Utilization of Liquid Olive Mill Waste and Some Natural Conditioners for Improving Sandy Soil Properties

Khalil, Aly; Abdel Nasser, Gamal; Aly, Wafaa Hassan; Hasham, Abd Allah

doi:10.21608/ajsws.2019.225940

Utilization of Liquid Olive Mill Waste and Some Natural Conditioners for Improving Sandy Soil Properties

Alexandria Journal of Soil and Water Sciences

Volume 3, Issue 2, July 2019, Page 68-87 PDF (1.32 MB)

Document Type: Research papers

DOI: 10.21608/ajsws.2019.225940

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Authors

Aly Khalil¹; Gamal Abdel Nasser²; Wafaa Hassan Aly²; Abd Allah Hasham¹

¹Soil Conservation Dept., Water Resources and Desert Soils Division, Desert Research Center, Cairo, Egypt

²Soil and Agricultural Chemistry Dept., Faculty of Agriculture Saba Basha – Alexandria University

Abstract

ABSTRACT: A field experiment conducted at Gilbana village, Southern El-Qantara Shark, North Sinai, Egypt. The aim of the study was to evaluate the role of olive mill wastewater and some natural conditioners (farmyard manure and K-Feldspar) in improving sandy soil properties. All the three used soil conditioners applied individually and in combination. The experimental design was Randomized Complete Block Design and the cultivated plant was sugarbeet. Results of the present study revealed that the application of all the studied treatments decreased pH and EC values, while increased organic matter content, as well as available N, P and K. On the other hand, such treatments increased microelements concentration of the investigated soil. Importantly, the combined treatment (Olive mill wastewater + Potassium feldspar + Farmyard manure) had the most effective treatment in the present study. Therefore, the application of such treatment to sandy soils is necessary to improve its properties.

Keywords

Keywords: Olive mill wastewater; feldspar; farmyard manure; natural soil conditioner

Full Text

Introduction

Olive mill wastewater (OMWW) is the liquid by-product generated during olive oil production (Mekki et al., 2013). This by-product has a critical environmental problem for the most olive oil producing countries. The problem concern to its large volumes, salinity, low pH, high organic load and toxic and phytotoxic compounds, such as polyphenol (Di Bene et al., 2013; Chaari et al., 2014).

The additions of the olive–mill waste as an organic amendment can improve soil quality and hence mitigate the negative environmental and agronomic limitations of these soils (Lopez-Pineiro et al., 2008). These wastes contain high percentages of organic matter and a vast range of plant nutrients that could reused as fertilizers for sustainable agricultural practices (Roig et al., 2006; Abu Khayer et al., 2013). Also, OMWW application has found to have significant effects on the soil's physical, chemical and biological properties (Saadi et al., 2007; Mechri et al., 2008; Jarboui et al., 2008; Lopez-Pineio et al., 2008; Kavvadias et al., 2010).

Mahmoud et al. (2010) found that the saturated hydraulic conductivity decreased by long-term application of untreated olive mill wastewater, while the soil disposition to water repellency increased. Olive mill wastewater enhanced the total organic content in the soil and increased total extracted carbon, humified organic carbon, available phosphorus and potassium (Montemurro et al., 2011).

Compost farmyard manure with Olive mill wastewater caused a decrease in soil bulk density compared to using olive mill wastewater by approximately 11% (Abd- El Aziz and Mousa, 2017). Compost farmyard manure with olive mill wastewater increased organic matter content more than compost farmyard manure only, and compost farmyard manure was more effective than olive mill wastewater (Abd- El Aziz and Mousa, 2017; Al-Widyan et al., 2005; Paredes et al., 2005).

Feldspar is by far the most abundant range of minerals in the earth's crust, forming about 60% of the earth's rocks. Most deposits provide sodium feldspar as well as potassium feldspar and mixed feldspar. Feldspar primarily used in industrial applications and is used as a soil conditioner. Wahba and Darwish (2008) found that feldspar and compost, individually or mixed, increase the available potassium content in sandy and calcareous soils.

The objective of this present study is to evaluate the role of olive mill wastewater, K-feldspar and farmyard manure as natural soil conditioners in improving sandy soil properties in Gilbana village, southern El-Qantara- shark, North Sinai, Egypt. The effect of the treatments on sugarbeet productivity will illustrated in another paper.

Materials and Methods

A field experiment conducted at Gilbana village, Southern El-Qantara Shark, North Sinai. The studied area is located at latitude 30º 52ˋ 16.8” N and longitude 32º 19ˋ 55.2ˋˋ E, and altitude 6 m (ASL). Map (1) shows the location of Galbana village, south of Al-Qantara Shark area, Egypt. Some physical and chemical characteristics of the experimental soil samples presented in Table (1).The other agronomic practices for sugarbeet cultivation done as recommended at the appropriate time. The experimental design was the Randomized Complete Block design with three replications and the experimental treatments were as follows:

1 - Control (without any conditioner application).

2 - Olive mill wastewater (12.6 m³/fed.).

3 - Potassium feldspar (15 ton/fed.).

4 - Farmyard manure (15 ton/fed.).

5 - Olive mill wastewater (12.6 m³/fed.)+ Potassium feldspar (15 ton/fed.).

6 - Olive mill wastewater (12.6 m³/fed.)+ Farmyard manure (15 ton/fed.).

7 - Potassium feldspar (15 ton/fed.) + Farmyard manure (15 ton/fed.).

8 - Olive mill wastewater (12.6 m³/fed.) + Potassium feldspar (15 ton/fed.) + Farmyard manure (15 ton/fed.).

The conditioners in the combined treatments added at the same rates previously mentioned as the individual ones. The data in Table 2 illustrates some chemical characteristics of such conditioners.

Map (1). Location of Gilbana village, southern El-Qantara Shark area.

The sugar beet plant as test crop harvested after 180 days from sowing date (May 20, 2017). Soil samples representing all treatments taken from two depths; i.e., surface layer (0-30 cm) and subsurface layer (30-60 cm) then prepared for analysis.

Table (1). Some chemical and physical characteristics of the experimental soil

Soil depth (cm)	pH	EC	Ca⁺⁺	Mg⁺⁺	Na⁺	K⁺	CO₃⁼+ HCO₃^-	Cl^-	SO4⁼	SAR	MAR	SSP	ESP	PI	KR
Soil depth (cm)	pH	dSm^-1	Soluble Cations (meq/l)				Soluble anions (meq/l)			-	-	%		-	-
(0:30)	7.95	2.98	7.44	3.67	18.20	0.67	10.00	11.00	8.80	7.72	33.0	60.7	9.2	0.73	1.64
(30:60)	7.65	2.84	8.60	4.30	14.90	0.55	8.00	17.60	2.80	5.87	33.3	52.6	6.88	0.64	1.16

Table (1). Cont.…

Soil depth (cm)	N	P	K	Cu	Fe	Mn	Zn	CaCO₃	O.M	Ks	MWD	GMD	Texture	Cr
Soil depth (cm)	mg/kg							%	%	cm/day	mm	mm		-
(0:30)	224	11.6	64	0.08	1.34	1.62	0.28	7.43	0.07	100	0.35	0.3	SAND	1.48
(30:60)	196	10.4	60	0.07	1.13	5.95	0.28	6.29	0.03	118	0.34	0.3	SAND	1.40

Table (2). Some chemical characteristics of the tested conditioners

Parameters	OMWW	K-Feldspar	Farmyard manure
pH	3.86	7.58	8.00
EC, dS/m	15.63	2.54	12.82
OC,%	19.7	-	16.5
OM, %	33.96	-	28.45
CaCO₃, %	-	14.28	28.57
Total Elements(mg/kg)
N	560	350	11340
P	179.3	73.5	52.55
K	18300	4675	25500
Ca	4890	9532.5	10230
Mg	679.3	3580	3482
Fe	405.4	14898	1565
Mn	43.25	455.25	195.3
Cu	35.55	42.175	32.31
Zn	25.06	132.6	48.69

Soil analysis

Soil physical characters:

The soil samples taken from each treatment after harvesting and analyzed for the following properties:

Soil particle density (Mg/m³) using the Pycnometer method (Carter and Gregorich, 2008).
Soil bulk density (Mg/m³) using the soil core method (Carter and Gregorich, 2008).
Mean weight diameter (MWD) according to Dimoyiannis (2009) method using the following equation:

(1)

Where: di is the mean diameter of any particular size range of aggregates separated by sieving (mm), and fi is the weight of aggregates in that size range as a fraction of the total dry weight of soil used (%).

Geometric mean diameter (GMD) according to the method of Shirazi and Boersma (1984)using the following equation:

(2)

Structure coefficient (Cr) as described by (Pieri, 1992) using the following equation:

(3)

Permeability index (PI) as calculated by the method suggested by Domenico and Schwartz (1990) as follows:

(4)

Where the ion concentrations are in meq/l

Kelley’s ratio (KR) as described by Kelley (1963) as follows:

(5)

Soil water retention at 0.0, 0.1, 0.33, 1, 5, 10, and 15 bar was measured using pressure cooker device and pressure membrane apparatus and soil water constants (FC, PWP and AW) deduced from the values of soil moisture content percentage at different pressures according to van Genuchten’s model (Van Genuchten, 1980):

(6)

Where:

h is the matric suction (cm),

q is the volumetric water content (cm³ cm^-3),

q_s is the saturated water content (cm³ cm^-3),

q_r is the residual water content (cm³ cm^-3),

α is a parameter, the inverse of which, 1/α, is an indication of the suction at the air-entry point (cm^-1), and

n and m are the dimensionless parameters related to the homogeneity of the pore size distribution.

The experimental data for soil water retention fitted to van Genuchten’s model with optimization software RETC (Van Genuchten et al., 1991).

Soil saturated hydraulic conductivity (Ks) was determined using undisturbed soil cores under constant water head in the laboratory following the method recommended by Klute (1986). Darcy’s equation used to calculate the (Ks) value (Richard, 1954).

Soil chemical characters:

Soil pH, Electrical Conductivity (dS/m), soluble cations (meq/l), soluble anions (meq/l), total calcium carbonates (%), and organic matter (%) were determined according to the methods outlined in Carter and Gregorich (2008).
Magnesium Adsorption Ratio (MAR) was calculated by the following formula (Richards, 1954; Eaton, 1950):

(7)

Where: Na⁺, Ca²⁺ and Mg²⁺ contents of soil solution expressed in meq/l.

Sodium Adsorption Ratio (SAR) as calculated by the following formula (Richards, 1954):

(8)

Soluble Sodium Percentage (SSP) was calculated by the following formula (Richards, 1954):

(9)

Exchangeable Sodium Percentage (ESP) was calculated by the following formula (Richards, 1954):

(10)

Soil available nutrients: Soil available macronutrients (N, P and K) and soil available micronutrients (Fe, Mn, Cu and Zn) were determined as follows.
Available nitrogen content (mg/kg): The soil sample was extracted by 2M KCl (1:20), available N was determined in soil extract by using micro- Kjeldahl method described by Paech and Tracey (1956).
Available phosphorus content (mg/kg): Available phosphorus extracted with 0.5 M NaHCO₃ solution and adjusted to pH 8.5 according to Olsen et al. (1954) and determined by ascorbic acid molybdenum blue method according to Jackson (1973).
Available potassium content (mg/kg): available K extracted by ammonium acetate (1N of pH 7.0) and determined by flame photometry according to Jackson (1973).
DTPA-extractable micronutrients: Ten grams of air-dried soil sample shaken with 20 ml of extracting solution (0.005 M DTPA + 0.01 M calcium chloride + 0.1 M TEA, pH 7.3) for two hours. The soil suspension filtered using Watman No. 42 filter paper and the contents of Fe, Mn, Cu and Zn measured by atomic absorption spectrophotometer (Lindsay and Norvell, 1978).

El-Salam Canal irrigation water

Chemical analysis data of the applied irrigation water presented in Table (3). It is clear that such water having pH value of 7.23, which mean that it enriched with soluble alkaline ions. It is also having EC value of 2.60 dS/m and SAR value of 5.75, which mean that, it is in the safe side (less than 10) according to Ayres and Westcot (1985).

Table (3). Chemical analysis data of the applied irrigation water

Parameters	values
pH	7.23
EC (dS/m)	2.60
Soluble cations(me/l)
Na⁺	8.20
K⁺	3.50
Ca⁺⁺	13.90
Mg⁺⁺	0.43
Soluble anions(me/l)
CO₃^--	0.00
HCO₃^-	6.00
Cl^-	15.20
SO₄^--	4.80
SAR	5.75
MAR	29.91
SSP (%)	53.40
ESP (%)	6.73
PI	0.64
KR	1.19

RESULTS and DISCUSSION

Effect of olive mill wastewater and natural conditioners on the tested soil physical properties:

Data in Table (4) illustrated the effect of the applied soil amendments on some physical properties of the soil surface layer. There are no significant differences between treatments on soil bulk density (BD). It can notice significant differences in soil saturated hydraulic conductivity (Ks) and Mean weight diameter (MWD) with LSD equal to 16.82 and 0.0368, respectively. The combined treatment (Olive mill wastewater + Potassium feldspar + Farmyard manure) was the best in this concern, where it showed the lowest Ks value (12.8 cm/day) and the highest MWD value (0.42 mm). Geometric mean diameter (GMD) and Rate of disintegration conducted slight significant differences with LSD 0.0301 and 0.0228, respectively. In addition, the combined treatment (Olive mill wastewater + Potassium feldspar + Farmyard manure) showed the highest GMD value (0.33 mm). The structure coefficient (Cr), Permeability Index (PI) and Kelley’s ratio (Kr) showed a non-significant difference with LSD equal to 0.40, 0.16 and 0.67, respectively. The combined treatment (Olive mill wastewater + Potassium feldspar + Farmyard manure) showed the highest Cr value (1.90), while it showed the lowest values in PI and Kr equal (0.51 and 0.55), respectively. Hunt and Gilkes (1992) reported that, for optimum movement of air and water through the soil, it is generally desirable to have soil with a low bulk density (<1.5 g/cm³).

With respect to the physical properties of soil subsurface layer (Table 5), it can be notice that all the studied parameters took the same trends previously mentioned for soil surface layer, except that Ks showed slight significant differences and Rate of disintegration showed non-significant.

Table (4). Some physical properties for surface layer of the studied soil as affected by the applied soil conditioners

Treatments	BD (g/cm³)	K_s (cm/day)	MWD (mm)	GMD (mm)	Cr	Rate of disintegration	Pi	Kr
Control (T1)	1.56	78.17	0.34	0.29	1.42	0.023	0.70	1.28
OMWW (T2)	1.56	30.87	0.33	0.29	1.43	0.058	0.69	0.98
K- Feldspar (T3)	1.58	54.23	0.41	0.32	1.76	0.044	0.73	1.29
FYM (T4)	1.45	22.67	0.36	0.30	1.70	0.047	0.59	1.10
OMWW+K- Feldspar(T5)	1.56	45.37	0.41	0.33	1.85	0.069	0.59	0.60
OMWW + FYM (T6)	1.55	34.33	0.37	0.31	1.77	0.033	0.63	0.89
K-Feldspar + FYM (T7)	1.55	30.60	0.39	0.32	1.71	0.039	0.64	1.04
OMWW+ K-Feldspar+ FYM (T8)	1.53	12.80	0.42	0.33	1.90	0.044	0.51	0.55
LSD(0.05)	0.12^ns	16.82^**	0.04^**	0.03^*	0.40^ns	0.023^*	0.16^s	0.67^ns

**: significant difference at 0.01 *: significant difference at 0.05 ns: non-significant

Table (5). Some physical properties for subsurface layer of the studied soil as affected by the applied soil conditioners

Treatments	BD (g/cm3)	Ks (cm/day)	MWD (mm)	GMD (mm)	Cr	Rate of disintegration	Pi	Kr
Control	1.57	110.93	0.32	0.27	1.18	0.071	0.70	1.43
OMWW	1.56	36.47	0.33	0.28	1.31	0.039	0.70	0.97
K- Feldspar	1.58	79.00	0.37	0.30	1.49	0.039	0.75	1.19
FYM	1.44	45.80	0.35	0.29	1.51	0.047	0.66	1.11
OMWW+K- Feldspar	1.56	69.83	0.38	0.31	1.56	0.065	0.71	1.05
OMWW+ FYM	1.55	34.93	0.35	0.29	1.52	0.034	0.72	1.32
K-Feldspar + FYM	1.55	45.17	0.38	0.31	1.54	0.029	0.70	1.26
OMWW+K-Feldspar+ FYM	1.53	27.10	0.40	0.32	1.69	0.030	0.65	0.95
LSD(0.05)	0.12ns	0.40*	0.03**	0.02*	0.31ns	0.03ns	0.14ns	0.63ns

The OMWW significantly increased the water retention capacity of the soils in all treatments (Table 6). This effect can be notes from the shape of the WRC, primarily in the low suction range. The high organic matter content in OMWW significantly improved the soil water-holding capacity, despite significantly reducing the large macro pore percentage. Table (6) shows the soil moisture constants for all treatments. The significant reduction of large soil pores found with OMWW amendment because of the higher organic matter and salt content of these liquid wastes, which blocked large-sized pores (Mahmoud et al., 2010). It is also apparent that fluctuation in soil-water retention capacity among different treatments resulted from the aggregation effects of OMWW application on pore size rather than from other factors; hence, this fluctuation mainly affected by soil structure (Gharaibeh et al., 2007).

Table (6). The soil moisture constants as affected by treatments

Treatments	Surface layer 0 – 30 cm			Subsurface layer 30 – 60 cm
Treatments	q_r cm³/cm³	q_fc cm³/cm³	q_s cm³/cm³	q_r cm³/cm³	q_fc cm³/cm³	q_s cm³/cm³
Control	0.018	0.107	0.339	0.017	0.104	0.339
OMWW	0.022	0.131	0.352	0.020	0.103	0.352
K- Feldspar	0.025	0.168	0.404	0.021	0.155	0.404
FYM	0.038	0.183	0.419	0.035	0.127	0.419
OMWW+K- Feldspar	0.030	0.159	0.355	0.021	0.118	0.355
OMWW+ FYM	0.041	0.205	0.469	0.032	0.146	0.469
K-Feldspar + FYM	0.042	0.198	0.456	0.035	0.127	0.456
OMWW+ K-Feldspar+ FYM	0.043	0.210	0.540	0.052	0.174	0.540
LSD (0.05)	0.011**	0.037**	0.076**	0.011**	0.042*	0.076ns

Table (7) show the available water for all treatments in surface and subsurface layers. The treatment T8 (OMWW+ K-Feldspar+ FYM) illustrated the highest available water content in the surface and subsurface layers, which equal to 17.03% and 13.16 cm/100 cm, respectively. Avoiding environmental seriousness and producing good quality crops requires utilizing natural byproducts, which became necessity. One way of improving the quality of applied wastes is composting, which yields an excellent product due to the accumulation of humus as substances produced from the biochemical process that takes place during composting (Rivero et al., 2004).

Table (7). Available water as affected by treatments in surface and subsurface layers

Treatment	Available water (cm/100 cm depth)
Treatment	Surface layer	Subsurface layer
Control	8.85	8.77
OMWW	10.88	8.30
K- Feldspar	14.30	12.00
FYM	12.84	9.80
OMWW + K- Feldspar	12.90	9.27
OMWW + FYM	16.45	10.38
K-Feldspar + FYM	15.51	7.56
OMWW+ K-Feldspar + FYM	17.03	13.16
LSD(0.05)	3.29**	4.01*

Effect of olive mill wastewater and natural conditioners on the tested soil chemical properties:

2.1. Soil pH, EC and soluble ions

Data presented in Tables (8 and 9) showed that the soil pH values ranged between 7.14 to 7.92 and 7.0 to 7.8 in surface and subsurface layers of the investigated soil respectively. It is clear that the application of all treatments reduced the soil pH values where the lowest value was associated with farmyard manure and OMWW treatments. This reduction may be due to the various acids or acid-forming compounds released from the added organic material.

Regarding EC values, it is clear that remarkable changes were obtained due to the applied treatments, where the variations not more than a unit of dS/m. In addition, the values of soil salinity lie in slightly to moderately salinity classes according to Richards (1954). The lowest EC value obtained with Potassium feldspar treatment as it reached 1.05 and 0.94 dS/m for surface and subsurface layers of the investigated soil, respectively. The positive effect of Potassium feldspar on EC values reflects its role in improving physical properties of the investigated soil as found in this study (Tables 8 & 9), therefore salts of soil would easily leached out. Rinaldi et al. (2003) reported that soil application of OMW could increase soil electrical conductivity. Therefore, periodically monitoring of soil salinity (EC) and developing a proper irrigation management strategies are required to minimizes the adverse effects of salt accumulation on soil quality and plant growth (Azam et al., 2002). Data in the same tables also indicate that the soluble soil cations and anions favorably affected by all the applied treatments. The application of the potassium feldspar treatment showed the highest reduction in both soluble Na+ and soluble Cl- values compared with the other treatments. As the decrement rate of such values under the control reached (19.57, 15.28 %) and (39.01, 13.72 %) for surface and subsurface layers of the investigated soil respectively.

2.2. Total calcium carbonate and organic matter content

Data in Tables (8 and 9) indicated that soil total calcium carbonate content favorably affected by all the applied treatments and the combined treatment (Olive mill wastewater + Potassium feldspar + Farmyard manure) was the best treatment. The rate of decrement under the control due such treatment reached 52.81 and 15.18% for surface and subsurface layers of the investigated soil, respectively. The amendments application remarkably increased soil organic matter content as compared to the control treatment. The highest organic matter values obtained with the combined treatment of (Olive mill wastewater + Farmyard manure) as the rate of increment over the control reached 2700 and 2675 % for soil surface and subsurface layers respectively. The positive effect of such treatment on increasing soil organic matter content may be due to the higher organic carbon content in these materials, Table (2). These results are in a good agreement with those obtained by Speir et al. (2004) who found that the application of organic amendments led to increase in the total organic carbon of soil.

Table (8). Some chemical properties for surface layer of soil as affected by the applied conditioners

Treatments	pH	EC dS/m	Soluble Cations (me/l)				Soluble anions (me/l)			CaCO3 (%)	OM (%)
Treatments	pH	EC dS/m	Ca	Mg	Na	K	HCO3	CL	SO4	CaCO3 (%)	OM (%)
Control	7.71	1.28	2.14	3.12	7.05	0.49	2.85	7.26	2.70	12.19	0.11
OMWW	7.41	1.16	3.60	1.94	5.35	0.72	4.85	5.55	1.21	12.19	0.7967
K- Feldspar	7.94	1.05	3.37	1.14	5.67	0.32	2.96	6.18	1.37	9.527	0.12
FYM	7.14	2.38	6.14	2.87	9.92	4.92	2.19	10.06	11.59	8.193	2.4533
OMWW+K- Feldspar	7.75	1.39	4.77	1.73	3.90	3.50	4.98	7.58	1.35	9.903	0.3133
OMWW+ FYM	7.43	2.47	4.86	5.72	9.32	4.76	10.50	9.78	4.39	6.663	3.0867
K-Feldspar+ FYM	7.33	2.24	6.35	1.75	8.37	5.98	8.11	9.95	4.39	7.05	2.5333
OMWW+K-Feldspar + FYM	7.20	2.39	7.39	4.08	5.93	6.50	11.13	9.06	3.72	5.713	2.77
LSD(0.05)	0.22**	0.68**	2.27*	1.88*	5.89ns	2.44**	2.43**	3.99ns	2.28**	3.21*	0.65**

Table (9). Some chemical properties for subsurface layer of soil as affected by the applied conditioners

Treatments	pH	EC dS/m	Soluble Cations (me/l)				Soluble anions (me/l)			CaCO3 (%)	OM (%)
Treatments	pH	EC dS/m	Ca	Mg	Na	K	HCO3	CL	SO4	CaCO3 (%)	OM (%)
Control	7.62	1.42	2.63	3.15	8.05	0.37	4.64	5.76	3.79	8.76	0.08
OMWW	7.29	1.03	2.95	1.91	4.68	0.70	4.07	5.20	0.98	12.38	0.42
K- Feldspar	7.87	0.94	2.82	1.38	4.91	0.28	3.47	4.97	0.96	10.29	0.10
FYM	7.04	1.94	5.22	3.05	9.06	2.06	5.98	7.17	6.25	7.05	1.74
OMWW+K- Feldspar	7.59	1.21	3.97	1.41	5.70	1.02	4.65	6.18	1.27	8.00	0.16
OMWW + FYM	7.34	2.50	5.43	3.71	11.78	4.08	11.27	10.31	3.42	8.76	2.22
K-Feldspar + FYM	7.22	1.88	4.31	3.24	9.41	1.87	6.52	8.95	3.36	10.67	2.06
OMWW+K-Feldspar +FYM	7.12	2.19	5.42	4.80	9.68	2.00	9.96	8.49	3.46	7.43	1.82
LSD(0.05)	0.20**	0.53**	1.79*	2.22*	3.64*	1.91*	2.27**	3.27*	3.05*	7.52ns	0.37**

Magnesium Adsorption Ratio (MAR) and Soluble Sodium Percentage (SSP) showed slight significant differences with LSD 21.851 and 17.951 for the surface layer, while they showed non-significant differences for the subsurface layer with LSD 26.511 and 12.991, respectively. The control treatment showed the highest percentages for both layers for MAR and SSP. Sodium Adsorption Ratio (SAR) and Exchangeable Sodium Percentage (ESP) showed non-significant differences for the surface layer with LSD 2.80 and 4.17, respectively, and the same for a subsurface layer but different LSD values (2.0722 and 3.0859), respectively. For the surface layer, the highest percentages occurred with T4 for SAR and ESP (4.68% and 5.7%), while the lowest percentages occurred with T5 (2.17% and 1.96%), respectively. For subsurface layer, T2 showed the lowest percentages for SAR and ESP 3.01% and 3.21%, and T6 showed the highest percentages (5.57% and 7.02%), respectively. Table (10) represent SAR, MAR, SSP and ESP analysis for surface and subsurface layers, respectively. Lopez-Pineiro et al. (2008) reported that using olive mill wastewater as an organic amendment decrease the negative environmental; enhance soil quality and agronomic limitations of these soils.

Table (10). Influence of olive mill wastewater and the natural conditioners on some chemical properties of the studied soil for surface and subsurface layers

Treatments	Surface layer				Su-surface layer
Treatments	SAR	MAR (%)	SSP (%)	ESP (%)	SAR	MAR (%)	SSP (%)	ESP (%)
Control	4.22	59.97	53.35	5.01	4.79	54.44	53.43	5.87
OMWW	3.23	36.11	46.32	3.53	3.01	38.61	45.43	3.21
K- Feldspar	3.81	26.39	54.09	4.41	3.40	31.67	52.44	3.79
FYM	4.68	32.07	41.16	5.70	4.46	35.81	47.55	5.37
OMWW + K- Feldspar	2.17	27.14	27.90	1.96	3.46	26.55	46.90	3.89
OMWW + FYM	4.09	52.99	38.11	4.82	5.57	39.02	46.64	7.02
K-Feldspar + FYM	4.18	21.20	34.67	4.96	4.86	42.99	50.14	5.96
OMWW+ K-Feldspar + FYM	2.54	36.15	24.25	2.52	4.29	47.08	44.24	5.12
LSD(0.05)	2.80ns	21.85*	17.95*	4.17ns	2.07ns	26.51ns	12.99ns	3.08ns

2.3. Available nutrient contents

Data in Tables (11 and 12) indicate the effect of the applied amendments on available nutrients of soil surface and subsurface layers. The results showed significant differences for all the rated nutrients. With respect to increasing the availability of N, P and K, it is clear that the combined treatment (Potassium feldspar + Farmyard manure) was the best in this concern. As the values of such elements reached (420 and 294 mg/kg), (188 and 139 mg/kg), (558 and 424 mg/kg) for N, P, K in the surface and subsurface layers, respectively. Farm manure increased P and K content in soil significantly while it had not effect on N content (Iqbal et al., 2005). Data in the same tables indicated that the available Fe, Mn, Zn and Cu in soil increased by the application of all the studied experimental treatments to the soil. The highest rate of increment in such elements was associated with the combined treatment (Olive mill wastewater + Potassium feldspar + Farmyard manure) as the rate of increment over the control reached (617.96 and 579.84 %), (884 and 735.33 %), (661.22 and 272.5 %), (520 and 600 %) for Fe, Mn, Zn, Cu in soil surface and subsurface layers respectively. The positive effect of the applied amendments on increasing the availability of all these nutrients may be due to the higher initial content of these nutrients in the applied amendments or due to its role in decreasing soil pH values Table (4). This reduction in soil pH increased the availability of soil nutrients, especially the micronutrients for the cultivated plant. OMWW and FYM contain nutrients and other compounds that might be beneficial to the soil fertility and productivity (Belaqziz et al., 2008; L´opez-Pi˜neiro et al., 2011). This is particularly important for the soil of the arid and semi-arid regions where low fertility, low nutrient availability, and productivity as well as low microbial activity and microbial biomass levels characterize the soil. This is due to low content of organic matter and low level of essential nutrients for the plant growth. Furthermore, soils of the semi-arid region are vulnerable to erosion and degradation due to poor soil structure because of lower organic matter content (Zhang et al., 2014).

Table (11). Available nutrients content in surface layer of the studied soil as affected by the applied conditioners

Treatments	Available macro-nutrients (mg/kg)			Available micro-nutrients (mg/kg)
Treatments	N	P	K	Fe	Mn	Zn	Cu
Control	252.00	14.90	68.00	1.67	1.75	0.49	0.055
OMWW	317.30	23.60	106.00	1.67	6.87	0.55	0.095
K- Feldspar	308.00	13.70	69.33	1.72	3.03	0.54	0.059
FYM	392.00	180.67	499.33	6.35	14.69	2.40	0.428
OMWW + K- Feldspar	317.30	28.27	179.33	4.22	9.17	0.75	0.136
OMWW + FYM	420.00	188.00	558.00	10.08	13.06	2.40	0.400
K-Feldspar + FYM	382.70	177.03	616.67	5.86	13.93	1.71	0.246
OMWW+ K-Feldspar + FYM	420.00	175.47	615.33	11.99	17.22	3.73	0.341
LSD(0.05)	36.43**	28.32**	208.56**	0.81**	2.61**	0.34**	0.10**

Table (12). Available nutrients content in subsurface layer of the studied soil as affected by the applied conditioners

Treatments	Available macro-nutrients (mg/kg)			Available micro-nutrients (mg/kg)
Treatments	N	P	K	Fe	Mn	Zn	Cu
Control	238.00	13.83	64.67	1.29	1.67	0.40	0.06
OMWW	280.00	18.40	88.00	1.49	5.49	0.58	0.09
K- Feldspar	280.00	10.53	63.33	1.68	2.33	0.48	0.08
FYM	317.33	136.27	256.00	4.14	11.19	1.41	0.25
OMWW + K- Feldspar	275.33	21.53	102.67	3.78	7.76	0.70	0.17
OMWW + FYM	294.00	139.30	424.00	8.01	10.52	1.65	0.38
K-Feldspar + FYM	303.33	121.57	258.00	4.08	11.46	1.54	0.32
OMWW+ K-Feldspar + FYM	298.67	132.30	304.00	8.77	13.95	1.49	0.42
LSD(0.05)	31.48*	31.99*	125.12**	2.23**	3.80**	0.34**	0.18*

Conclusion

Olive mill wastewater (OMWW) contains many nutritive elements, which could improve the agricultural production. The OMWW considered as a fertilizer material for crop cultivation. Furthermore, OMWW does not present any risks for the soil salinity; in addition, it generates an improvement of some physical and chemical soil properties.

The results of this study confirmed the ability of olive mill wastewater when used alone to improve the properties of sandy soil and compensate the deficiency of its nutrients. Moreover, when the soil treated with mixtures of olive mill wastewater and potassium feldspar or farmyard manure gave the highest reduction in salinity. It indicated that the application of the combined treatment (Olive mill wastewater + Potassium feldspar + Farmyard manure) resulted in the best treatment. Therefore, the application of such treatment to sandy soils is necessary to improve its physical and chemical properties. The application of olive mill wastewater to a sandy soil can used as an economic and simple alternative for disposal methods of such material. The use of each material in the present study is easily producible, biodegradable, and less expensive and cause no environmental hazards to human health. These products will be ecologically safe and culturally more acceptable among farmers.

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