Using of Potassium Silicate to Alleviate Drought Stress Effect on Peanut as Grown in Sandy Soil

Gomaa, Mahmoud; Fathallah Rehab, Ibrahim; Kandil, Essam Esmael; Ali, Ali Mohamed Mohamed; Abd elhafez, Waleed Breek GadAllah

doi:10.21608/jalexu.2021.179977

Using of Potassium Silicate to Alleviate Drought Stress Effect on Peanut as Grown in Sandy Soil

Journal of the Advances in Agricultural Researches

Article 2, Volume 26, Issue 3 - Serial Number 100, September 2021, Page 109-119 PDF (432.06 K)

Document Type: Research papers

DOI: 10.21608/jalexu.2021.179977

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Authors

Mahmoud Gomaa¹; Ibrahim Fathallah Rehab²; Essam Esmael Kandil¹; Ali Mohamed Mohamed Ali³; Waleed Breek GadAllah Abd elhafez¹

¹Plant Production Dept. Faculty of Agriculture (Saba Basha) Alexandria University.

²Faculty of Agriculture saba basha, Alexandria University

³Dept.of Soil Fertility and Microbiology, Desert Research Center, Cairo, Egypt

Abstract

Two field Experiments were conducted at Abd El-Maneim Ryad, South Tahrir, El- Beheira Governorate, Egypt, during the summer growing seasons of 2017 and 2018 to study the role of foliar application of potassium silicate for alleviating drought stress effect on peanut grown in sandy soil. This experiment carried out in a split plot design with three replicates where the drought stress treatments (irrigation after depletion of 40%, 55%, 70% and 85% Available soil water were occupied main plot, while potassium silicate concentration (control, 500, 1000 and 1500mg/l silicate) was allocated in sub main plot.
Results revealed that irrigation after depletion of 55% available soil water recorded the highest mean values of yield and yield components i.e. (100-pods weight, no. of pods/plant, pods yield/fed, biological yield/fed and straw yield/fed during both seasons, while, the irrigation after depletion of 40% available soil water recorded the highest mean values of harvest index percentage during both seasons).
Foliar application of potassium silicate at 1500 mg/l silicate recorded the maximum 100- pods weight, no. of pods/plant, pods yield/fed, biological yield/fed and straw yield/fed, while, control treatment recorded the highest mean values of harvest index percentage during both seasons. Chemical compositions i.e. (oil percentage and oil yield/fed) recorded the best values with irrigation after depletion of 40% available soil water, while, proline content recorded the highest mean values at irrigation after 85% depletion of available water; in addition, potassium silicate at 1500 mg/l silicate recorded the highest percentages of oil and oil yield/fed, while, proline content recorded the best values with control treatment, during both seasons. Water use efficiency recorded the highest mean value with irrigation after depletion of 85%available soil water during both seasons; with regard, potassium silicate at 1500 mg/l silicate gave the highest mean values of water use efﬁciency as compared with control treatment which recorded the lowest mean values of WUE during both seasons

Keywords

Peanut; drought stress; potassium silicate; yield and yield components

Full Text

INTRODUCTION

Groundnut or peanut (Arachis hypogaea L.) is considered to be one of the most important edible legume crops in Egypt, due to its seeds has high nutritive value for human and the produced cake as well as the green leafy hay for livestock (Abdalla et al., 2009). Peanut is one of the most important cash crops, besides food crops and oil seed crops, in the world. However, most of the world’s peanut production is grown mostly under rain-fed conditions, where unpredicted and inadequate rainfall or drought seriously affects peanut production (Icrisat, 2011). Peanut is the world’s 4^th most essential edible oil crop and 3^rd most vital source of vegetable protein (CGIAR, 2005). Peanut is a vital legume crop grown in tropical and sub-tropical semi-arid regions of the world; the yield level is severely affected by deficiency of soil moisture. Peanut is a main seed legume in Egypt as compared with other oil crops (Arruda et al., 2015).

Drought is the most limiting factor, resulting in low yields in many parts of the world (Songsri et al., 2008). Drought during the pod filling phase of peanut is common and causes the greatest reduction in peanut pod yield (Ravindra et al., 1990). Also, Girdthai et al. (2010) stated that drought reduced pod yield up to 35% and biomass by 21%.Water deficit stress is one of the main environmental restraints limiting agricultural productivity and acts avital role in the distribution of plant species across different types of environments (Ashraf, 2010). Drought stress has been the major environmental factor responsible to yield losses in numerous crops worldwide. The losses are highly flexible reliant on timing, intensity, and period coupled with other location-specific environmental stress factors such as temperature and salinity (Kambiranda et al., 2012). Drought not only results in yield loss, but also is the chief reason for decrease innutritional quality of seed (Amir et al., 2005) and rises in aflatoxin contamination (Girdthai et al., 2010).

Silicon (Si) is one of the abundant elements in the lithosphere and it is the most abundant element in soil next to oxygen and comprises 28 percent of its weight and 3 - 7 percent in soil solution (Epstein, 1999). Si is most commonly found in soils in the form of solution as silicic acid and plants take up directly as silicic acid (Ma, et al., 2001). Application of silicon increased the shoot silicon concentration and dry matter production (Prakash, et al., 2011). Silicon can be enhanced plant resistance to manyabiotic stresses: salinity, drought, metal toxicity and ultra violet radiation (Balakhnina and Borkowska, 2013). Silicon spraying improved growth and physiological indices hence could increase the ability of plants to resistance water stress. Silicon application reduces transpiration leads to water stress tolerance (Asgharipour and Mosapour, 2016). The role of silicon in plant biology is to decrease various stresses such asbiotic and abiotic stresses. Si helps to protect crops from insect attack, disease and environmental stress. In organic farming system, the addition of silicon sources to crops may increase the yield and decreasing the use of chemical fertilizers, pesticides and fungicides (Patil, et al., 2017). Si can improve growth, biomass and yield of wide range of crops including monocotyledonous crops that have the capability to collect high amounts of Si in their organs (Shedeed,2018).

Foliar application of K- silicate has many benefits in enhancing leaf erectness and photosynthesis efficiency also decreasing capability to lodging in herbal crops (Ahmad et al., 2013). In addition, Si offers benefits in numerous agricultural applications e.g. increases growth and yield, improves strength, minimize climate stress and provides impedance to mineral stress. On this way Kandil et al. (2019) found that K- silicate increased yield, yield components and quality of soybean under environmental stress.Also, Gomaa et al. (2020) and Gomaa et al. (2021b) revealed that foliar application of K-silicate three times resulted in the highest growth, yield and grain characters can increase WUE of maize. On the other hand, under water-deficit stress, irrigation every fifteen days combined with application of K-silicate spraying in three times recorded the highest values of growth and grain yield and its components. Also, El-Naggar et al. (2020) indicated that using Si in Nanoparticles increased yield and its components of maize. Gomaa et al. (2021a) showed that application of Si increased yield and its components of maize.

The overall objective of the present research was to study the role of foliar application of potassium silicate for alleviating drought stress effect on peanut grown in sandy soil.

MATERIALS AND METHODS

Two field Experiments were conducted at Abd El-Maneim Ryad, South Tahrir, Beheira, Governorate, Egypt, in the summer growing seasons of 2017 and 2018 to study the alleviating drought stress effect on peanut grown in sandy soil using foliar application of potassium silicate.

The preceding crop was Potato (Solanum tuberosum L.) in the two seasons. The physical and chemical properties of experimental soil are presented in Table (1) according to the method described by Page et al. (1982).

Table (1). The initial physical and chemical properties of the experimental soil seasons of 2017 and 2018

Physical properties 2017 2018

98.58

----

1.42

Sand

95.52

----

4.48

Sand

Sand (%)

Silt (%)

Clay (%)

Textural class

Chemical properties

7.58

0.27

0.32

0.31

8. 7

0. 39

0. 31

EC (dS/m)

O. M (%)

Ca CO₃ (%)

Soluble Cations (meq /L)

1. 96

3. 75

1.83

0.66

1. 50

3. 50

1.85

0.64

Ca ⁺²

Mg ⁺²

Na ⁺¹

K ⁺¹

Soluble Anions (meq /L)

3. 27

2. 31

1. 26

3. 20

2. 40

1. 24

HCO₃^-1

Cl ^-1

SO₄^-2

Available nutrients (mg/kg soil)

175

217

123. 13

250

Experimental layout

The experiments were carried out in a split plot design with three replicates, where the irrigation treatment i.e. (irrigation after depletion of 40 %, 55%, 70% and 85% available soil water) was applied after ten days from planting were arranged in the main plots, then the four potassium silicate (control=spray tap water, 500, 1000 and 1500 mg/l silicate) as applied after 35, 45, 55 and 65 days from planting and were allocated in the subplots.

Peanut (Arachis hypogaea L.) variety Giza 6 were planted on 20^th April and harvested on 18^th of August in the two seasons 2017 and 2018.

Table (2). Field capacity (FC), permanent wilting point (PWP), available soil water (ASW), and bulk density (BD) of the experimental soil.

Season								Depth of Soil (cm)
2018				2017
BD g /cm³	ASW (%)	PWP (%)	FC (%)	BD g /cm³	ASW (%)	PWP (%)	FC (%)
1.44	4.0	4.7	8.7	1.63	4.0	4.6	8.6	0-30

Determination of available water

AW(mm) = (q_fc - q_pwp)Dr

AW(%) = (q_fc - q_pwp)

Where:

AW = depth of water available

q_fc = volumetric field capacity

q_pwp = volumetric permanent wilting point

Dr = depth of root zone

Determination of depletion (%)

Depletion of 40% available soil water = 0.40 x AW(%)

Depletion of 55% available soil water = 0.55 x AW(%)

Depletion of 70% available soil water = 0.70 x AW(%)

Depletion of 85% available soil water = 0.85 x AW(%)

Soil moisture content

Soil moisture (%) was measured using the following equation:

Soil moisture (%) = × 100

To convert into volumetric moisture content, the dry weight fraction is multiplied by the bulk density, g _b

Irrigation treatments

Irrigation after depletion of 40% available soil water

= field capacity - depletion of 40% available soil water

Irrigation after depletion of 55% available soil water

= field capacity - depletion of 55% available soil water

Irrigation after depletion of 70% available soil water

= field capacity - depletion of 70% available soil water

Irrigation after depletion of 85% available soil water

= field capacity - depletion of 85% available soil water

Fertilizer application

Before sowing were applied 300 kg/fed super phosphate calcium and 100 kg sulphur/fed during soil preparation. After sowing all experimental units were received fertilizer as 40 and 25 kg/fed of N and K, respectively. Sources of these fertilizers were ammonium nitrate (33.5% N) and potassium sulphate (50% K₂O), while, N fertilizer was added in four equal doses and K fertilizer were added in two equal doses during vegetative growth. The experimental units were hand hoed three times for controlling. Other agricultural practices were done as recommended by the Ministry of Agriculture and Land Reclamation.

Studied characters

Yield and yield components such as 100-pods weight (g), no. of pods/plant, pods yield (kg/fed), straw yield (kg/fed), biological yield (kg/fed), and harvest index (%) as well as chemical composition such as proline (mg/g) and oil (%) in addition to water use efﬁciency (Kg/m³) were studied.

3.5 Statistical analysis

The obtained data were subjected to the proper method of statistical analysis of variance as described by Gomez and Gomez (1984). The treatment means were compared using the least significant differences (L.S.D.) at 0.05 level of probability by SAS (Statistical Analysis System) version 9.1 (2002).

RESULTS AND DISCUSSION

A) Yield and yield components

Result tabulated in Table (3) showed irrigation after depletion of 55% available soil water recorded the heaviest 100 pods weight (209.36 and 198.80 g), maximum number of pods/plant (43.25 and 39.81) and pods yield (2910.74 and 2374.46 kg/fed) in two seasons, respectively, as compared to irrigation after depletion of 40% available soil water which recorded the lowest 100 pods weight (162.70 and 154.56 g), minimum number of pods/plant (28.66 and 26.45) and pods yield/fed (2514.17 and 2114.01 kg), during both seasons, respectively. Number of pods per plant was the most vulnerable item damaged by drought stress (Pandey et al., 1984). The effect of drought stress on the yield of three bean cultivars showed that stress at flowering stage reduced the number of pods per plant and seeds per pod in all three varieties (Fienebaum et al., 1991). The number of pods/plant reduced due to drought stress (Seyed et al., 2011). Also, Gomaa et al. (2020) and Gomaa et al. (2021b) reported the similar results, who found that water stress reduced growth and yield characters of maize.

The yield advantages due to moderate water deficit during the pre-flowering phase are associated with greater pod synchrony after the release of water stress, resulting in production of more mature pods (Nageswara et al., 1988). When stress is released, the plant try to set more fruiting sites with the existing assimilates as the vegetative site demanding assimilate supply are reduced. To improve the conventional irrigation management practices to enhance yield and water use efficiency in groundnut during summer seasons a field experiment was conducted by Nautiyal et al. (2002) where dry matter partitioning among various plant parts, and leaf area index (LAI) varied significantly under water deficit and more dry matter accumulated in petiole and stem under stress. The pod development are progressively inhibited by drought due to insufficient soil moisture and lack of assimilate (Reddy et al., 2003). Girdthai et al. (2010) found that peanut pod yield is decreased when subjected to drought stress due to reduction in the photosynthetic rate and disrupts the carbohydrate metabolism (Farooq et al., 2009). Moreover, most of stressed peanut genotypes had lower pod growth rate than peanut having Field capacity (FC) treatment, indicating that the assimilate portion may enhance to support the economic part. Prabawo et al. (1990) reported that re-watering after pod filling stages increased pod yields of Spanish type peanuts. Yield loss caused by moisture stress depends on genotype, plant developmental stage, severity and duration of water shortage (Korte et al., 1993).Under drought conditions, the peanut agronomic characteristics and grain yield of all cultivars decreased and a significant reaction of the genotypes was observed (Vorasoot et al., 2003).

In this respect, increasing the concentration of potassium silicate foliar application increased 100 pods weight, number of pods/plant and pods yield/fed,whereas, foliar application of potassium silicate at 1500 mg/l silicate recorded the maximum 100 pods weight (214.75 and 204.01 g), number of pods/plant (42.17 and 38.79)and pods yield/fed (2965.97 and 2610.04 kg), as compared to control treatment which recorded the lowest mean values of 100-pods weight (156.55 and 147.42 g), number of pods/plant (30.74 and 28.35) and pods yield/ fed (2420.99 and 1902.72 kg) during both seasons, respectively. These results are agreement with those results reported by Gomaa et al. (2020) and Gomaa et al. (2021a)

The interaction between irrigation treatments (A) and potassium silicate concentration (B) was significant on 100 pods weight, number of pods/plant and pods yield/fed during both seasons.The greatest values of these traits were recorded when peanut crop were irrigated after depletion of 55% available soil water under foliar application of potassium silicate at 1500 mg/l silicate, whereas the lowest values resulted from irrigation after depletion of 40% available soil water under tap water spray (control) during both seasons.

Table (3). Effect of irrigation levels (A), potassium silicate (B) and their interaction (A*B) on 100-pods weight, No. of pods/plant and of Pods yield peanut during 2017 and 2018 seasons

Treatments		100-pods weight (g)		No. of pods/ plant		Pods yield (kg/ fed)
Treatments		2017	2018	2017	2018	2017	2018
A) Irrigation levels 85 % 70 % 55 % 40 %		172.10c 194.37b 209.36a 162.70d	163.49c 183.35b 198.80a 154.56d	34.10c 38.98b 43.25a 28.66d	31.36c 35.86b 39.81a 26.45d	2589.99c 2734.12b 2910.74a 2514.17d	2188.61c 2298.87b 2374.46a 2114.01d
LSD_(0.05)		6.11	5.56	1.82	1.25	57.58	46.07
B) Potassium silicate Control 500 mg/l 1000 mg/l 1500 mg/l		156.55d 173.95c 193.28b 214.75a	147.42d 165.25c 183.61b 204.01a	30.74d 34.13c 37.95b 42.17a	28.35d 31.42c 34.91b 38.79a	2420.99d 2588.01c 2774.05b 2965.97a	1902.72d 2114.14c 2349.04b 2610.04a
LSD_(0.05)		0.40	1.93	0.15	0.21	10.91	2.44
*The interaction (AB)**		*	*	*	*	*	*
Irrigation levels	Potassium silicate (mg/l)
85 %	Control	145.93	138.63	28.91	26.54	2301.80	1855.76
	500	162.14	154.03	32.13	29.56	2475.01	2061.96
	1000	180.16	171.15	35.70	32.84	2690.34	2291.07
	1500	200.17	190.16	39.67	36.49	2892.79	2545.63
70 %	Control	164.81	151.36	33.05	30.40	2444.09	1949.26
	500	183.12	173.97	36.72	33.78	2628.06	2165.84
	1000	203.47	193.30	40.80	37.54	2825.77	2406.49
	1500	226.08	214.77	45.33	41.70	3038.56	2673.88
55 %	Control	177.52	168.65	36.69	33.75	2690.66	2013.35
	500	197.25	187.38	40.69	37.51	2832.42	2237.06
	1000	219.16	208.21	45.30	41.68	2981.46	2485.62
	1500	243.52	231.34	50.33	46.31	3138.41	2761.80
40 %	Control	137.96	131.06	24.30	22.69	2247.42	1792.51
	500	153.28	145.62	27.00	24.84	2416.54	1991.68
	1000	170.32	161.80	30.00	27.60	2598.62	2212.98
	1500	189.24	179.77	33.33	30.67	2794.10	2458.86
LSD_(0.05)		0.46	2.23	0.18	0.24	12.60	2.81

- Irrigation level: irrigation after depletion of 40 %, 55%, 70% and 85% available soil water.

Means followed by the same letter within each column are not significant different at 0.05 level of probability.

* Denotes significant at 0.05 level of probability.

The results in Table (4) illustrated that irrigation after depletion of 55% available soil water recorded the highest straw yield/fed (2598.52 and 2858.34 kg) and biological yield/fed (5509.26 and 5232.80 kg) during the two seasons, respectively, as compared to irrigation after depletion of 40% available soil water which recorded the minimum straw yield/ fed (1330.38 and 1463.33 kg) and biological yield/fed (3844.56 and 3577.34 kg), while, irrigation after depletion of 40% available soil water recorded the highest percentage of harvest index (48.50 and 49.05 %), respectively, as compared to irrigation after depletion of 55% available soil water which recorded the minimum harvest index (40.37 and 40.70%), during both seasons, respectively.

Toprope et al. (2004) reported that Harvest index (HI) was the critical measure of water use efficiency under water deficit stress conditions. Greater HI was observed at pegging and pod development stage under drought conditions. Yield loss caused by moisture stress depends on genotype, plant developmental stage, severity and duration of water shortage (Korte et al., 1993).Under drought conditions, the peanut agronomic characteristics and grain yield of all cultivars decreased, and a significant reaction of the genotypes was observed (Vorasoot et al., 2003).

Also, data in Table (4) indicated that all potassium silicate concentration significantly increased straw yield/fed and biological yield/fed, generally, potassium silicate concentration at 1500 mg/l silicate recorded the highest straw yield/fed (2230.47 and 2453.51 kg) and biological yield/ fed (5196.44 and 5063.55 kg), while, potassium silicate at control recorded the highest harvest index percentage (44.77 and 46.85%), respectively, as compared with all treatments during both seasons.

The interaction between irrigation treatments and potassium silicate concentration was highly significant for straw yield/fed, biological yield and not significant for harvest index percentage during both seasons. The maximum values of the straw yield/fed and biological yield/fed were recorded when peanut crop were irrigated after depletion of 55% available soil water under foliar application of potassium silicate at 1500 mg/l silicate in both seasons, whereas the lowest ones were given with irrigation after depletion of 40% available soil water under tap water spray (control) in both cropping seasons. Harvest index (%) under irrigation after depletion of 40% available soil water and tap water spray (control) recorded the maximum values, while, the minimum values recorded under irrigation after depletion of 55% available soil water and foliar application of potassium silicate at 1500 mg/l silicate during both cropping seasons.

Table (4). Effect of irrigation levels (A) potassium silicate (B) and their interaction (A * B) for straw, biological yield and harvest index during 2017 and 2018 seasons.

Treatments		Straw yield (kg/ fed)		Biological yield (kg/ fed)		Harvest index (%)
Treatments		2017	2018	2017	2018	2017	2018
A) A) Irrigation levels 85 % 70 % 55 % 40 %		1662.98c 2078.71b 2598.52a 1330.38d	1829.33c 2286.61b 2858.34a 1463.33d	4252.97c 4812.83b 5509.26a 3844.56d	4017.93c 4585.48b 5232.80a 3577.34d	46.21b 44.22c 40.37d 48.50a	46.86b 44.17c 40.70d 49.05a
LSD_(0.05)		46.42	51.01	76.88	67.99	0.52	0.50
B) Potassium silicate Control 500 mg/l 1000 mg/l 1500 mg/l		1626.04d 1806.68c 2007.42b 2230.47a	1788.61d 1987.34c 2208.16b 2453.51a	4047.01d 4394.69c 4781.47b 5196.44a	3691.33d 4101.47c 4557.20b 5063.55a	44.77a 43.90b 43.02c 42.16d	46.85a 45.73b 44.50c 42.98d
LSD_(0.05)		9.62	10.58	16.55	10.05	0.1	0.11
The interaction *(AB)**		**	**	**	**	ns	ns
Irrigation Levels	Potassium silicate (mg/l)
85 %	Control	1410.08	1551.13	3375.50	3033.30	46.19	48.29
	500	1566.75	1723.47	3669.94	3337.34	45.26	47.77
	1000	1740.84	1914.97	3991.29	3744.82	44.35	45.94
	1500	1934.26	2127.74	4341.51	4160.91	43.46	44.46
70 %	Control	1762.58	1938.86	4894.00	4437.00	44.90	46.47
	500	1958.42	2154.30	5280.57	4929.99	44.01	44.98
	1000	2176.02	2393.66	5701.63	5477.77	43.13	43.52
	1500	2417.80	2659.63	6160.83	6086.42	42.27	42.12
55 %	Control	2203.34	2423.64	4206.66	3888.12	38.65	40.49
	500	2448.15	2692.93	4586.49	4320.13	37.90	39.19
	1000	2720.17	2992.15	5001.79	4800.15	37.14	38.61
	1500	3022.41	3324.61	5456.37	5333.50	36.40	37.10
40 %	Control	1128.06	1240.79	3711.88	3406.89	51.75	54.71
	500	1253.40	1378.66	4041.76	3785.43	50.72	53.62
	1000	1392.67	1531.84	4431.18	4206.04	49.98	52.35
	1500	1547.41	1702.05	4827.06	4673.37	48.15	50.67
LSD_(0.05)		11.10	12.22	29.63	22.05	0.12	0.10

- Irrigation level: irrigation after depletion of 40 %, 55%, 70% and 85% available soil water.

Means followed by the same letter within each column are not significant different at 0.05 level of probability.

** Denotes significant at 0.01 level of probability.

ns, Denotes not significant.

B ) Chemical composition

The perusal of results in Table (5) indicated that irrigation after depletion of 85% available soil water recorded the highest proline content (236.08 and 219.55 mg/g) in two seasons, respectively, as compared to irrigation after depletion of 40% available soil water which recorded the minimum proline content (187.19 and 174.09 mg/g), during both seasons, respectively. The proline content enhances the drought stress progressed and reached a peak as obtained after 10 days stress, and then decreased under severe water stress as observed after 15 days of stress (Anjum et al., 2011). Proline can act as a signaling molecule to modulate mitochondrial functions, influence cell proliferation or cell death and trigger specific gene expression, which can be essential for plant recovery from stress (Szabados and Savoure, 2010). Accumulation of proline under stress in many plants has been related with stress tolerance, and its concentration has been revealed to be generally higher in stress-tolerant than in stress-sensitive plants (Demiral and Turkan, 2005).

In another side, increasing potassium silicate concentration decreased proline content, during both seasons. However, potassium silicate at 1500 mg/lsilicate gave the lowest mean values of proline content (181.18and 168.96 mg/g), as compared to control treatment which recorded the highest mean values of proline content (249.22 and 231.77 mg/g), during both seasons, respectively. These findings may be related to the synergistic effect of the two studied factors on the different biochemical pathways in the plant cell. Silicon moderately offset the negative effects of drought stress by accumulation of proline and soluble protein content, thereby conferring stress tolerance (Sapre and Vakharia, 2016). In contrast, Crusciol et al. (2009) and Pilon et al. (2014) stated that proline (%) in leaves increased under water-deficit stress and higher silicon availability, which shows that silicon may be helpwith plant osmotic adjustment. Mauad et al. (2016) indicates that under water stress conditions, silicon application the proline content in the vegetative and reproductive phases of rice plants, which could be an indicator of stress tolerance.

The interaction between irrigation treatments and potassium silicate concentration was highly significant on proline content during both seasons. Irrigation after depletion of 85% available soil water recorded the highest proline content under the foliar spraying of tap water.

Results resented in Table (5) showed that irrigation after depletion of 40% available soil water recorded the highest oil percentage (45.31 and 42.14 %), as compared to irrigation after depletion of 85% available soil water which recorded the lowest oil percentage (34.36 and 31.95 %), during both seasons, respectively.

With regards to the effect of foliar application of different concentrations of potassium silicate increased oil percentage, during 2017 and 2018 seasons. Whereas, foliar application of potassium silicate at 1500 mg/l silicate recorded the best content of oil percentage (45.51 and 42.32 %), followed by potassium silicate at 1000 mg/l silicate (40.95 and 38.09 %), as compared to control treatment which recorded the lowest mean values of oil percentage (33.17 and 30.85 %), during both seasons, respectively.

The interaction between irrigation treatments and potassium silicate concentration was highly significant on oil percentage during both seasons. Oil content recorded the best results under irrigation after depletion of 40% available soil water with foliar spraying of potassium silicate at 1500 mg/l silicate in both seasons.

C) Water use efficiency

Results in Table (6) showed that increasing drought levels increased water use efficiency during both seasons. However, irrigation after depletion of 85% available soil water recorded the highest water use efficiency (0.835 and 0.706 Kg/m³),followed by irrigation after depletion of 70% available soil water(0.779 and 0.655 Kg/m³), as compared to irrigation after depletion of 40% available soil water which recorded the lowest mean value of water use efficiency (0.492 and 0.414 Kg/m³), during both seasons.

Where water is the limiting factor to crop production, deﬁcit irrigation can enhance WUE, so that the available water is better allocated. Water use efﬁciency (WUE) calculated as the harvested yield (kg) per volume of irrigation water (m³) according to FAO recommendations (Doorenbos and Kassam, 1979). Out of several biotic and abiotic factors responsible, optimum water management is one of the most important factors that significantly influence productivity as well as the quality of the production (Bhriguvanshi et al., 2012).

In another side, increasing potassium silicate concentration increased water use efﬁciency (WUE), during 2017 and 2018 seasons. However, potassium silicate at 1500 mg/l silicate gave the highest mean values of water use efﬁciency (0.782 and 0.688 kg/m³), as compared to control treatment which recorded the lowest mean values of water use efﬁciency (0.637 and 0.501 kg/m³), during both seasons, respectively.

WUE under water stress may be due to the vital role of K-silicate in reducing water-deficit stress on plant growth and yield (Gomaa et al. 2021b).

The interaction between irrigation treatments and potassium silicate concentration was highly significant on water use efficiency during both seasons. WUE under irrigation after depletion of 85% available soil water and foliar spraying with K-silicate at 1500 mg/l silicate gave the highest values followed by irrigation after depletion of 70% available soil water under the same foliar spray of K-silicate.

Table (5).Effect of irrigation levels (A), potassium silicate and their interaction (A * B) on proline content, oil content and water use efficiency of peanut during 2017 and 2018 seasons

Treatments		Proline (mg/g)		Oil (%)		WUE (Kg/m³)
Treatments		2017	2018	2017	2018	2017	2018
C) A) Irrigation levels 85 % 70 % 55 % 40 %		236.08a 224.42b 208.87c 187.19d	219.55a 208.71b 194.72c 174.09d	34.36d 36.95c 39.88b 45.31a	31.95d 34.36c 37.08b 42.14a	0.835a 0.779b 0.725c 0.492d	0.706a 0.655b 0.592c 0.414d
LSD_(0.05)		4.76	4.12	0.39	0.36	0.01	0.01
D) Potassium silicate Control 500 mg/l 1000 mg/l 1500 mg/l		249.22a 224.30b 201.87c 181.18d	231.77a 208.59b 178.73c 168.96d	33.17d 36.86c 40.95b 45.51a	30.85d 34.28c 38.09b 42.32a	0.637d 0.681c 0.731b 0.782a	0.501d 0.557c 0.619b 0.688a
LSD_(0.05)		0.75	0.22	0.07	0.06	0.003	0.001
The interaction *(AB)**		**	**	**	**	**	**
Irrigation Levels	Potassium silicate (mg/l)
85 %	Control	274.59	202.49	29.13	27.09	0.440	0.351
	500	247.13	182.23	32.37	30.10	0.473	0.390
	1000	222.42	164.01	35.97	33.45	0.509	0.433
	1500	200.19	147.61	39.96	37.17	0.547	0.481
70 %	Control	261.03	226.48	31.33	29.13	0.670	0.502
	500	234.92	203.83	34.81	32.37	0.706	0.557
	1000	211.43	183.45	38.68	35.97	0.743	0.619
	1500	190.29	165.10	42.97	39.96	0.782	0.688
55 %	Control	243.53	242.75	33.81	31.44	0.696	0.555
	500	219.17	218.48	37.57	34.93	0.749	0.617
	1000	197.26	196.63	41.74	38.82	0.805	0.686
	1500	175.53	176.97	46.38	43.13	0.865	0.761
40 %	Control	217.73	255.37	38.42	35.73	0.742	0.598
	500	195.95	229.83	42.69	39.70	0.798	0.665
	1000	176.36	206.85	47.43	44.12	0.868	0.739
	1500	158.72	186.16	52.71	49.02	0.933	0.821
LSD_(0.05)		0.87	0.25	0.08	0.07	0.004	2.39

- Irrigation level: irrigation after depletion of 40 %, 55%, 70% and 85% available soil water.

Means followed by the same letter within each column are not significant different at 0.05 level

of probability.

** Denotes significant at 0.01 level of probability.

CONCLUSION

The results can recommend that spraying the Giza 6 variety of peanut crop with potassium silicate at 1500 mg/l silicate four times as applied after (35, 45, 55 and 65 days from planting) to alleviate deleterious impacts of drought stress and irrigation after depletion of 55% available soil water to save water under water deficit conditions at South Tahrir El-Beheira Governorate as this combination has a significant effect and obtained high yield and its components under this study conditions and the similar conditions areas.

References

Abdalla, A.A., M.A. El-Howeity and A.H. Desoky (2009). Response of peanut crop cultivated in newly reclaimed soil to inoculation with plant growth-promoting Rhizobacteria. Minufiya J. Agric. Res., 34(6): 2281-2304.

Ahmad, A., M. Afzal, A.U.H. Ahmad and M. Tahir (2013). Foliar effect of silicon on yield and quality of rice. Cercetări Agronomiceîn Moldova, 3: 21-28.

Amir, Y., T. Benbelkacem, L. Hadni and A. Youyou (2005). Effect of irrigation and fertilization on characteristics of peanut seeds cultivated near Tizi-Ouzou. J. Agric. Food Chem., 4: 879–885.

Anjum, S. A., X. Xie, L. Wang, M. F. Saleem, C. Man and W. Lei (2011). Morphological, physiological and biochemical responses of plants to drought stress. Afri. J. Agric. Res., 6(9): 2026-2032.

Arruda, I.M., V. Moda-Cirino, J.S. Buratto and J.M. Ferreira (2015). Growth and yield of peanut cultivars and breeding lines under water deficit. ISSN 1983- 4063 - www.agro.ufg.br/pat - Pesq. Agropec. Trop., Goiânia, 45(2): 146-154.

Asgharipour, M. R. and H. Mosapour (2016). A foliar application silicon enhances drought tolerance in Fennel. J. Animal & Plant Sci., 26(4):1056-1062.

Ashraf, M. (2010). Inducing drought tolerance in plants. Biotech. Adv., 28: 169–183.

Balakhnina, T. and M. Borkowska (2013). Effects of silicon on plant resistance to environmental stresses: review. Int. Agrophys., 27:225-232.

Bhriguvanshi, S.R., T. Adak, K. Kumar, V.K. Singh and A. Singh. (2012). Impact of fertigation regimes on yield and water use efficiency of mango (Mangifera indica L.) under subtropical condition. Ind. J. Soil Cons. 40(3): 252–256

CGIAR (2005). Groundnut (Arachis hypogaea L.). Consultative Group on Int Agric Research. http://www.cgiar.org/ impact/researchground nut.html.

Crusciol, C.A., A.L. Pulz, L.B. Lemos, R.P. Soratto and G.P. Lima (2009). Effects of silicon and drought stress on tuber yield and leaf biochemical characteristics in potato. Crop Sci., 49: 949-954.

Demiral, T. and I. Turkan (2005).Comparative lipid peroxidation, antioxidant defense systems and proline content in roots of two rice cultivars differing in salt tolerance. Environ.&Exp. Bot., 53(3):247-257.

Doorenbos, J. and Kassam, A.H. (1979). Yield response to water. FAO Irrigation and Drainage, Paper 33, Rome, 193 p.

El-Naggar, M.E., N.R. Abdelsalam, M.M.Fouda, M.I.Mackled, M.A. Al-Jaddadi, H.M. Ali, M.H. Siddiqui and E.E.Kandil (2020). Soil application of nano silica on maize yield and its insecticidal activity against some stored insects after the post-harvest. Nanomaterials, 10(4):739.

Epstein, E. (1999). Silicon. Annual Review of Plant Physiology Plant Molecular Biol., 50: 641-664.

Farooq, M., A. Wahid, N. Kobayashi, D. Fujita and S.M.A. Basra (2009). Plant drought stress: effects, mechanisms and management. Agron. Sustain. Dev., 29:185–212.

Fienebaum. V., D.S. Santos and M.A. Tillmann (1991). Influence of water deficit on the yield components of three bean cultivars. Pesquisa-Agropecuaria Breasileria. 26(2): 275-280.

Girdthai, T., S. Jogloy, N. Vorasoot, C. Akkasaeng, S. Wongkaew, C.C. Holbrook and A. Patanothai (2010). Associations between physiological traits for drought tolerance and aflatoxin contamination in peanut genotypes under terminal drought. Plant Breed., 129:693-699.

Gomaa, M. A., E. E.,Kandil, A. Z. El-Dein, AM. E.Abou-Donia (2020). Effect of irrigation intervals and foliar application of potassium silicate on growth of maize. Egyptian Academic Journal of Biological Sciences, H. Botany, 11(1): 103-109.

Gomaa, M.A., E.E Kandil, A.A. El-Banna and D. H. Chelaby (2021a). Response of some maize hybrids to foliar application of silicon under soil affected by salinity. Egyptian Academic Journal of Biological Sciences, H. Botany, 12(1): 1-8.

Gomaa, M. A., E. E.,Kandil, A. Z. El-Dein, AM. E.Abou-Donia, H. M.Ali and N. R. Abdelsalam: (2021b). Increase maize productivity and water use efficiency through application of potassium silicate under water stress. Scientific reports, 11(1), 1-8.

Gomez and Gomez (1984). Statistical procedures in agricultural research. 2^nd edition. Wiley, NewYork

ICRISAT (2011). Groundnut (Arachis hypogaea L.). Hyderabad, India: International Crop Research Institute for the Semi-Arid Tropics. Prod. Adv. Agron., 77: 185–268.

Kambiranda, D.M., H.K.N. Vasanthaiah, R. Katam, A. Ananga, S.M. Basha and K. Naik (2012). Impact of drought stress on peanut (Arachis hypogaeaL.) productivity and food safety. In: Vasanthaiah HKN, Kambiranda DM, editors. Plants and Environment. Rijeka, Croatia: In Tech, pp. 249–272.

Kandil, E.E., A. A. Farag and M. I.A El-Shabory (2019). Effect of planting dates and silicon foliar application on soybean productivity. Advanced J. of Agric. Sci., 24(3):211-225.

Korte, L.L., J.H. Williams, T.E. Specht and R.C. Sorensen (1993). Irrigation of soybean genotypes during reproductive ontogeny. Agronomic responses. Crop Sci.,28: 521-530.

Ma, J. F., K. Tamaki and M. Ichii (2001). Role of root airs and lateral roots in silicon uptake by rice. Plant Phy., 127: 1773- 1780.

Mauad, M., C. Crusciol, A. Nascente, H. Filho and G. Lima (2016). Effects of silicon and drought stress on biochemical characteristics of leaves of upland rice cultivars. Revista Ciência Agronômica, 47(3): 532-539.

Nageswara, R.R.C., S. Singh, M.V.K. Sivakumar, K.L. Srivastava and J.H. Williams (1988). Effect of water deficit at different growth phase of peanut. I Yield responses. Agron. J., 77: 782–786.

Nautiyal, P.C., V. Ravindra, A.L. Rathnakumar, B.C. Ajay and P.V. Zala (2002). Genetic variation in photosynthetic rate, pod yield and yield components in Spanish groundnut cultivars during three cropping seasons. Field Crop Res., 125:83-89.

Page, A.L., R.H. Miller and D.R. Keeney (1982). Methods of Chemical Analysis. Part 2: Chemical and Microbiological Properties (2^nd Ed.). American Society of Agronomy, U.S.A.

Pandey, R.K., W.A.T. Herrera, A.N. Villegas and J.W. Pendleton (1984). Drought response of grain legumes under irrigation gradient. Plant growth. Agron. J., 76: 557-560.

Patil, H., R. V. Tank and M. Patel (2017). Significance of silicon in fruit crops- A Review. Plant Archives., 17(2):769-774.

Pilon, C., R.P. Soratto, F. Broetto and A.M. Fernandes (2014). Foliar or soil applications of silicon alleviate water-deficit stress of potato plants. Crop Ecology & Phys., 106(6): 2325- 2334.

Prabawo, A., B. Prastawo and G.C. Wright (1990). Growth, yield and soil water extraction of irrigated and dryland peanuts in South Sulawesi. Indonesia. Irrig. Sci., 11:63–68.

Prakash, N. B., N. Chandrashekhar, C. Mahendra, S. U. Patil, G. N. Thippeshappa and H. M. Laane (2011). Effect of foliar spray of soluble silicic acid on growth and yield parameters of wet land rice in hilly and coastal zone soils of Karnataka, South India, J. Plant Nutr., 34 (12):1883-1893.

Ravindra, V., P.C. Nautiyal and Y.C. Joshi (1990). Physiological analysis of drought resistance and yield in groundnut (Arachis hypogaeaL). Trop. Agric. Trinidad, 67: 290–296.

Reddy, T.Y., V.R., Reddy and V. Anbumozhi (2003). Physiological responses of peanut (Arachis hypogaeaL.) to drought stress and its amelioration: a critical review. Plant Growth Regul., 41: 75–88.

Sapre, S.S. and D.N. Vakharia (2016). Role of silicon under water deficit stress in wheat: (Biochemical perspective): A review. Agric. Rev., 37(2): 109-116.

SAS (2002). By SAS institute INC., Cary, NC, USA. SAS (r) proprietary software version 9.00.

Seyed, A, A.R., M.H. Gharine, A.M. Bakhshande, Q.A. Fathi and A. Naderi (2011). Effects of final drought stress (the end of the growing season) on grain yield, yield components, oil content, protein and growth properties of rapeseed (brassica napus) in ahvaz weather conditions. plant production (farm scientific journal). 34(2): 53-66.

Shedeed, S. I. (2018). Assessing effect of potassium silicate consecutive application on forage maize plants (Zea mays L.). J. Inn. Pharm. & Biol. Sci., 5 (2): 119-127.

Songsri, P., S. Jogloy, N. Vorasoot, C. Akkasaeng, A. Patanothai and C.C. Holbrook (2008). Root distribution of drought-resistant peanut genotypes in response to drought. J. Agron. Crop Sci., 194: 92–103.

Szabados, L. and A. Savoure (2010). Proline: a multifunctional amino acid. Trends

in Plant Sci.,15: 89–97.

Toprope, V.N., V.G. Makne and N.P. Jangwad (2004). Identification of groundnut varieties showing tolerance to drought. In National symposia: Enhancing productivity of groundnut for sustaining food and nutritional security. Oct 11-13: 54-55.

Vorasoot, N., P. Songsri, C. Akkasaeng, S. Jogloy and A. Patanothi (2003). Effect of water strees on yield and agronomic characters of peanut (Arachis hypogaeaL.). SongklanakarinJ. Sci. Technol., 25: 283-288.

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