2.2.1 Hydro-meteorological data and sensible and latent heat fluxes

A range of hydro-meteorological variables are measured by a meteorological station at the Dahra field site (Tagesson et al., 2015b). The hydro-meteorological variables used in this study were rainfall (mm), air temperature (^∘C), relative air humidity (%), wind speed (m s⁻¹), air pressure (hPa) at 2 m height, soil temperature (^∘C), soil moisture (%) at 0.05, 0.10, and 0.30 m depth, and net radiation (W m⁻²). Data were sampled every 30 s and stored as 15 min averages (sum for rainfall). Data have then been 3h and daily averaged for the purpose of this study.

Land–atmosphere exchanges of sensible and latent heat was measured for the years 2012 and 2013 with an eddy covariance system consisting of an open-path infrared gas analyzer (LI-7500, LI-COR Inc., Lincoln, USA) and a three-axis sonic anemometer (Gill R3 ultrasonic anemometer, Hampshire, UK) (Tagesson et al., 2015a). The sensors were mounted 9 m above the ground and data were collected at a 20 Hz rate. The post-processing was performed with the EddyPro 4.2.1 software (LI-COR Biosciences, 2012) and statistics were calculated for 30 min periods. For a thorough description of the post-processing of sensible and latent heat fluxes, see Supplement of Tagesson et al. (2015b).

2.2.2 Atmospheric NH₃ concentrations using passive samplers

Atmospheric concentrations of NH₃ and other compounds such as N₂O, HNO₃, O₃, and SO₂ were measured using passive samplers on a monthly basis, in accordance with the methodology used within the INDAAF (International Network to study Deposition and Atmospheric chemistry in Africa) program (https://indaaf.obs-mip.fr, last access: 8 May 2019) driven by the Laboratoire d'Aerologie (LA) in Toulouse. While not being actually part of the INDAAF network, the Dahra site was equipped with the same passive sampler devices and analyses of these samplers were performed following the INDAAF protocol at LA.

Passive samplers were mounted under a stainless-steel holder to avoid direct impact from wind transport and splashing from precipitation. The holder was attached at a height of about 1.5 m above ground. All the samplers were exposed in pairs in order to ensure the reproducibility of results. The samplers were prepared at LA in Toulouse, installed and collected after 1 month exposure by a local investigator, and sent back to LA. Samplers before and after exposition were stored in a fridge (4 ^∘C) to minimize possible bacterial decomposition or other chemical reactions. Samplers were then analysed by ion chromatography (IC) to determine ammonium and nitrate concentrations. Validation and quality control of passive samplers according to international standards (World Meteorological Organization report), as well as the sampling procedure and chemical analysis of samples, have been widely detailed in Adon et al. (2010). Monthly mean NH₃ concentrations in parts per billion by volume are calculated for the period 2012 and 2013. The measurement accuracy of NH₃ passive samplers, evaluated through covariance with duplicates, and the detection limit evaluated from field blanks were estimated respectively at 14 % and 0.7±0.2 ppb (Adon et al., 2010).

2.2.3 Measurements of NO, NH₃, and CO₂ (respiration) fluxes from soil and soil physical parameters

NO, NH₃, and CO₂ fluxes were measured for 7 d in July 2012, 8 d in July 2013, and 10 d in November 2013; these periods will hereafter be called J12, J13, and N13 respectively. The samples were taken at three different locations along a 500 m transect following a weak dune slope (top, middle, and bottom) with one location per day. Each location was then sampled every 3 d, approximately from 08:00 to 19:00 UTC for soil fluxes, and 24 h a day for NO and NH₃ concentrations. Between 15 and 20 fluxes were measured each day during the three campaigns.

NO and NH₃ fluxes were measured with a manual closed dynamic Teflon chamber (non-steady-state through-flow chamber; Pumpanen et al., 2004) with dimensions of 200 mm width × 400 mm length × 200 mm height. During the J12 campaign, the chamber was connected to a Laboratoire d'Aerologie analyzer, whereas in J13 and N13, it was connected to a Thermo Scientific 17I analyzer (ThermoFischer Scientific, MA, USA). The calculation of fluxes is based on an equation detailed in Delon et al. (2017), adapted from Davidson et al. (1991). The increase rate of NO and NH₃ mixing ratios used in the flux calculation equation was estimated by a linear regression fitted to data measured for 180 to 300 s for NO (120 s for NH₃) following the installation of the chamber on the soil, as detailed in Delon et al. (2017). Close to the Teflon chamber, soil CO₂ respiration was measured with a manual closed dynamic chamber (SRC-1 from PP Systems, 150 mm height × 100 mm diameter) coupled to a non-dispersive infrared CO₂∕H₂O analyzer EGM-4 (PP Systems, Hitchin, Hertfordshire, UK). Soil CO₂ respiration was measured within 30 cm of the location of the NO and NH₃ fluxes. Measurements were performed on bare soil to ensure only root and microbe respiration. Results of NO, NH₃, and CO₂ fluxes are presented as daily means with daily standard deviations. Along with flux measurements, soil physical parameters were measured during the campaigns: soil pH ranges from 5.77 to 7.43, sand content ranges between 86 % and 94 %, and clay content ranges between 4.7 % and 7.9 %. All the methods, calculations, and results from the field campaigns are fully detailed in Delon et al. (2017).

2.3.1 The STEP–GENDEC model

The STEP model is presented in Appendix A, with forcing variables detailed in Table A1, site parameters used in the initialization in Table A2, numerical values of parameters used in the equations in Table A3, and equations, variables, parameters, and constants used in the equations in Table A4.

STEP is an ecosystem process model for Sahelian herbaceous savannas (Mougin et al., 1995; Tracol et al., 2006; Delon et al., 2015). It is coupled to GENDEC, which aims at representing the interactions between litter, decomposer microorganisms, microbial dynamics, and C and N pools (Moorhead and Reynolds, 1991). It simulates the decomposition of the organic matter and microbial processes in the soil in arid ecosystems. Information such as the quantity of organic matter from faecal matter from livestock and herbal masses is transferred from STEP as inputs to GENDEC (Fig. 1).

Figure 1Schematic representation of NO and CO₂ flux modelling in STEP–GENDEC–NOflux (adapted from Delon et al., 2015).

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Soil temperatures are simulated from air temperature according to Parton (1984). This model requires daily maximal and minimal air temperature, global radiation (provided by forcing data), herbaceous aboveground biomass (provided by the model), initial soil temperature, and soil thermal diffusivity. Details of equations are given in Delon et al. (2015) and Appendix A (Tables A3 and A4).

Soil moisture values are calculated following the tipping-bucket approach (Manabe, 1969): when the field capacity is reached, the excess water in the first layer (0–2 cm) is transferred to the second layer, between 2 and 30 cm. Two other layers are defined, between 30–100 cm and 100–300 cm. Equations related to soil moisture calculation are detailed in Appendix A (Table A4) and in Jarlan et al. (2008). This approach, while being simple in its formulation, is especially useful in regions where detailed description of the environment is not available or unknown, and where the natural heterogeneity of the soil profile is high due to the presence of diverse matter fragments such as buried litter, dead roots from herbaceous mass and trees, stones, branches, and tunnels dug by insects and little mammals.

The STEP model is forced daily by rain, global radiation, air temperature, wind speed, and relative air humidity at 2 m height. Initial parameters specific to the Dahra site are listed in Table A1 and site parameters in Table A2.

2.3.2 Respiration and biogenic NO fluxes

The quantity of carbon in the soil was calculated from the total litter input from faecal and herbal mass, where faecal matter is obtained from the number of livestock heads grazing at the site (Diawara, 2015; Diawara et al., 2018). The quantity of carbon is 50 % the buried litter mass. The carbon and nitrogen exchanges between pools and all equations are detailed in Moorhead and Reynolds (1991) and will not be developed here. Carbon dynamics depend on soil temperature, soil moisture, and soil nitrogen (linked to microbial dynamics). The concentration of nitrogen in the soil is derived from the quantity of carbon using C∕N ratios.

Biogenic NO fluxes were calculated using the coupled model STEP–GENDEC–NOflux, as detailed in Delon et al. (2015). The NOFlux model uses an artificial neural network approach to estimate the biogenic NO emission from soil to the atmosphere (Delon et al., 2007, 2015). The NO flux is calculated from and depends on parameters such as soil surface temperature and moisture, soil temperature at 30 cm depth, sand percentage, N input (here given as a percentage of the ammonium content in the soil), wind speed, and soil pH. The input of N to the soil from the buried litter is provided by STEP, and the calculation of the ammonium content in the soil coming out from this N input is provided by GENDEC. The equations used for NO flux calculation are reported in Appendix B, taken from Delon et al. (2015).

The main structure of the model is kept identical as in the Delon et al. (2015) version, except for N uptake by plants, for which the present paper proposes a formulation detailed in Appendix C. In brief, in the previous version of the model 2 % of the ${\mathrm{NH}}_{\mathrm{4}}^{+}$ pool of the soil was used for NO emission calculation. In the current version, the NO emitted to the atmosphere results from 1 % of the ${\mathrm{NH}}_{\mathrm{4}}^{+}$ pool in the soil minus the N absorbed by plants. The percentage of soil ${\mathrm{NH}}_{\mathrm{4}}^{+}$ pool used to calculate the NO emission has been changed from 2 % to 1 % based on Potter et al. (1996), who proposed a range between 0.5 % and 2 %. In the present study, the 1 % value was more adapted to fit experimental values.

Soil respiration is the sum of autotrophic (root only) and heterotrophic respiration. The autotrophic respiration in STEP is calculated from growth and maintenance respirations of roots and shoots (Mougin et al., 1995), following equations reported in Table A4. Autotrophic respiration depends on root depth soil moisture and soil temperature (2–30 cm) and root biomass, whose dynamics are simulated by STEP. The heterotrophic respiration is calculated in GENDEC from the growth and death of soil microbes in the soil depending on the available litter C (given by STEP). Microbial respiration ρ in grammes of carbon per day is calculated as in Eq. (1).

Microbial growth in grammes of carbon per day is γ=ε Ca, where ε is the assimilation efficiency (unitless) and Ca is total C available in grammes of carbon per day, i.e. total C losses from four different litter inputs, buried litter, litter from trees, faecal matter, and dry roots. Microbial death is driven by the death of the living microbe mass, and the change in water potential during drying–wetting cycles (change between −1.5 and −0.01 MPa in the layer 2–30 cm). These calculations are described in Moorhead and Reynolds (1991) and Delon et al. (2015) and are not reported in detail in this study. A schematic view of STEP–GENDEC–NOFlux is presented in Fig. 1. Simulated variables and corresponding measurements used for validation are summarized in Table 1.

Table 1Summary of different models used in the study, with the variables simulated and compared to measurements. All simulated and measured variables were daily averaged for the purpose of the study.

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2.4.1 Inferential method (Zhang et al., 2010)

An inferential method was used to calculate the bidirectional exchange of NH₃. The overall flux F_NH3 (µg m⁻² s⁻¹) is calculated as

with V_d= 1/($R_{\mathrm{a}}+R_{\mathrm{b}}+R_{\mathrm{c}}$), where V_d (m s⁻¹) is the deposition velocity, determined by using the big-leaf dry deposition model of Zhang et al. (2003). R_a (s m⁻¹) and R_b (s m⁻¹) are the aerodynamic and quasi-laminar resistances respectively, and R_c (s m⁻¹) is the total resistance to deposition resulting from component terms such as stomatal, mesophyll, and non-stomatal/external/cuticular and soil resistances (Flechard et al., 2013, and references therein). $C_{{\mathrm{NH}}_{\mathrm{3}}}$ (µg m⁻³) is determined at the monthly scale from passive sampler measurements. The χ_cp term (µg m⁻³) is calculated following the two-layer Zhang et al. (2010) model, hereafter referred to as Zhang2010. This model gives access to an extensive literature review on compensation point concentrations and emission potential values classified for 26 different land use classes (LUCs). Compensation point concentrations are calculated in the model and vary with canopy type, nitrogen content, and meteorological conditions. This model was adapted by Adon et al. (2013) for the specificity of semi-arid ecosystems such as leaf area index (LAI) or type of vegetation, assuming a ground emission potential of 400 (unitless), considered a low-end value for non-fertilized ecosystems according to Massad et al. (2010) and based on Delon et al. (2017) experimental results, and a stomatal emission potential of 100 (unitless) based on Massad et al. (2010) for grass, and on the study of Adon et al. (2013) for similar ecosystems as the one found in Dahra. Considering the bidirectional nature of NH₃ exchange, emission occurs if the canopy compensation point concentration is superior to the ambient concentration (Nemitz et al., 2001). Emission fluxes are noted as positive. Meteorological forcing required for the simulation is 3 h-averaged wind speed, net radiation, pressure, relative humidity, air temperature at 2 m height, surface temperature at 5 cm depth, and rainfall. The equations used in this model are extensively described in Zhang et al. (2003, 2010), and will not be detailed here.

2.4.2 The Surfatm model

The Surface-Atmosphere (Surfatm) model combines an energy budget model (following Choudhury and Monteith, 1988) and a pollutant exchange model (following Nemitz et al., 2001), which allows distinction between the soil and the plant exchange processes. As in Zhang2010, the scheme is based on the traditional resistance analogy describing the bidirectional transport of NH₃ governed by a set of resistances R_a, R_b, and R_c (Hansen et al., 2017, and references therein) already described in the preceding paragraph. Surfatm includes a diffusive resistance term from the topsoil layer to the soil surface. Surfatm represents a comprehensive approach to study pollutant exchanges and their link with plant and soil functioning. The NH₃ exchange is directly coupled to the energy budget, which determines the leaf and surface temperatures, the humidity of the canopy, and the resistances in the layers above the soil and in the soil itself. This model has been comprehensively described in Personne et al. (2009) and more recently in Hansen et al. (2017).

The model is forced every 3 h by net radiation, deep soil temperature (30 cm), air temperature, relative humidity, wind speed, rainfall, and atmospheric NH₃ concentration with monthly values from passive sampler measurements repeated every 3 h. Forcing also includes values of leaf area index (LAI, measured), canopy height Z_h (estimated), roughness length Z₀ (0.13 Z_h), displacement height D (0.7 Z_h), stomatal emission potential (constant), ground emission potential (derived from measurements during field campaigns, constant the rest of the time), and measurement height Z_ref (2 m). LAI was measured according to the methodology developed in Mougin et al. (2014). Data from Dahra were measured monthly during the wet season and were not published (Mougin, personal communication). Linear interpolation was performed between these monthly estimates, and values for the dry season were found in Adon et al. (2013), for an equivalent semi-arid ecosystem in Mali, derived from MODIS (Moderate-Resolution Imaging Spectroradiometer) measurements. The ground emission potential has been set to 400 (unitless), and the stomatal emission potential has been set to 100 (unitless) as in the simulation based on Zhang2010, except during field campaign periods, where the ground emission potential was derived from experimental values (700 in J12 and J13 and 2000 in N13). In Table 2, constant input parameters are listed. Some of them were adapted to semi-arid conditions to get the best fit between measured and simulated fluxes, specified in Table 2.

Table 2Input parameters for the Surfatm model. Ranges refer to Hansen et al. (2017). All measured parameters refer to Delon et al. (2017).

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The main difference between Surfatm and Zhang2010 is the presence of a SVAT (surface vegetation atmosphere transfer) model in Surfatm (Personne et al., 2009), allowing for energy budget consideration and accurate restitution of surface temperature and moisture. Simulated variables and corresponding measurements used for validation are summarized in Table 1.

4.1.1 Relevance of monthly NH₃ concentration input vs. daily NH₃ flux outputs

In the two models, $C_{{\mathrm{NH}}_{\mathrm{3}}}$ used as input data arises from passive sampler measurements, integrated at the monthly scale (see Sect. 2.2.2). Output fluxes are provided at a 3 h timescale, averaged at the daily scale for the purpose of this study. The relevance of using monthly NH₃ concentrations instead of concentrations with finer resolution in time has already been approached in the literature. Riddick et al. (2014, 2016) have used ALPHA samplers to measure NH₃ concentrations at the scale of the week and/or the month. They have noticed that time-averaged NH₃ fluxes from these samplers provided estimated fluxes similar to those calculated from online sampling. In the case of passive sampling concentration measurements, meteorological and area sources of uncertainty can still be accounted for in the flux calculation. Riddick et al. (2014) conclude that active and passive sampling strategies give similar results, which support the use of low-cost passive sampling measurements at remote locations where it is often logistically hard to deploy expensive active sampling methods for flux measurements. These statements have been confirmed in Loubet et al. (2018), and provide a valuable reason to use monthly concentrations as inputs in the present study.

4.1.2 NH₃ deposition flux variation

Dahra is a grazed savanna where the main source of NH₃ emission to the atmosphere is the volatilization of livestock excreta (Delon et al., 2012); the excreta quantity and quality is at a maximum at the end of the wet season, (Hiernaux et al., 1998; Hiernaux and Turner, 2002; Schlecht and Hiernaux, 2004) because animals are better fed. In August, a strong leaching of the atmosphere occurs, which decreases the NH₃ atmospheric concentration (not shown here), compared to July concentration, and the deposition flux decreases as well. Indeed, if the concentration decreases from July to August whereas the canopy compensation point remains stable, the flux will decrease as shown by Eq. (3).

August is the month with the maximum ammonium wet deposition, which leads to a strong leaching of the atmosphere and explains the decrease in the NH₃ concentration (Laouali et al., 2012).

4.1.3 Role of soil moisture and soil temperature in NH₃ fluxes

A significant correlation is found between Zhang2010 fluxes and measured soil moisture at 5 cm depth (R²=0.6, p<0.01, slope = −1.2, offset = 2.1) for 2012–2013. Surfatm fluxes and measured soil moisture at 5 cm depth are also significantly correlated with R²=0.3, p<0.01, slope = −0.7, offset = 1.7 for 2012–2013, and this correlation is higher if only the dry season is considered (0.7 and 0.5 respectively). A weak but significant correlation is found between Surfatm fluxes and soil surface temperature (R²=0.2, p<0.001, slope = 0.14, offset = 33.9) for both wet seasons, whereas it is not found with Zhang2010 fluxes. An explanation may be that the NH₃ exchange in Surfatm is directly coupled with the energy balance via the surface temperature (Personne et al., 2009). A stepwise multiple linear regression analysis was performed between Zhang2010 fluxes and NH₃ ambient concentrations, air humidity, wind speed, and soil surface temperature and moisture, for both years of simulation. The model selection was performed by adding each variable step by step, i.e. the best combination was chosen with the best associated significant R² (p<0.05). The resulting model gives a R² of 0.9 (p<0.001), showing a large interdependence of the above-cited parameters on NH₃ fluxes, whereas the correlation between NH₃ fluxes and each individual parameter is not significant. While the isolated soil temperature effect is not demonstrated, these complex interactions between influencing parameters suggest that the contribution of soil temperature to NH₃ fluxes, together with other environmental parameters, becomes relevant.

As for Zhang2010 fluxes, a stepwise multiple linear regression analysis is run between Surfatm NH₃ fluxes and NH₃ concentrations, air humidity, wind speed, soil surface temperature, and latent heat fluxes. R² is 0.6 with p<0.001. The nested influences of environmental parameters in Surfatm are highlighted. These interactions become more complex with the energy balance effect, but may be more accurate in representing the partition between surface and plant contributions.

4.1.4 Contribution of soil and vegetation to the net NH₃ flux

In Surfatm, during the wet season, deposition on the vegetation through stomata and cuticles dominates the exchange. Indeed, during rain events, the cuticular resistance becomes small and cuticular deposition dominates despite an increase in soil emission. This increase is due to an increase in the deposition velocity of NH₃, after the humidity response of the surface, and a decrease in the canopy compensation point, sensitive to the surface wetness (Wichink-Kruit et al., 2007). In Zhang2010, despite the difference in magnitude, cuticular deposition increases as well during the wet season, but is dominated by deposition on the soil.

During the dry season, aboveground herbaceous dry biomass stands for a few months after the end of the wet season when the soil becomes bare, and the vegetation effect is negligible in both models. At the end of wet season 2013, the soil contribution to the total flux increases significantly in Surfatm due to the increase in the ground emission potential prescribed at 2000 (instead of 400 for the rest of the year, to be consistent with measurements noted in Delon et al., 2017).

4.1.5 Surfatm versus Zhang2010 NH₃ bidirectional models

The two models are based on the same two-layer model approach developed in Nemitz et al. (2001). In the two models, the ground emission potential and the NH₃ ambient concentrations are prescribed. The comparison of modelled and measured flux values in Fig. 9 shows differences, especially for results predicted by Zhang2010. This is partly because in Surfatm the ground emission potential varies with time and was specifically modified for the field campaign periods, whereas this parameter does not vary in Zhang2010. The lack of variability of the ground emission potential in Zhang2010 highlights the sensitivity of fluxes to this specific parameter for 1-D modelling in semi-arid soils. The abrupt transitions between seasons need a certain flexibility of the ground emission potential to represent the changes in flux direction.

In Surfatm, the temperatures (above and in the soil) are calculated through the sensible heat flux; the humidity and evaporation at the soil surface are calculated through the latent heat flux. The resistances needed for the compensation point concentration and for the flux calculation are deduced from the energy budget. This allows us to simultaneously take into account the role of temperature and humidity of the soil. In Zhang2010, the R_a, R_b, and R_c resistances are calculated directly from the meteorological forcing, and the soil resistance is prescribed. Again, the flexibility of this parameter is more adapted than fixed values for 1-D modelling, and this may lead to completely different repartitions of the fluxes between the soil and the vegetation, as shown in Fig. 10. This difference in flux repartition highlights the importance of the choice in the type of soil and/or vegetation for the simulations.

However, the close correlation between both models (R²=0.5, p<0.01, slope = 0.6, offset = 0.4) indicates a similar representation of the net flux in each model and emphasizes clear changes at the transition between seasons.