Wissem Hamdi 1 and Faten Gamaoun 2 and David E. Pelster 3 and Mongi Seffen 4
Recommended by Marco Trevisan
1, High Institute of Agronomy, Sousse University, Chott Meriem, 4042 Sousse, Tunisia
2, Applied Chemistry and Environment Research Unit, EPAM, 4000 Sousse , Tunisia
3, International Livestock Research Institute, P.O. Box 30709, Nairobi, Kenya
4, Laboratory of Energy and Materials (LABEM), High School of Sciences and Technology, Sousse University, 4011 Hammam Sousse, Tunisia
Received 6 March 2013; Revised 9 June 2013; Accepted 25 June 2013
This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
1. Introduction
Nitrogen (N) is a critical nutrient needed by all plants for growth [1]. Input of inorganic N as a fertilizer is considered essential in modern agriculture in order to satisfy the dietary needs of a growing world population. Nitrate ( NO 3 - ) is the one of the principal N forms taken up by plants. As such, inorganic N is widely used in agriculture and numerous studies have suggested that leaching of NO 3 - following high input rates of chemical fertilizer and due to mineralization of organic N already present in the soils can cause degradation of surface and groundwater quality. Excess NO 3 - contaminated water supplies have been linked to outbreaks of infectious disease [2]. Also, NO 3 - can be converted to nitrite in the digestive tracts of infants and ruminant animals, which then combines with blood hemoglobin, reducing its ability to carry oxygen, occasionally leading to death. The ability of soil to adsorb anions can reduce NO 3 - leaching to the deeper horizons and maximize the NO 3 - available for plant nutrition and can thus play a fundamental role in enhancing soil nutrition in regions, such as Mediterranean areas, where NO 3 - availability is often a limiting factor [3]. Previous studies have reported the sorption of NO 3 - by soils [4, 5]. However, NO 3 - mobility in soils is mainly controlled by a number of soil properties including iron and aluminum oxide concentrations [6], organic matter content [7], pH of soil solutions [8], and soil texture and clay mineralogy [9]. Other studies suggested that sorption of NO 3 - was influenced by the competition with other anions as Cl - [10]. Qafoku et al. [11] reported that NO 3 - sorption was directly related to NO 3 - concentration in the soil solution.
The NO 3 - sorption process has been studied in many different soil orders in tropical latitudes [12], including Oxisols [13] as well as in ultisols of the southeastern and mid-Atlantic United States [14] and in forest soils of the American northwest [15]. However, none of these investigated NO 3 - dynamics for the soils of Tunisia, in particular the soils of the Sousse region, which is considered to be one of the most important crop production areas in Tunisia. The aim of this study was to investigate the NO 3 - sorption capacity of these soils by soil depth.
2. Materials and Methods
2.1. Site Description
Soil samples were collected from a citrus orchard at the High Agronomic Institute of Chott Meriem Sousse, (35°54[variant prime]N10°36[variant prime]E) on 1 June 2011. The climate is Mediterranean and is characterized by hot dry summers and moderate wet winters, an average annual precipitation of 230 mm and a mean annual temperature of 18.5°C. Ammonium nitrate fertilizer is applied annually at a rate of 200 kg N ha-1 . The soils are medium-textured brown iso-humic [16], with an average infiltration rate of 45 mm h-1 .
2.2. Chemical Analysis
Four soil pits were sampled to a depth of 120 cm and separated into four depths: 0-25, 25-60, 60-90, and 90-120 cm. Samples were air-dried and ground to pass a 2 mm sieve. Soil pH was determined in 1 : 2 soil : water suspension [17]; organic matter (OM) determined by the wet oxidation method (Walkley and Black); particle-size distribution by the pipette method [18]; cation exchange capacity (CEC) by the BaCl2 extraction method [19]. Mehlich-III [20], P, Ca, Mg, Fe, Al, Cd, Cu, and Mn were determined by equilibrating 2.5 g of air-dried soil sample with 25 mL of Mehlich-III extracting solution for 5 min and filtering through Whatman no. 40 filter paper. The different concentrations in the extracts were measured using an inductively coupled plasma optical emission spectrometer (Perkins Elmer, Model 4300DV). Soil N- NO 3 - and N- NH 4 + concentrations were analysed using the steam distillation method [21].
2.3. Batch Study
The NO 3 - sorption on the iso-humic soil of Chott Meriem was studied as a function of the soil to soil-solution NO 3 - ratio. Nitrate sorption in each horizon was determined via batch equilibration techniques adapted from [14]. The following soil: solution ratios (1%, 12.5%, 25%, and 50%) have been proposed in the literature [22] and were used in this study. The concentration of the solution was 100 mg NO 3 - L-1 . The temperature was 20°C. Briefly 5 g of air-dried soil from each soil subsample was equilibrated with 100 mL of NO 3 - solution. Two drops of toluene were added to each mixture to prevent any biological NO 3 - transformations. Equilibration was estimated to have occurred after the mixture was shaken on a reciprocal shaker at 20°C for 1 h at a rate of 100 oscillations/min. After equilibration the mixtures were centrifuged at 5000 rpm for 10 min and the NO 3 - concentration of the supernatant was determined immediately using a spectrophotometer at 220 nm.
The amount of adsorption at equilibrium Q e (mg g-1 ) was calculated by [figure omitted; refer to PDF] where C i and C e (mg L-1 ) are the liquid-phase concentrations of NO 3 - at initial conditions and at equilibrium, respectively. V is the volume of the solution (L). M is the mass of dry adsorbent used (g).
3. Results and Discussion
3.1. Soil Properties
The main soil properties thought to influence NO 3 - sorption and movement are provided in Table 1. The pH for these soil horizons were all above 8, while soil texture varied between fine sandy loam and sandy clay loam in the two first horizons (0-25 cm) and (25-60 cm) and clay and sandy clay loam, for the two next deeper horizons (60-90 cm and 90-120 cm), respectively. The variation in texture reflected the differences in parent materials [23]. Clay content, which tended to increase with depth, can affect soil fertility and water and nutrient holding capacities as well as plant root movement [24]. The organic matter content for the different soils horizons showed a similar pattern to the clay, where the concentrations tended to increase in the deeper horizons (Table 1). It has been reported that NO 3 - mobility is often related to the organic matter content and could be due to the higher cation exchange capacity [25]. The amount of exchangeable cations differed markedly; Ca 2 + concentrations were high in the different horizons and tended to increase at depth. The inverse can be seen for other exchangeable cations such K+ and Fe2+ where concentrations were moderate and decreased with increasing depth. For the other ions there were no distinct patterns in terms of the amount and distribution within the different horizons of the soil profile.
Table 1: Physiochemical properties of iso-humic soil from Chott Mariam.
| Depths | |||
| 0-25 cm | 25-60 cm | 60-90 cm | 90-120 cm |
pH | 8.12 | 8.41 | 8.56 | 8.54 |
CEC (meq/100 g of soil) | 19.72 | 22.04 | 23.45 | 23.45 |
OM (%) | 0.7 | 0.9 | 1.1 | 1.3 |
Total C (mg kg-1 ) | 10988 | 8255 | 20988 | 27093 |
Total N (mg kg-1 ) | 900 | 540 | 510 | 260 |
N-NO3 (mg kg-1 ) | 86.47 | 36.15 | 169.25 | 38.21 |
N-NH4 (mg kg-1 ) | 6.68 | 3.29 | 3.57 | 3.39 |
Exchangeable P (mg kg-1 ) | 93.68 | 20.9 | 4.12 | 4.99 |
Exchangeable Na (mg kg-1 ) | 57.5 | 232.3 | 533.6 | 124.2 |
Exchangeable Al (mg kg-1 ) | 76.68 | 87.23 | 72.79 | 51.55 |
Exchangeable Ca (mg kg-1 ) | 5450.38 | 5508.61 | 5874.56 | 17306.04 |
Exchangeable K (mg kg-1 ) | 491.23 | 299.77 | 135.49 | 106.61 |
Exchangeable Mg (mg kg-1 ) | 410.16 | 433.23 | 356.83 | 461.68 |
Exchangeable Mn (mg kg-1 ) | 59.16 | 52.54 | 22.95 | 4.22 |
Exchangeable Fe (mg kg-1 ) | 33.57 | 24.62 | 9.01 | 3.38 |
Clay (%) | 12.8 | 24.4 | 30.5 | 25.8 |
Silt (%) | 38 | 15.2 | 10 | 15.2 |
Sand (%) | 49.2 | 60.4 | 59.5 | 59.1 |
Texture | Sandy loam | Sandy loam | Clay | Clay loam |
3.2. Effect of Contact Time on NO 3 - Sorption
As shown in Figure 1, the NO 3 - adsorption rate was rapid for the first 60 min and decreased over time. Equilibrium sorption was established after approximately 120 min for NO 3 - ions at an initial concentration of 100 mg L-1 . From the results it can be seen that the contact time required for maximum sorption of NO 3 - by different soil profile was dependent on the initial NO 3 - concentration and on certain soil components, especially the OM and clay content. This behavior suggests that at the initial stage, sorption takes place rapidly on the external surface of the adsorbent followed by a slower internal diffusion process, which may be the rate-determining step. This trend in NO 3 - sorption suggests that the binding may be through interactions with functional groups located on the surface of the soil. According to these results, the contact time was fixed at 120 min for the batch experiments to make sure that equilibrium was attained. The results demonstrated that at a fixed adsorbent dosage, the NO 3 - sorption was higher in deeper horizons than in superficial horizons. The two deepest horizons contained more organic matter, which counterbalances the effect of positive charges of the oxides on NO 3 - sorption. Indeed, organic groups displace water ligands at the positively charged sites on surfaces oxides [26]. As shown in Table 1 the amount of clay increased with depth along with increasing CEC, which enhances the NO 3 - sorption capacity.
Figure 1: Effect of contact time on NO 3 - sorption for 4 soil depths from a batch experiment using an iso-humic soil from Chott Meriam, Tunisia. (Initial conditions for the batch experiment were 100 mg NO 3 - L-1 , 22°C, and 5 g air-dried soil).
[figure omitted; refer to PDF]
3.3. Effect of Soil-Solution Ratios on NO 3 - Sorption
The sorption of NO 3 - on iso-humic soil of Chott Meriem was studied as a function of the soil to soil-solution NO 3 - ratio. The following soil : solution ratios (1%, 12.5%, 25%, and 50%) have been proposed in the literature [22] and used in this study. The experiment was conducted in batch. As shown in Figure 2 there was not a lot of variation between the different depths in the NO 3 - adsorption capacity at a low soil : solution ratio (1%). However, the NO 3 - sorption capacity increased with an increase in the soil : solution ratio. When the ratio increased from 1% to 50%, the NO 3 - sorption capacities increased from 0.0012 to 0.048, 0.0015 to 0.051, 0.0016 to 0.0525, and 0.0018 to 0.054 for the 0-25, 25-60, 60-90, and 90-120 cm depths, respectively. These observations infer that increasing soil : solution ratios play a major role in the increasing NO 3 - sorption capacity by the soils, similar to results obtained by Qafoku et al. [11]. It can be noted that the ratio increases as the mass of soil increases. It has been suggested that increased soil mass causes increased variable charges in the solution and consequently increased sorption of NO 3 - . Furthermore, it was reported that NO 3 - mobility was often related to the active components of organic matter and the clay-sized fractions [27], likely due to the resulting increase in CEC [25].
Figure 2: Effect of soil-solution ratios on NO 3 - sorption for 4 soil depths from a batch experiment using an iso-humic soil from Chott Meriam, Tunisia (soil/solution ratios: 1%, 12.5%, 25%, and 50%, 22°C, 24 h).
[figure omitted; refer to PDF]
3.4. Effect of Initial NO 3 - Concentration on NO 3 - Sorption
Seeing that the initial NO 3 - concentration in solution provides an important driving force to overcome mass transfer limitations of NO 3 - between aqueous and solid phases, a higher initial NO 3 - concentration will increase the sorption process. The effect of initial NO 3 - concentration on NO 3 - sorption for all soil depths was investigated in the following concentrations (25, 50, 75, 100, 125, and 150 mg NO 3 - L-1 ). Figure 3 shows the change of the equilibrium sorption capacity of soil samples with different initial NO 3 - concentrations. It was observed that the amount of sorbed NO 3 - at equilibrium increased with increasing initial NO 3 - concentration for all soil horizons, although rates differed according to the soil layer.
Figure 3: Effect of initial NO 3 - concentration on NO 3 - sorption for 4 soil depths from a batch experiment using an iso-humic soil from Chott Meriam, Tunisia (25, 50, 75, 100, 125, and 150 mg L-1 , 22°C, 24 h, and soil mass = 5 g).
[figure omitted; refer to PDF]
Many previous works reported that at low concentration, more NO 3 - is sorbed by the soil than is left in solution. There is some controversy concerning the mechanism of NO 3 - adsorption at low concentration in soil. Toner et al. [28] proposed a totally reversible adsorption, which is a simple electrostatic retention (i.e., the adsorption is the result of van der Waals type interactions). On the contrary, Qafoku et al. [11] explained the adsorption as an overlapping or interpenetration of double layers around positively charged Al-polymers and negatively charged silicate minerals.
Below concentrations of 100 mg NO 3 - L-1 , NO 3 - sorption was low in the top horizon (0-25 cm), higher in the 25-60 cm horizon, and peaked within the 60-90 cm and 90-120 cm depths. Above concentrations of 125 NO 3 - mg L-1 , the slope of the curves decreased. This decline in NO 3 - sorption with increased initial concentrations in all soil depths is likely due to the weakening of attractive forces between NO 3 - and the soil matrix as well as desorption of other anions (e.g., P) as suggested by Strahm and Harrison [15].
3.5. Adsorption Equilibrium and Isotherms
To facilitate the estimation of the NO 3 - sorption capacities of the soils at the following concentrations (25, 50, 75, 100, 125, and 150 mg NO 3 - L-1 ), the experimental data were fitted to the Freundlich and Langmuir equilibrium adsorption isotherm models. The Langmuir equation is as follows: C e / Q e = 1 / Q m b + C e / Q m , where C e is the equilibrium concentration of NO 3 - in the solution (mg/L), Q e the amount of NO 3 - sorbed per unit weight of soil (mg kg-1 ), and Q m and b are the Langmiur constants signifying the sorption capacity of the adsorbent and energy of the sorption process, respectively. The sorption data was plotted (Figure 4), and Q m and K L (listed in Table 2) were calculated from the intercept and the slope of the plots.
Table 2: Langmuir and Freundlich parameters for sorption of NO 3 - on four depths of iso-humic soil from Chott Mariam, Tunisia.
|
| Depths | |||
|
| 0-25 cm | 25-60 cm | 60-90 cm | 90-120 cm |
Langmuir parameters | Q (mg/g) | 0.153 | 0.134 | 0.144 | 0.121 |
K L (L/mg) | 0.0031 | 0.0041 | 0.0046 | 0.0068 | |
R 2 | 0.89 | 0.95 | 0.93 | 0.97 | |
| |||||
Freundlich parameters | K F | 0.00086 | 0.001 | 0.0012 | 0.002 |
n | 1.23 | 1.27 | 1.28 | 1.44 | |
R 2 | 0.99 | 0.99 | 0.98 | 0.99 |
Figure 4: Langmuir isotherms for NO 3 - sorption by soil profile at (25, 50, 75, 100, 125, and 150 mg NO 3 - L-1 , 22°C, 24 h, and soil mass = 5 g).
[figure omitted; refer to PDF]
The Langmuir equation characterized the NO 3 - sorption data fairly well, with R 2 values between 0.89 and 0.97 for the different soil horizons (Table 2). The adjusted R 2 values suggest that the Langmuir isotherm provides a good model of the sorption system only for the 25-60 cm and 90-120 cm horizons. In this work, it appears that the Q m was greatest in the surface horizon and tended to decrease with depth. However, K L increased with depth, which suggests that not all inorganic sites may be available for NO 3 - binding [15].
The Freundlich equation is as follows: ln ( q e ) = ln ( K F ) + ( 1 / n ) ln ( C e ) , where q e is the amount of NO 3 - per gram of soil at the equilibrium, C is the NO 3 - concentration in solution at the equilibrium, and K and n are the empirical constants indicating the adsorption capacity and adsorption intensity, respectively. Figure 5 shows the plot of ln ( q e ) versus ln ( C e ) , enabling the constants K and n to be determined from the intercept and slope, respectively (Table 2). The R 2 values for the Freundlich isotherm model were greater than those from the Langmuir model (Table 2). The values of n for all soil samples were found to be nearly similar at all depths, indicating reasonable sorption of NO 3 - onto soil samples at the concentration studied, as is evident from Table 2. Additionally it can be also shown that the values of ( K F ), which is a measure of the degree of sorption, decrease at greater depths, consistent with previous studies [15].
Figure 5: Freundlich isotherms for NO 3 - sorption by soil profile at (25, 50, 75, 100, 125, and 150 mg NO 3 - L-1 , 22°C, 24 h, and soil mass = 5 g).
[figure omitted; refer to PDF]
4. Conclusion
In this study, the sorption of NO 3 - from aqueous solutions onto alkaline soils of the Chott Meriem region was examined. The results indicated that the soil NO 3 - sorption capacity of different horizons was affected by the ratio of the soil mass and solution volume, the initial NO 3 - concentration, and the contact time. The amount of NO 3 - sorbed on soils increased with depth. However, a considerable amount of NO 3 - in the soil was not sorbed by the soil and, thus, it is expected that the majority of NO 3 - in excess of biological immobilization rates will be transported through the soils into ground or surface waters. Also, although both Langmuir and Freundlich isotherm models were used to describe the sorption behavior of NO 3 - on soil samples, the Freundlich adsorption isotherm model better described the NO 3 - sorption in this soil profile.
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Copyright © 2013 Wissem Hamdi et al. Wissem Hamdi et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Abstract
Increasing concentrations of [superscript] [subscript] NO 3 [/subscript] - [/superscript] in surface water and groundwater can cause ecological and public health effects and has come under increased scrutiny by both environmental scientists and regulatory agencies. For many regions though, including the Sahel of Tunisia, little is known about the [superscript] [subscript] NO 3 [/subscript] - [/superscript] sorption capacity of soils. In this project we measured [superscript] [subscript] NO 3 [/subscript] - [/superscript] sorption by a profile of an iso-humic soil from Chott Meriem, Tunisia. Soil samples were collected from four soil depths (0-25, 25-60, 60-90, and 90-120 cm) on 1 June 2011, and their sorption capacity was determined using batch experiments under laboratory conditions. The effects of contact time, the initial concentration, and the soil-solution ratio on [superscript] [subscript] NO 3 [/subscript] - [/superscript] sorption were investigated. In general, the results suggested that [superscript] [subscript] NO 3 [/subscript] - [/superscript] was weakly retained by the Chott Meriem soil profile. The quantity of [superscript] [subscript] NO 3 [/subscript] - [/superscript] sorption increased with depth, contact time, initial concentration, and soil-solution ratios. To evaluate the sorption capacities of the soil samples at concentrations ranging between 25 and 150 mg L-1 experimental data were fitted to both Freundlich and Langmuir isotherm sorption models. The results indicated that Freundlich model was better for describing [superscript] [subscript] NO 3 [/subscript] - [/superscript] sorption in this soil profile.
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