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Impact of Irrigation Water Salinity on Growth, Yield and Water Use of Wheat (2015--2016)

S. K. BISWAS
IWM Division, BARI, Gazipur

A.R. AKANDA
IWM Division, BARI, Gazipur

Abstract/ Executive Summary:

Water and soil salinity are important factors determining crop growth and yield, especially, in saline soils. A field experiment was conducted at the experimental field of the IWM division of Bangladesh Agricultural Research Institute, Gazipur during December- March 2014-2015 and 2015-2016 to investigate the effect of irrigation water salinity on the growth, yield components, and yield of wheat. Irrigation with four fixed levels of salinity (4, 7, 10, and 13 dS/m) and one varying level (salinity increased as plants grow older) of saline water was compared with freshwater (<0.5 dS/m) irrigated (control) treatment. All the growth and yield components were found negatively affected by irrigation with different levels of saline water. The decreases of growth and yield parameters were not significant up to the salinity of 7 dS/m. Beyond this, a strong negative effect was observed on almost all growth and yield contributing parameters like plant height, rooting density, leaf area index, spike length, spikelet per spike, number and weight of grain per spike, 1000- grain weight, and biomass yield. In all cases, the highest values were recorded in control and the lowest was recorded in higher levels of salinity (for 13 dS/m in the first year and 16 dS/m in the second year). Irrigation with saline water of 4 dS/m and freshwater gave identical results in terms of growth, yield and yield contributing parameters. Over the years, the highest grain yields of 5.14 and 4.29 t/ha were found in the control treatment and low salinity treatment in the first and second season, respectively, while the lowest yields of 3.58 and 3.03 t/ha were found in the high salinity treatments. On average, compared to the low salinity level, medium (10 dS/m) and high salinity (13 dS/m) levels reduced the grain yield by 20.65 and 31.72% and biomass yield by 20.1 and 33.0%, respectively. Whereas varying levels of salinity reduced the grain yield only by 10.24% and biomass yield by 15.88%. The water use by the crop ranged from 204 to 258 mm in the first season and 212 to 283 mm in the second season with the maximum in no salinity treatment and a minimum in high salinity treatment. Applying varying levels of salinity gave almost similar results in terms of growth, yield, and yield components with 7 dS/m salinity levels. This treatment gave the highest water productivity of 1.70 and 1.88 kg/m³ in the first and second seasons, respectively, with 223 and 243 mm of total water use. Therefore, irrigation with low saline water at the early growth stages and higher salinity water at the later stages might be a good option for growing wheat in a saline environment.

Keywords: Soil salinity, Physiological properties, Wheat

Location: Experimental field of IWM Division of Bangladesh Agricultural Research Institute, Gazipur.

Start Date: 00-00-2015

End Date: 00-00-2016

Program Area: Crop-Soil-Water Management

Commodity: Water salinity, Wheat

Objectives:

The present study, therefore, was undertaken with the objectives,(i) to study the impact of soil salinity on crop physiological properties,(ii) to find out the impact of different salinity levels on grain yield and water use of the wheat crop.

Methodology:

The experimental trial on wheat (variety: BARI Gom- 25) was carried out in the open field during 2014–2015 and 2015 –2016 at the experimental field of IWM Division of Bangladesh Agricultural Research Institute, Gazipur. The soil was sandy clay loam with FC and BD of 28.5% and 1.36 g/cc, respectively. Wheat seeds were sown on 03 December 2014 and 31 November 2015 at a spacing of 20 cm between rows at a seed rate of 120 kg/ha. The unit plot size was 2m ´ 1.8m. The experimental plots were fertilized with N₉₀, P_13, and K₂₅ kg ha^-1 in the form of Urea, TSP and MOP respectively. All the fertilizers and one-third of urea were applied during final land preparation and the rest of urea were applied in two equal splits as top-dressing at 20, and 40 days after sowing. Prior to sowing, NaCl was mixed with the soil to obtain the desired salinity levels of about 5 dS/m to synchronize with the salinity of coastal areas at sowing time. The quantities of water and corresponding NaCl requirement to obtain a given salinity level were calculated using the equation suggested by USDA (1954). In a completely randomized block design, with three replications, five levels of salinity treatments were compared with a freshwater control treatment. The crop received four irrigations each at 20, 40, 60 and 80 days after sowing (DAS). The plots were irrigated up to 100 % of field capacity (F.C.). Among the salinity treatments, four fixed levels and one varying level of saline irrigation water were as follows:

T₁= Irrigation with freshwater (< 0.5 dS/m)

T₂= Irrigation with water having a salinity of 4 dS/m

T₃= Irrigation with water having a salinity of 7 dS/m

T₄= Irrigation with water having a salinity of 10 dS/m

T₅= Irrigation with water having a salinity of 13 dS/m

T₆=Irrigation with water having a salinity of 4, 7, 10, 13 dS/m at 20, 40, 60, and 80 DAS

The soil salinity of the plots was measured five times at sowing, after 3 days of each irrigation, and at harvest by a portable EC meter. All the physiological and yield contributing characters of wheat were recorded. During the cropping season, leaf area index and aboveground biomass were determined at successive phenological stages. Ten plants were cut at ground level and chosen as samples. Then the plant samples were divided into leaves and stems. The leaf area of each plot sample was measured by a leaf area meter. Then the leaves and stems were oven-dried at 70 °C for 48 hours to obtain the weight of above-ground biomass. Biomass was also estimated at the time of harvest. The crops were harvested on 25 March 2015 and 21 March 2016 at hard maturity and manually threshed with 100% grain recovery. The number of spikes per square meter, spike length, spikelet per spike, number and weight of grain per spike, 1000- grain weight, grain, and biological yield were recorded at harvest. Harvest index was calculated by dividing grain yield by biological yield, which was the sum of dry grain weight and dry shoot weight at each harvest sample. The root biomass was measured at harvest from half of the unit soil strip on 30 cm x 20 cm soil surface in the depth increment of 20 cm up to 60 cm, keeping 30 cm row in the middle (Kumar et al., 1993). Finally, analysis of variance of the growth and yield parameters of wheat was done for the RCBD design using MSTAT-C.

Source of Information: Annual Research Report 2015--2016, Irrigation and Water Management Division, BARI, Joydebpur, Gazipur

Article Link (Online Journal):

Funding Source:

Budget:

Total Budget (Tk.) :

Achievement/Findings:

Irrigation with saline water has a detrimental effect on the growth and yield of wheat. Irrigation with saline water having a salinity of 10 and 13 dS/m significantly suppressed most growth, yield, and yield attributes of wheat compared to irrigation by freshwater as well as low saline water. Either irrigation by medium saline water throughout the growing season or irrigation by lower saline water at the early growth stages and higher saline water at the later stages might be a good option for growing wheat in saline areas where freshwater availability for irrigation is very scarce. As irrigation with saline water increased the soil salinity, this should be taken into account whether there is a gradual increase in soil salinity for long-term use of saline water for crop cultivation.

Knowledge Management: Report/Proceedings