1 of 2

Nitrogen Cycle in the Soil

The three major forms of nitrogen in mineral soils are organic nitrogen associated with humus, mineral forms of nitrogen held by soil colloids, and mineral forms of nitrogen in solution. Nitrogen may be added to the soil by fertilizer, manure or residue application, fixation by symbiotic or nonsymbiotic bacteria, and rain. Nitrogen is removed from the soil by plant uptake, leaching, volatilization, denitrification and erosion. Figure 3:1-1 shows the major components of the nitrogen cycle.

Nitrogen is considered to be an extremely reactive element. The highly reactive nature of nitrogen results from its ability to exist in a number of valance states. The valence state or oxidation state describes the number of electrons orbiting the nucleus of the nitrogen atom relative to the number present in an electronically neutral atom. The valence state will be positive as the atom looses electrons and will be negative as the atom gains electrons. Examples of nitrogen in different valence states are:

The ability of nitrogen to vary its valence state makes it a highly mobile element. Predicting the movement of nitrogen between the different pools in the soil is critical to the successful management of this element in the environment.

Figure 3:1-2: SWAT+ soil nitrogen pools and processes that move nitrogen in and out of pools.

Initialization of Soil Nitrogen Levels

Users may define the amount of nitrate and organic nitrogen contained in humic substances for all soil layers at the beginning of the simulation. If the user does not specify initial nitrogen concentrations, SWAT+ will initialize levels of nitrogen in the different pools.

Initial nitrate levels in the soil are varied by depth using the relationship:

$NO3_{conc,z}=7*exp(\frac{-z}{1000})$ 3:1.1.1

where $NO3_{conc,z}$ is the concentration of nitrate in the soil at depth $z$ (mg/kg or ppm), and $z$ is the depth from the soil surface (mm). The nitrate concentration with depth calculated from equation 3:1.1.1 is displayed in Figure 3:1-3. The nitrate concentration for a layer is calculated by solving equation 3:1.1.1 for the horizon’s lower boundary depth.

Organic nitrogen levels are assigned assuming that the C:N ratio for humic materials is 14:1. The concentration of humic organic nitrogen in a soil layer is calculated:

Nitrogen in the fresh organic pool is set to zero in all layers except the top 10 mm of soil. In the top 10 mm, the fresh organic nitrogen pool is set to 0.15% of the initial amount of residue on the soil surface.

While SWAT+ allows nutrient levels to be input as concentrations, it performs all calculations on a mass basis. To convert a concentration to a mass, the concentration is multiplied by the bulk density and depth of the layer and divided by 100:

Table 3:1-1: SWAT+ input variables that pertain to nitrogen pools.

Initialization of Soil Nitrogen Levels

Initial nitrate levels in the soil are varied by depth using the relationship:

$NO3_{conc,z}=7*exp(\frac{-z}{1000})$ 3:1.1.1

Organic nitrogen levels are assigned assuming that the C:N ratio for humic materials is 14:1. The concentration of humic organic nitrogen in a soil layer is calculated:

$orgN_{hum,ly}=10^4*(\frac{orgC_{ly}}{14})$ 3:1.1.2

where $orgN_{hum,ly}$ is the concentration of humic organic nitrogen in the layer (mg/kg or ppm), and $orgC_{ly}$ is the amount of organic carbon in the layer (%). The humic organic $N$ is partitioned between the active and stable pools using the following equations:

$orgN_{act,ly}=orgN_{hum,ly}*fr_{actN}$ 3.1.1.3

$orgN_{sta,ly}=orgN_{hum,ly}*(1-fr_{actN})$ 3:1.1.4

where $orgN_{act,ly}$ is the concentration of nitrogen in the active organic pool (mg/kg), $orgN_{hum,ly}$ is the concentration of humic organic nitrogen in the layer (mg/kg), $fr_{actN}$ is the fraction of humic nitrogen in the active pool, and $orgN_{sta,ly}$ is the concentration of nitrogen in the stable organic pool (mg/kg). The fraction of humic nitrogen in the active pool, $fr_{actN}$ , is set to 0.02.

$orgN_{frsh,surf}=0.0015*rsd_{surf}$ 3:1.1.5

where $orgN_{frsh,surf}$ is the nitrogen in the fresh organic pool in the top 10 mm (kg N/ha), and $rsd_{surf}$ is material in the residue pool for the top 10 mm of soil (kg/ha).

The ammonium pool for soil nitrogen, $NH4_{ly}$ , is initialized to 0 ppm.

$\frac{conc_N*\rho_b*depth_{ly}}{100}=\frac{kgN}{ha}$ 3:1.1.6

where $conc_N$ is the concentration of nitrogen in a layer (mg/kg or ppm), $\rho_b$ is the bulk density of the layer (Mg/m $^3$ ), and $depth_{ly}$ is the depth of the layer (mm).

Table 3:1-1: SWAT+ input variables that pertain to nitrogen pools.

Variable Name

Definition

Input File

Nitrogen Cycle in the Soil

SWAT+ monitors five different pools of nitrogen in the soil (Figure 3:1-2). Two pools are inorganic forms of nitrogen, NH4+ and $NO_3^-$ , while the other three pools are organic forms of nitrogen. Fresh organic N is associated with crop residue and microbial biomass while the active and stable organic N pools are associated with the soil humus. The organic nitrogen associated with humus is partitioned into two pools to account for the variation in availability of humic substances to mineralization.

Figure 3:1-2: SWAT+ soil nitrogen pools and processes that move nitrogen in and out of pools.