases, inhibition of fluxes through concentration build-up, pressure effects and spatial and temporal variability in gas fluxes. Mass balance techniques are suitable for small, defined source areas, typically tens to thousands of square metres in extent. Emissions are calculated from the difference in the rates at which the gas is carried into a control volume above the source area by the wind and carried out. The required primary data are profiles of gas concentration on the downwind boundaries as well as the wind speed profile, the wind direction and the upwind background gas concentration. They have been used to measure gas emissions from landfills, treated fields and small animal herds. Circular test areas make the method independent of wind direction. A newly developed technique based on a backward Lagrangian stochastic dispersion model is also applicable to small, well-defined source areas of any shape. The surface flux is calculated form measurements of atmospheric turbulence and stability and the gas concentration at any height downwind. Implementation of the method is aided greatly by a software package WindTrax. The combination provides a powerful new tool for measuring gas emissions from treated areas and intensive animal production systems. Finally, techniques suitable for measuring gas emissions on large landscape scales (ha) are discussed. Eddy covariance is the micrometeorologist’s preferred technique for this scale. The method uses fast response anemometers and gas sensors to make direct measurements of the vertical gas flux at a point, several times a second. However, it is not feasible for many trace gases for a variety of reasons. These are discussed. Relaxed eddy accumulation is an alternative technique that retains the attraction of eddy covariance by providing a direct point measurement. It removes the need for a fast response gas sensor by substituting for it a fast solenoid valve sampling system. Flux–gradient methods are in more common use. Fluxes are calculated as the product of an eddy diffusivity and the vertical concentration gradient of the gas or the product of a transfer coefficient and the difference in gas concentration between two heights. Assumptions of the method and precautions in its application are discussed.
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References
Baker JM (2000) Conditional sampling revisited. Agric For Meteorol 104:59–65
Baker JM, Norman JM, Bland WI (1992) Field scale application of flux measurement by conditional sampling. Agric For Meteorol 62:59–65
Baldocchi D (2003) Assessing the eddy covariance technique for evaluating carbon dioxide exchange rates of ecosystems: past, present and future. Global Change Biol 9:479–492
Beauchamp EG, Kidd GE, Thurtell G (1978) Ammonia volatilization from sewage sludge applied in the field. J Environ Qual 7:141–146
Breuer L, Papen H, Butterbach-Bahl K (2000) N2O emission from tropical forest soils of Australia. J Geophys Res 105:26353–26367
Businger JA, Oncley S (1990) Flux measurement with conditional sampling. J Atmos Ocean Technol 7:349–352
Businger JA, Yaglom AM (1971) Introduction to Obukhov’s paper on turbulence in an atmosphere with a non-uniform temperature. Boundary-Layer Meteorol 2:3–6
Coppin PA, Taylor KJ (1983) A three component sonic anemometer/thermometer system for general micrometeorological research. Boundary-Layer Meteorol 27:27–42
Denman KL, Brasseur G, Chidthaisong G, Ciais PM, Cox RE, Dickinson D, Hauglustaine C, Heinze E, Holland E, Jacob D, Lohmann U, Ramachandran S, da Silva D, Wofsy FC, Zhang X (2007) Couplings between changes in the climate system and biogeochemistry. In: Solomon S, Qin M, Manning M, Chen Z, Marquis M, Averyt KB, Tigor M, Miller HL (eds) Climate change 2007: the physical science basis. Contribution of working Group 1 to the fourth assessment Report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge, UK, pp 499–587
Denmead OT (1979) Chamber systems for measuring nitrous oxide fluxes in the field. Soil Sci Soc Am J 43:89–95
Denmead OT, Reicosky DC (2003) Tillage-induced gas fluxes: comparison of meteorological and large chamber techniques. In: Proceedings of the International Soil Tillage Research Prganizations 2003 conference, Brisbane, Australia, July 13–18, 2003
Denmead OT, Simpson JR, Freney JR (1977) A direct field measurement of ammonia emission after injection of anhydrous ammonia. Soil Sci Soc Am J 41:1001–1004
Denmead OT, Freney JR, Simpson JR (1982) Atmospheric dispersion of ammonia during application of anhydrous ammonia fertilizer. J Environ Qual 11:568–572
Denmead OT, Harper LA, Freney JR, Griffith DWT, Leuning R, Sharpe RR (1998) A mass balance method for non-intrusive measurements of surface–air trace gas exchange. Atmos Environ 32:3679–3688
Denmead OT, Leuning R, Jamie I, Griffith DWT (2001) Nitrous oxide emissions from grazed pastures: measurements at different scales. Chemosphere Global Change Sci 2:301–312
Denmead OT, Chen D, Turner D, Li Y, Edis R (2004) Micrometeorological measurements of ammonia emissions during phases of the grazing rotation of irrigated dairy pastures. In: Proceedings of Supersoil 2004: Program and Abstracts for the 3rd Australian New Zealand Soils Conference. University of Sydney, Australia, 5–9 December 2004. Available at: www.regional.org.au/au/asssi/
Denmead OT, Macdonald BCT, Bryant G, White I, Moody P, Dalal RC, Stainlay W (2006) Greenhouse gas emissions from sugarcane soils and nitrogen fertiliser management. Proc Aust Soc Sugar Cane Technol 28:252–260
Desjardins RL, Buckley D, St Amour G (1984) Eddy flux measurements of CO2 above corn using a microcomputer system. Agric For Meteorol 32:257–265
Desjardins RL, Rochette P, Pattey E, MacPherson I (1993) Measurements of greenhouse gas fluxes using aircraft- and tower-based techniques. In: Harper LA, Mosier AR, Duxbury JM, Rolston DE (eds) Agricultural ecosystem effects on trace gases and global climate change. American Society of Agronomy Special Publication no. 55. American Society of Agronomy, Madison, WI, pp 19–43
Desjardins R, Denmead OT, Harper L, McBain M, Masse D, Kaharabata S (2004) Evaluation of a micrometeorological mass balance method employing an open-path laser for measuring methane emissions. Atmos Environ 38:6855–6866
deVries DA, Philip JR (1986) Soil heat flux, thermal conductivity, and the null-alignment method. Soil Sci Soc Am J 50:12–18
Finnigan JJ, Clements R, Malhi Y, Leuning R, Cleugh HA (2003) A re-evaluation of long-term flux measurement techniques Part 1: averaging and coordinate rotation. Boundary-Layer Meteorol 107:1–48
Flesch TK, Wilson JD (2005) Estimating tracer emissions with a backward Lagrangian stochastic technique. In: Hatfield JL, Baker JM (eds) Micrometeorology in agricultural systems. Agronomy monograph no. 47. American Society of Agronomy, Madison, WI, pp 513–531
Flesch TK, Wilson JD, Yee E (1995) Backward-time Lagrangian stochastic dispersion models and their application to estimate gaseous emissions. J Appl Meteorol 34:1320–1322
Flesch TK, Prueger JH, Hatfield JL (2002) Turbulent Schmidt number from a tracer experiment. Agric For Meteorol 111:299–307
Flesch TK, Wilson JD, Harper LA, Crenna BP, Sharpe RR (2004) Deducing ground to air emissions from observed trace gas concentrations: a field trial. J Appl. Meteorol 43:487–502
Freney JR, Denmead OT, Wood AW, Saffigna PG, Chapman LS, Ham GJ, Hurney AP, Stewart RL (1992) Factors controlling ammonia loss from trash covered sugarcane fields fertilised with urea. Fertil Res 31:341–349
Harper LA, Denmead OT, Freney JR, Byers FM (1999) Direct measurements of methane emissions from grazing and feedlot cattle. J Anim Sci 77:1392–1401
Hatfield JL, Baker JM (2005) Micrometeorology in agricultural systems. Agronomy monograph no. 47. American Society of Agronomy, Madison, WI (584 pp)
Hicks BB, McMillen RT (1984) A simulation of the eddy accumulation method for measuring pollutant fluxes. J Clim Appl Meteorol 23:637–643
Ibrom A, Dellwik E, Flyvbjerg H, Jensen NO, Pilegaard K (2007) Strong low-pass filtering effects on water vapour flux measurements with closed-path eddy correlation systems. Agric For Meteorol 147:140–156
Jury WA, Letey J, Collins T (1982) Analysis of chamber methods used for measuring nitrous oxide production in the field. Soil Sci Soc Am J 46:250–256
Kaimal JC, Finnigan JJ (1994) Atmospheric boundary layer flows: their structure and measurement. Oxford University Press, New York
Laubach J, Kelliher FM (2004) Measuring methane emissions of a dairy herd by two micrometeorological techniques. Agric For Meteorol 125:279–303
Laubach J, Kelliher FM, Knight TTW, Clark HH, Molano G, Cavanagh A (2008) Methane emissions form beef cattle – a comparison of paddock- and animal-scale measurements. Aust J Exp Agric 48:132–137
Laville P, Jambert C, Cellier P, Delmas R (1999) Nitrous oxide fluxes from a fertilized maize crop using micrometeorological and chamber methods. Agric For Meteorol 96:19–38
Leclerc MY, Thurtell GW (1990) Footprint prediction of scalar fluxes using a Markovian analysis. Boundary-Layer Meteorol 52:247–258
Lenschow DH, Raupach MR (1991) The attenuation of fluctuations in scalar concentrations through sampling tubes. J Geophys Res 96:15259–15268
Leuning R, Judd MJ (1996) The relative merits of open- and closed-path analysers for measurements of eddy fluxes. Global Change Biol 2:241–253
Leuning R, King KM (1992) Comparison of eddy-covariance measurements of CO2 fluxes by open- and closed-path CO2 analysers. Boundary-Layer Meteorol 59:297–311
Leuning R, Moncrieff J (1990) Eddy-covariance CO2 flux measurements using open-path and closed-path CO2 analysers – corrections for analyser water vapour sensitivity and damping of fluctuations in air sampling tubes. Boundary-Layer Meteorol 53:63–76
Leuning R, Freney JR, Denmead OT, Simpson JR (1985) A sampler for measuring atmospheric ammonia flux. Atmos Environ 19:1117–1124
Leuning R, Baker SJ, Jamie IM, Hsu CH, Klein L, Denmead OT, Griffith DWT (1999) Methane emission from free-ranging sheep: a comparison of two measurement methods. Atmos Environ 33:1357–1365
Livingston GP, Hutchinson GL (1995) Enclosure-based measurement of trace gas exchange: applications and sources of error. In: Matson PA, Harriss RC (eds) Biogenic trace gases: measuring emissions from soil and water. Blackwell, Oxford, pp 14–51
Matson PA, Harriss RC (1995) Biogenic trace gases: measuring emissions from soil and water. Blackwell, Oxford, p 394
McBain MC, Desjardins RL (2005) The evaluation of a backward Lagrangian stochastic (bLS) model to estimate greenhouse gas emissions from agricultural sources using a synthetic tracer source. Agric For Meteorol 135:61–72
McGinn SM (2006) Measuring greenhouse gas emissions from point sources in agriculture. Can J Soil Sci 86:355–371
McInnes KJ, Heilman JL (2005) Relaxed eddy accumulation. In: Hatfield JL, Baker JM (eds) Micrometeorology in agricultural systems. Agronomy monograph no. 47. American Society of Agronomy, Madison, WI, pp 437–453
McNaughton KG (2006) On the kinetic energy budget of the unstable surface layer. Boundary-Layer Meteorol 118:83–107
Meyer CP, Galbally IE, Wang YP, Weeks IA, Jamie I, Griffith DWT (2001) Two automatic chamber techniques for measuring soil–atmosphere exchanges of trace gases and results of their use in the OASIS field experiment. Technical paper no. 51. CSIRO Atmospheric Research, Aspendale, Australia (33 pp)
Moore CJ (1986) Frequency response corrections for eddy correlation systems. Boundary-Layer Meteorol 37:17–35
Oncley SP, Delaney AC, Horst TW (1993) Verification of flux measurement using relaxed eddy accumulation. Atmos Environ 27:2417–2426
Pain BF, Clarkson CR, Phillips VR, Klarenbeek JV, Misselbrook TH, Bruins M (1991) Odour emission arising from application of livestock slurries on land: measurements following spreading using a micrometeorological technique and olfactometry. J Agric Eng Res 48:101–110
Pattey E, Desjardins RL, Rochette P (1993) Accuracy of the relaxed eddy accumulation technique, evaluated using CO2 flux measurements. Boundary-Layer Meteorol 66:341–355
Pattey E, Edwards G, Strachan IB, Desjardins RL, Kaharabata S, Wagner-Riddle C (2006a) Towards standards for measuring greenhouse gas emissions from whole farms. Can J Soil Sci 86:373–400
Pattey E, Strachan IB, Desjardins RL, Edwards GC, Dow D, MacPherson JI (2006b) Application of a tunable diode laser to the measurement of CH4 and N2O fluxes from field to landscape scale using several micrometeorological techniques. Agric For Meteorol 136:222–236
Phillips FA, Leuning R, Baigent R, Kelly KB, Denmead OT (2007) Nitrous oxide flux measurements from an intensively managed irrigated pasture using micrometeorological techniques. Agric For Meteorol 143:92–105
Prasertsak P, Freney JR, Saffigna PG, Denmead OT, Prove BG (2001) Fate of urea nitrogen applied to a banana crop in the wet tropics of Queensland. Nutr Cycl Agroecosyst 59:65–73
Prueger JH, Kustas WP (2005) Aerodynamic methods for estimating turbulent fluxes. In: Hatfield JL, Baker JM (eds) Micrometeorology in agricultural systems. Agronomy monograph no. 47. American Society of Agronomy, Madison, WI, pp 407–436
Raupach MR, Legg BJ (1984) The uses and limitations of flux–gradient relationships in micrometeorology. Agric Water Manag 8:119–131
Ryden JC, McNeill JE (1984) Application of the micrometeorological mass balance method for the determination of ammonia loss from a grazed sward. J Sci Food Agric 35:1297–1310
Schuepp PH, Leclerc MY, MacPherson JI, Desjardins RL (1990) Footprint prediction of scalar fluxes from analytical solutions of the diffusion equation. Boundary-Layer Meteorol 50:355–373
Wagner-Riddle C, Thurtell GW, Edwards GC (2005) Trace gas concentration measurements for micrometeorological flux quantification. In: Hatfield JL, Baker JM (eds) Micrometeorology in agricultural systems. Agronomy monograph no. 47. American Society of Agronomy, Madison, WI, pp 321–343
Webb EK, Pearman GI, Leuning R (1980) Correction of flux measurements for density effects due to heat and water vapour transfer. Q J R Meteorol Soc 106:85–100
Wesely ML, Lenschow DH, Denmead OT (1989) Flux measurement techniques. In: Lenschow DH, Hicks BB (eds) Global tropospheric chemistry: chemical fluxes in the global atmosphere. National Centre for Atmospheric Research, Boulder, CO, pp 31–46
Wilson JD, Shum WKN (1992) A re-examination of the integrated horizontal flux method for estimating volatilisation from circular plots. Agric For Meteorol 57:281–295
Wilson JD, Thurtell GW, Kidd GE, Beauchamp EG (1982) Estimation of the rate of gas mass transfer from a surface plot to the atmosphere. Atmos Environ 16:1861–1867
Wilson JD, Catchpoole VR, Denmead OT, Thurtell GW (1983) Verification of a simple micrometeorological method for estimating the rate of gaseous mass transfer from the ground to the atmosphere. Agric Meteorol 29:183–189
Wyngaard JC, Moeng CH (1992) Parameterising turbulent diffusion through the joint probability density. Boundary-Layer Meteorol 60:1–13
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I wish to thank three anonymous reviewers for their very thorough examinations of the manuscript and their very valuable suggestions for improvement.
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Denmead, O.T. Approaches to measuring fluxes of methane and nitrous oxide between landscapes and the atmosphere. Plant Soil 309, 5–24 (2008). https://doi.org/10.1007/s11104-008-9599-z
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DOI: https://doi.org/10.1007/s11104-008-9599-z