The Influence of Continuous Organic Manure Application on Chemical Properties and Organic Carbon of Cultivated Soils

ElMalek, AbdElRahman Saad

doi:10.21608/jalexu.2015.161559

The Influence of Continuous Organic Manure Application on Chemical Properties and Organic Carbon of Cultivated Soils

Document Type : Research papers

Author

AbdElRahman Saad ElMalek

Soil Sciences Department, College of Food & Agricultural Sciences, King Saud University, P.O. Box 2460, Riyadh 11451, Kingdom of Saudi Arabia

10.21608/jalexu.2015.161559

Abstract

A study was conducted to determine the effects of short- and long-term application of organic manure on soil chemical properties including soil pH, EC, CaCO₃, SOC, and soil available N and P under arid conditions. The solid and liquid organic manure were applied to the soils cropped with the vegetable for either up to 2-years under vegetable plants or 15-years to soils cropped with fruit trees. Soil samples were collected at sampling depths of 0-15, 15-30, 30-45, 45-60 cm. Results showed that the soil organic carbon (SOC) content ranged between 0.6-12 g kg^-1 and 1.7-31.5 g kg^-1 after organic manure application for one year and 15-years in soil samples cropped with fruit trees, respectively. Moreover, SOC content ranged between 0.6 and 6.4 g kg-1 and 0.9 and 8.6 g kg^-1 after organic manure application for the one year and 2-years in soil samples cropped with vegetable, respectively. The highest soil available N (211 mg kg^-1) was found after long term application of organic manure (15-years) followed by that (162 mg kg^-1) found after the 2-years organic manure application. The higher soil available P (52-60.2 mg kg^-1) was also found with 15-years and 2-years application of organic manure. It could be concluded that the addition of organic manure to the soil of arid condition may be suitable for maintaining soil organic carbon and improving soil fertility by increasing N and P availability.

Keywords

Main Subjects

Soil science

Full Text

Introduction

Among the soils used for agriculture in arid conditions are the calcareous sandy soils. In calcareous soil, the high content of CaCO₃ and high soil pH could reduce the availability of nutrients to plants (Wassif et al., 1995). Amelioration of these soils is a must to improve their productivity. In this context, the use of soil conditioners like organic wastes could be practiced for this purpose. The use of organic manures with high organic matter, N and P contents may improve soil properties for agricultural use (Wassif et al., 1995; Morera et al., 2002; Bouajil and Sana, 2011; Diacono and Montemurro, 2010; Miller and Miller, 2000).

Soil quality is a complex characteristic and is determined by the physical, chemical and biological components of the soil (Manna et al., 2005; Johansson et al.,1999). Changes in soil physico-chemical and biological characteristics are considered good indicators of soil quality. The fact is that soil chemical and biological properties change when soil organic carbon content is increased due to organic amendments (Diacono and Montemurro, 2010; Bouajil and Sana, 2011). There is evidence that organic residues can improve soil fertility by increasing nutrient availability (Bouajil and Sana, 2011). In soils, impact of addition of organic amendments on SOC and nutrients availability was investigated by several authors (Richard et al., 1995; Hue 1991; Hou et al., 2012). Organic manure will maintain soil organic carbon as well as add N and other nutrients to the soils for agronomic crops (Triberti et al., 2008). Additionally, organic amendments may increase the solubility and availability of P in soils (Hue, 1991; Iyamuremy et al., 1996a; 1996b; 1996c).

Assessment of dynamics of soil organic carbon (SOC) and chemical soil properties under arid conditions after long term application of organic manure can help to draw the useful conclusion for their contribution. There is currently no available information about the effects of the long term application of organic manure on SOC and chemical soil properties in arid conditions in Saudi Arabia. Therefore, the objective of this study was to determine effects of the short and long term application of organic manure on soil chemical properties including soil pH, EC, CaCO₃, SOC, and soil available N and P under arid conditions.

Materials and Methods

The study area is located in the northern part of Saudi Arabia at Al Juaf (lat 29' 49" N, long 39' 52" E). According to Soil Survey Staff (2006), the area was classified as Aridic-Hyperthermic zone. The solid organic manure was applied to the soils for either up to 2 years under vegetable crops or 15 years under fruit trees. Soil samples were collected at sampling depths of 0-15, 15-30, 30-45, 45-60 cm. The disturbed surface and subsurface soil samples for physico-chemical analyses as well as the total content of organic carbon were collected from soil profiles under fruit trees or vegetable plants. All soil samples were air-dried at room temperature (20-22^oC) and ground to pass through a 2-mm sieve. The particle size distribution was determined by the pipette method (Gee and Bauder, 1994). Soil texture is ranging between sand and sandy clay loam. Soil chemical properties were measured according to standard methods (Sparks 1996). Soil pH was measured using a glass electrode in a suspension of saturation soil paste. Electrical conductivity (EC) was measured in the soil extracts of saturation soil paste. Calcium carbonate content was determined using a calcimeter. The soil organic matter was measured according to Nelson and Sommers (1996). Soil available inorganic N (NH₄-N and NO₃-N) was determined according to Keeney and Nelson(1982). Also, ammonium bicarbonate extractable phosphorus was determined colorimetrically according to Soltanpour and Workman (1979).

Statistical analysis

The values of mean are calculated. The statistical analysis was performed by using Statistica for Windows Statistical Software (StatSoft, 1995).

Results and Discussion

Effects of organic manure on soil chemical properties

Table 1 shows the average values of the measured soil chemical properties as affected by organic manure application. In addition, table 2 shows significance at the 0.05 and 0.01 probability levels. The pH values of soil samples ranged between 7.94 and 8.85 in soil samples of fruit trees and between 8.00 and 8.85 in samples of vegetables soils (Table 1). The high values of soil pH may be attributed to the high free CaCO₃ content in soil.

The EC values ranged between 0.002 and 0.461 dSm^-1 in soil samples of fruit trees and between 0.098 and 0.379 dSm^-1 in soil samples of vegetable crops (Table 1). Generally, the EC values were lower at surface layers after short term of organic manure application than those after long-term of organic manure application. This suggests that the continuous application of organic manure, for long time, may be responsible for the increasing soil salinity. However, these increases in EC did not reach to the high levels that may be responsible for damaging plants. The results also indicated that the long-term application (15-years) of organic manure showed lower EC values than the short-term application (1-year) with increasing sampling depth of fruit soils. One possible reason is that the long term of organic manure application may lead to enhance root growth of fruits trees, resulting in depletion of nutrient and solutes from lower depths and subsequently decreasing soil salinity. The CaCO₃ contents ranged between 3.8 and 8.40% in soil samples of fruit trees and between 3.2 and 9.2% in soil samples of vegetable soils (Table 1). It was observed that there are significant differences in pH, EC and CaCO₃ content values between 1-year and 15-years application under fruit trees and between 1-year and 2-years under vegetable crops of the surface layer (Table 2). This can be explained by the effects of organic manure on soil physico-chemical properties.

Table (1). Soil chemical properties of the soil profile under fruit trees and vegetable crops

Soil depth	Under Fruit Trees						Under Vegetables
	1-year Application			15-years Application			1-year Application			2-years Application
	pH	EC_e	CaCO₃	pH	EC_e	CaCO₃	pH	EC_e	CaCO₃	pH	EC_e	CaCO₃
0-15	8.22	0.002	8.40	8.28	0.269	7.10	8.30	0.23	9.20	8.28	0.258	8.30
15-30	8.82	0.183	8.10	8.85	0.141	8.20	8.00	0.379	7.30	8.39	0.158	7.10
30-45	8.47	0.461	4.10	7.94	0.002	6.10	8.68	0.122	4.50	8.34	0.190	5.10
45-60	8.64	0.189	4.60	8.15	0.002	3.80	8.69	0.098	3.90	8.85	0.098	3.20

Table (2). Summary statistics showing significance at 0.05 and 0.01 probability levels

.Effects/property	pH	EC	CaCO₃	OC	Soil available N	Soil available P
Under fruit trees
Depth (1-year Application )	**	**	**	**	**	**
Depth (15-years Application )	**	**	**	**	**	**
Year (0-15 cm depth)	*	*	**	**	**	**
Year (15-30 cm depth)	NS	**	NS	NS	**	*
Year (30-45 cm depth)	**	**	**	**	NS	NS
Year (45-60 cm depth)	NS	**	**	NS	NS	NS
Under vegetable crops
Depth (1-year Application )	NS	**	**	**	**	**
Depth (2-years Application)	**	**	**	**	**	**
Year (0-15 cm depth)	**	**	**	**	**	**
Year (15-30 cm depth)	NS	**	**	**	**	NS
Year (30-45 cm depth)	NS	**	**	NS	NS	NS
Year (45-60 cm depth)	NS	NS	**	**	NS	NS
NS: not significant; * significant at p < 0.05; ** significant at p < 0.01

Effects of organic manure on OC content and distribution of soil profile

Soil organic matter plays a major role in the improvement of soil physical, chemical and biological properties. It has been reported that organic matter of soils (especially of sandy soils) is a very valuable property, mainly due to its high capacity for water and nutrient-holding. Additionally, its decay in soils could provide recycled essential nutrients to plants. Figure 1 shows the average values for measuring SOC as affected by organic manure application. In addition, Table 2 shows significance at the 0.05 and 0.01 probability levels. The results showed that the SOC contents ranged between 0.6 and 12 g kg^-1 after organic manure application for the 1-year and between 1.7 and 31.5 g kg^-1 after manure application for 15-years in soil samples of fruit trees (Figure 1). Moreover, the SOC contents ranged between 0.6 and 6.4 g kg^-1 and 0.9 and 8.6 g kg^-1 after organic manure application for 1-year and the 2-years in soil samples of vegetable crops. It should be mention that the soil organic C content was greater in the surface layer (0–15 cm) than the sub-surface layer (15–30, 30-45 and 45-60 cm) for all treatments. The higher content of SOC content in the surface soil is mainly due to organic manure incorporated in the surface layer. Overall, the higher organic carbon content (31.5 g kg^-1) was pronounced after long-term of organic manure application (15-years) in soil samples under fruit trees. These results indicate that long-term additions of organic manure would have the beneficial effects in building carbon pools in soils of arid conditions. An increase in contents of soil organic carbon in soil amended with manure has been reported by several researchers (Gong et al., 2008; Manna et al., 2005). The increase in nutritional status of soils due to the continuous addition of organic manure can result in an increase of plant residues, which could be accumulated in the surface soil and subsequently it results in higher content of soil organic carbon.

Effects of organic manure on soil available N and P

Figures 2 and 3 show the average values of the amount of available N and P in soils as affected by organic manure application. In addition, Table 2 shows significance at the 0.05 and 0.01 probability levels. Data show that the soil available N ranged between 30 and 67 mg kg^-1 after organic manure application for the first year and between 35 and 211 mg kg^-1 after manure application for the 15 year in soil samples cropped with fruit trees (Figure 2). Moreover, the soil available N ranged between 22 and 62, 50 and 140, and 50 and 162 mg kg^-1 after organic manure application for the five month, the first year and the second year in soil samples cropped with vegetable plants. It should be mentioned that the soil available N was greater in the surface layers (0–15 cm and 15-30 cm) than the sub-surface layers (30-45 and 45-60 cm) layers, which is attributed mainly to organic manure incorporated in the surface layer. Overall, our results showed that the higher soil available N (211 mg kg^-1) was pronounced after long term of organic manure application (15-years) in soil samples cropped with fruit trees followed by that found after the two-years organic manure application to the soil of vegetable plants. An increase in the availability of N in soil amended with manure has been reported by several researchers (Gong et al., 2008; Hou et al., 2012; Eghball, 2000; Zaman et al., 2004). It has been reported that continuous application of compost and non-composted manure increased N mineralization (Eghball, 2000), reflecting on enhancing plant growth. Zaman et al. (2004) reported also that the long-term application of organic amendments resulted in a positive impacts on N mineralization, mainly due to enhancing microbial and enzyme activities.

Fig. (1). Distribution of soil organic carbon (SOC) in soil profile under fruit trees and vegetable crops

Soil available P ranged between 0.5 and 2.8 mg kg^-1 after organic manure application for the 1-year and between 0.9 and 52 mg kg^-1 after manure application for the 15-years in soil samples cropped with fruit trees (Figure 3). Moreover, the soil available P ranged between 1.5 and 9.2, and 0.2 and 60.2 mg kg^-1 after organic manure application for the 1-year and the 2-years in soil samples cropped with vegetable plants. Similar to N, the soil available P was greater in the surface layers (0–15 cm) than the sub-surface layers (15-30 cm, 30-45 cm and 45-60 cm), which is mainly due to organic manure incorporated in the surface layer. Overall, our results showed that the higher soil available P (52-60.2 mg kg^-1) was reported after 15-years and 2-years application of organic manure in soil samples cropped with fruit trees and vegetable plants.

In soil samples of fruit trees, there is significant relationship between soil organic C content and soil available N (r² = 0.57) or soil available P (r² = 0.88) (Figure 4). Moreover, in soil samples cropped with vegetable plants, there is significant relationship between soil organic C content and soil available P (r² = 0.71) (Figure 5). The general factors controlling P solubility and availability in the soil include soil pH, Fe and Al oxides, organic matter, and the presence of other elements such as N, S, and cations. The application of organic materials to calcareous soils can decrease P adsorption, possibly due to competition between P ions and organic anions or retention sites in the soil (Hue, 1991; Iyamuremye et al., 1996a; 1996b; 1996c). Decomposition of organic matter by soil microorganisms also produces CO₂ which dissolves in water to form carbonic acid, increasing the solubility of Ca-P and Mg-P precipitates in alkaline soils.

Fig.(2). Distribution of soil available N in soil profile under fruit trees and vegetable crops

Fig. (3). Distribution of soil available P in soil profile under fruit trees and vegetable crops.

Fig.( 4). Relationship between soil organic carbon (SOC) and soil available N and P in soil samples of fruit trees.

Fig. (5). Relationship between soil organic carbon (SOC) and soil available N and P in soil samples of vegetable crops.

Conclusions

The long-term application of organic manure resulted in greater C sequestration in agricultural soils. In this study, the accumulation of SOC was greater in the surface layer of the soil as compared to subsurface layers. In addition, SOC accumulation, applying organic manure to the soils improved soil fertility by increasing the availability of N and P. However, future study should focus on C fractions that are more sensitive for the changes in SOC. In addition, the effect of the agriculture practices on soil C sequestration should be investigated under arid conditions.

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