Short-range impacts to sensitive ecosystems as a result of ammonia emitted by livestock farms are often assessed using atmospheric dispersion modelling systems such as AERMOD. These assessments evaluate mean annual atmospheric concentrations of ammonia and nitrogen deposition rates at the ecosystem location for comparison with ecosystem damage thresholds. However, predictions of mean annual atmospheric concentrations can be dominated by periods of stable night-time conditions, which can contribute significantly to mean concentrations. AERMOD has been demonstrated to overestimate concentrations in certain stable low-wind conditions and so the model could potentially overestimate the short-range impacts of livestock ammonia emissions. This paper tests several modifications to the parameterisation of AERMOD (v12345) that aim to improve model predictions in low-wind conditions. The modifications are first described and then are applied to three pig farm case studies in the USA, Denmark and Spain to assess whether the modifications improve long-term mean ammonia concentration predictions through improved model performance. For these three case studies, most of the modifications tested improved model performance as a result of reducing the long-term mean concentration predictions, with the largest effect for low- or ground-level sources (e.g. slurry lagoons or naturally ventilated housing)

Sutton, Mark A.

Theobald, Mark Richard

Archivo Digital UPM

Improving the low-wind performance of the AERMOD atmospheric dispersion model for predicting short-range impacts of livestock ammonia emissions.

Servicio de Coordinación de Bibliotecas de la Universidad Politécnica de Madrid

 
IMPROVING THE LOW-WIND PERFORMANCE OF THE AERMOD ATMOSPHERIC 
DISPERSION MODEL FOR PREDICTING SHORT-RANGE IMPACTS OF LIVESTOCK AMMONIA 
EMISSIONS 
 
 Mark R. Theobald1 and Mark A. Sutton2 
 
1Department of agricultural chemistry and analysis, Higher Technical School of Agricultural Engineering, 
Technical University of Madrid (UPM), Madrid, Spain 
2Centre for Ecology & Hydrology, Edinburgh Research Station, United Kingdom 
 
 
Abstract: Short-range impacts to sensitive ecosystems as a result of ammonia emitted by livestock farms are often assessed 
using atmospheric dispersion modelling systems such as AERMOD.  These assessments evaluate mean annual atmospheric 
concentrations of ammonia and nitrogen deposition rates at the ecosystem location for comparison with ecosystem damage 
thresholds.  However, predictions of mean annual atmospheric concentrations can be dominated by periods of stable night-
time conditions, which can contribute significantly to mean concentrations.  AERMOD has been demonstrated to 
overestimate concentrations in certain stable low-wind conditions and so the model could potentially overestimate the short-
range impacts of livestock ammonia emissions. This paper tests several modifications to the parameterisation of AERMOD 
(v12345) that aim to improve model predictions in low-wind conditions.  The modifications are first described and then are 
applied to three pig farm case studies in the USA, Denmark and Spain to assess whether the modifications improve long-term 
mean ammonia concentration predictions through improved model performance.  For these three case studies, most of the 
modifications tested improved model performance as a result of reducing the long-term mean concentration predictions, with 
the largest effect for low- or ground-level sources (e.g. slurry lagoons or naturally ventilated housing). 
 
Key words: Ammonia, Agriculture, AERMOD, Atmospheric Dispersion Modelling, Low wind speed 
 
INTRODUCTION 
Ammonia emitted into the atmosphere from agricultural sources can have an impact on nearby sensitive 
ecosystems, either through elevated ambient concentrations or dry/wet deposition to vegetation and soil surfaces. 
Short-range atmospheric dispersion models such as AERMOD are often used to assess these potential impacts 
on semi-natural ecosystems (Theobald et al., 2012). Recent studies have shown how AERMOD can 
overestimate atmospheric concentrations under low-wind stable conditions.  In order to correct this 
overestimation, Paine et al. (2010) suggested an empirical correction to the calculation of the friction velocity 
(u*) for low-wind stable conditions based on a linear relationship between u* and the wind speed.  Paine et al. 
(2010) also suggested an increase in the minimum value of the crosswind turbulence (σv) from 0.2 to 0.4 m s-1. 
More recently the developers of AERMOD have included BETA options in the model to improve low wind 
speed performance (US EPA, 2012). These options include the parameterisation of u* proposed by Qian and 
Venkatram (2011): 
 
)/2exp(1
)2/exp(1
2
22/1
* r
rUCu DN
−−
−+
= ,        (1) 
 
where CDN is the drag coefficient for neutral conditions, U is the wind speed and r is the ratio between the wind 
speed and a critical wind speed (Ucrit). The AERMOD BETA options also include two additional low wind 
options: LOWWIND1 (Increased σv min and with horizontal meander) and LOWWIND2 (Increased σv min and no 
horizontal meander).  This study applies these suggested modifications and BETA options to assess whether they 
improve predicted concentrations for three agricultural case studies. 
 
 
MATERIALS AND METHODS 
The AERMOD parameterisations applied are summarised in Table 1. 
 
 
 
 
 
 
 
 
Table 1. Parameterisations tested 
 
Scenario u* parameterisation  Dispersion parameterisation Reference 
Base Original Original Cimorelli et al. (2002) 
P1 Linear with wind speed  Original 
Paine et al. (2010) P2 Original Increased σv min 
P3 Linear with wind speed Increased σv min 
BETA 0 Equation (1) Original Qian and Venkatram (2011) 
BETA 1 Equation (1) Increased σv min, no horizontal meander 
US EPA (2012) 
BETA 2 Equation (1) Increased σv min, horizontal meander 
 
Mean atmospheric ammonia concentrations were simulated and compared with measured values for three case 
study pig farms (Table 2).  Two of these case studies (Falster and North Carolina) were used by Theobald et al. 
(2012) to evaluate the performance of several atmospheric dispersion models.  A third case study pig farm 
(Aguilafuente) was added for this study in order to assess model performance for Mediterranean climatic 
conditions. 
 
Table 2. Case studies used 
 
Case study  Location  Source information Study length Reference 
Aguilafuente Segovia, Spain 
Three mechanically 
ventilated pig houses 
and a slurry lagoon 
1 year 
None 
Falster Denmark One mechanically ventilated pig house 
3 months Pedersen et al. 
(2007) 
North 
Carolina USA 
Five naturally ventilated 
pig houses and a slurry 
lagoon 
1 year Walker et al. 
(2008) 
 
Long-term mean ammonia concentrations were simulated and compared with those measured using passive 
samplers located at various distances and directions from the sources.  Long-term mean concentrations were 
used for this study since they are used in ecological impact assessments in Europe (e.g. for the UK see 
Environment Agency (2010)).  Model performance was assessed using the performance indicators suggested by 
Chang and Hanna (2004): fractional bias (FB); geometric mean bias (MG); normalised mean square error 
(NMSE); geometric variance (VG); the number of predictions within a factor of two of the observed values 
(FAC2) and the correlation coefficient (R or R2). 
 
RESULTS 
 
Effect of modifications on mean concentrations 
The modifications to the AERMOD model generally decreased long-term mean concentration predictions for all 
three case studies (Figure 1). The largest effect was for the North Carolina case study (volume and area sources), 
for which all of the modifications except P2 (increased σv min) decreased long-term mean concentrations by 28-
57%. The overall effect of the modifications for the Aguilafuente case study (point and area sources) was similar 
but smaller, although increases in concentrations were also predicted for some measurement locations.  The 
smallest effect of the modifications was for the Falster case study (point sources) for which the concentration 
predictions varied by -21% to +9%. The two modifications based on a linear relationship of u* with wind speed 
for low-wind stable conditions (P1 and P3) had a similar effect on mean concentrations although increasing σv 
min (P3) increased the concentration predictions for some wind sectors for the Aguilafuente case study.  
Increasing σv min on its own (P2) resulted in small overall changes in concentration predictions but substantial 
increases and decreases in the concentration predictions for individual locations.  All three BETA modifications 
had a similar effect on long-term mean concentration predictions although BETA 1 (adjusted u*, increased σv min, 
no horizontal meander) was the only BETA modification that decreased overall concentration predictions for all 
three case studies. 
 
 
Figure 1. Effect of the modifications on long-term mean concentrations relative to the base case study, averaged over all 
measurement locations.  Error bars show the range of the effect on the long-term mean concentrations for all measurement 
locations. 
 
Effect of modifications on performance indicators 
For the Aguilafuente case study, all modifications tested improved the indicator values of FB and NMSE (i.e. the 
points on Figure 2 are all closer to the origin than that of the base case study (0)).  The indicator values of MG 
are all slightly worse than the base case study, although MG of the base case study (-0.004) was very close to the 
optimum. Improvements in the indicator values of VG were obtained with all modifications tested, except BETA 
1.  Values of FAC2 were improved or left unchanged for all modifications whilst the linear correlation of the 
predicted concentrations with the measured values (R2) was improved (not shown). For the Falster case study the 
effect of the modifications was to improve some of the indicator values whilst worsening others (Figure 3). The 
modifications P1-P3 and BETA 1 improved the values of FAC2 and R2, whilst BETA 0 and BETA 2 worsened 
them.  All performance indicator values were improved when the modifications were applied to the North 
Carolina case study, except for the P2 modification (increased σv min only) (Figure 4), which worsened all 
indicator values except FAC2 (not shown).  Overall the modifications have varying effects on the performance 
indicator values depending on the case study.  This variability is probably due to the combined effects of source 
types, source to measurement location distances and meteorological conditions.  Overall the modifications result 
in an improvement of the indicator values (with a few exceptions) although the changes are not large. In fact the 
modifications result in few changes to model acceptability based on the acceptability criteria of Chang and 
Hanna (2004), with the exception of the Carolina case study, for which the modifications result in the model 
meeting the bias acceptability criteria (FB and MG) as well as the FAC2 criterion due to the decrease in 
prediction concentrations.   
 
Figure 2. Plotted values of the performance indicators: fractional bias (FB); geometric mean bias (MG); normalised mean 
square error (NMSE) and geometric variance (VG) for the Aguilafuente case study. Dotted lines indicate the theoretical 
minimum values for NMSE and VG. 
 
 
Figure 3. Plotted values of the performance indicators: fractional bias (FB); geometric mean bias (MG); normalised mean 
square error (NMSE) and geometric variance (VG) for the Falster case study. Dotted lines indicate the theoretical minimum 
values for NMSE and VG. 
 
Figure 4. Plotted values of the performance indicators: fractional bias (FB); geometric mean bias (MG); normalised mean 
square error (NMSE) and geometric variance (VG) for the North Carolina case study. Dotted lines indicate the theoretical 
minimum values for NMSE and VG. 
 
 
 
DISCUSSION AND CONCLUSIONS 
This study tests several modifications to the AERMOD model aimed to improved the low-wind speed 
performance of the model for situations similar to those encountered in environmental impact assessments for 
ammonia emissions from agricultural practices (i.e. prediction of long-term mean concentrations). As the above 
analysis shows, the modifications improved model performance for most cases, as demonstrated by the fact that 
more performance indicator values were improved as a result of the modifications than were worsened. The 
smallest improvement was obtained using modification P2 (increased σv min only). This modification increased 
lateral dispersion of the plume, decreasing concentrations in the main wind directions and increasing 
concentrations in the less frequent wind directions. This resulted in little or no improvement in model 
performance (see Figures 2-4).  For these three case studies, the largest improvement in model performance was 
obtained based on a linear relationship of u* with wind speed for low-wind stable conditions (P1 and P3), 
although the BETA modifications gave similar improvements in some cases.  The improvements in model 
performance varied depending on the case study.  Part of this variation depended on the source and measurement 
location characteristics.  Concentration predictions were least affected at measurement locations close to 
elevated point sources, whereas they were most affected close to area and volume sources.  To illustrate these 
differences, Figure 5 shows the hourly concentration predictions as a result of the emissions from different 
source types plotted against wind speed when the modifications P1-3 are applied to the Aguilafuente case study. 
Predicted concentrations as a result of the housing emissions (elevated point sources) are affected less by the 
modifications than those resulting from the slurry lagoon emissions (area source).  This shows that the dispersion 
from ground-level area sources is more sensitive to the modifications to u* than that from elevated point sources, 
which would explain why the modifications had a small effect on the predicted mean concentrations for the 
Falster case study (elevated point sources).  This would also explain the large effect of the modifications on the 
concentration predictions for the North Carolina case study since all emission sources are ground- or low-level.   
 
 
Figure 5. Hourly concentration predictions as a result of the emissions from a) animal houses and b) slurry lagoon plotted 
against wind speed for the original model parameterisation (Base) and when the modifications P1-3 are applied to the 
Aguilafuente case study. 
 
The focus of this work has been on long-term mean concentration predictions since these are the focus for 
environmental impact assessments for ammonia.  However, it is useful also to look at how these modifications 
affect hourly percentile concentrations to make this study relevant to work on other regulatory pollutants (e.g 
nitrogen dioxide, particulate matter etc.).  Similarly to the effect on long-term mean concentrations, the 
modifications affect the percentile concentrations least for the Falster case study (98th percentile concentrations 
decreased by 1-7%) and most for the North Carolina case study.  For the latter study the P2 modification 
(increased σv min only) decreased 98th percentile concentrations by just 3% whereas the other modifications 
decreased them by 18-58%.   
 
ACKNOWLEDGEMENTS 
The authors would like to thank Poul Pedersen (Danish Agriculture and Food Council) and John Walker (US 
EPA) for providing case study datasets and Peter Eckhoff and Roger Brode (US EPA) for their assistance with 
the AERMET source code. The authors would also like to thank the European Commission 7th Framework 
ÉCLAIRE IP for financial support. 
 
REFERENCES 
US EPA, 2012, Revised Draft Users’Guide for the AMS/EPA Regulatory Model – AERMOD (EPA-454/B-03-
001, September 2004 - addendum v12345). 
Chang, J.C., Hanna, S.R., 2004. Air quality model performance evaluation. Meteorol. Atmos. Phys., 87(1), 167-
196. 
Cimorelli, A.J., Perry, S.G., Venkatram, A., Weil, J.C., Paine, R.J., Wilson, R.B., Lee, R.F., Peters, W.D., Brode, 
R.W., Pauimer, J.O., 2002. AERMOD: Description of model formulation version 02222. United States 
Environmental Protection Agency, Research Triangle Park, NC 27711, USA, 85pp. 
Environment Agency, 2010. Guidance on modelling the concentration and deposition of ammonia emitted from 
intensive farming. 
Paine, R.; Connors, J.; Szembek, C. AERMOD Low Wind Speed Evaluation Study: Results and Implementation; 
Paper 2010-A-631-AWMA. Presented at A&WMA’s 103rd Annual Conference and Exhibition, 
Calgary, Alberta, Canada, June 2010 
Pedersen, P., Løfstrøm, P., Vibeke Andersen, H., 2007. Ammoniak spredning omkring en svineproduktion. 
Dansk Svineproduktion, Meddelelse nr. 790 (In Danish). 
Qian W, Venkatram A. Performance of Steady-State Dispersion Models Under Low Wind-Speed Conditions. 
2011. Bound.-Layer Meteorol.;138(3):475-91. 
Theobald M.R., Løfstrøm P., Walker J., Andersen H.V., Pedersen P., Vallejo A., Sutton M.A., 2012. An 
intercomparison of models used to simulate the short-range atmospheric dispersion of agricultural 
ammonia emissions. Environmental Modelling & Software 37, 90-102. 
Walker, J., Spence, P., Kimbrough, S., Robarge, W., 2008. Inferential model estimates of ammonia dry 
deposition in the vicinity of a swine production facility. Atmos. Environ., 42(14), 3407-3418. 


http://oa.upm.es/26644/1/INVE_MEM_2013_161552.pdf

Improving the low-wind performance of the AERMOD atmospheric dispersion model for predicting short-range impacts of livestock ammonia emissions.

Abstract

Similar works

Full text

Available Versions

Archivo Digital UPM

Servicio de Coordinación de Bibliotecas de la Universidad Politécnica de Madrid