7
Gholam Reza Pourshaban Kateshali; Gholam-Ali Akbari; Iraj Alahdadi; elias Soltani
Abstract
To evaluate the changes in essential oil and chemical compounds of ginger plant under the influence of irrigation interval and NPK macronutrients, an experiment was carried out using randomized complete blocks in the form of a split plot with 9 treatments and 3 replications in Pakdasht Region, in 2021. ...
Read More
To evaluate the changes in essential oil and chemical compounds of ginger plant under the influence of irrigation interval and NPK macronutrients, an experiment was carried out using randomized complete blocks in the form of a split plot with 9 treatments and 3 replications in Pakdasht Region, in 2021. Treatments included irrigation internals at three levels: V1=4, V2=6, and V3=8 days, as the main factor, and NPK at three levels, F1= (N: 300, P: 100, K: 200), F2= (350, 150, 250), F3 :( 250, 50, 150) (kg.ha-1) as the sub-factor. Extraction of essential oil in this research was done by distillation with water using a Cloninger machine, and the analysis of essential oil compounds was done by gas chromatograph, and 34 chemical compounds were identified. The main components of essential oil in terms of percentage included (α-zingiberene=23.65), (geranial=11.09), (camphene=9.58), (β-sesquiphellandrene =8.43), (β-bisabolene=3.75) and (α-curcumene=2.6). These 6 compounds included 59.1% of the total ginger essential oil, and the other 28 compounds made up only 40.9% of the total essential oil. The results of analysis of variance showed that the interaction effect of irrigation and studied fertilizers on essential oil and main compounds of ginger essential oil were significant at the 1% probability level. The best treatments for essential oil and camphene traits were V1F3, geranial V3F2, α-zingiberene V1F2, and for three traits of α-curcumene, β-bisabolene, and β-sesquiphellandrene was V3F3. Some of the compounds in ginger essential oil were increased by optimal irrigation and supply of essential nutrients for the plant, but some compounds increased under water stress and insufficiency of NPK.
m y; j s; Mohammad Ebrahim Banihabib; a r; a r; e s
Abstract
Due to extensive agricultural activities on the plains and the use of chemical fertilizers containing nitrogen, significant amount of this element enter the aquifer. On the other hand, effluent of wastewater treatment plants is used in irrigation and drainage networks as an alternative or supplementary ...
Read More
Due to extensive agricultural activities on the plains and the use of chemical fertilizers containing nitrogen, significant amount of this element enter the aquifer. On the other hand, effluent of wastewater treatment plants is used in irrigation and drainage networks as an alternative or supplementary source of surface water. Therefore, adoption of strategies for reducing and controlling the amount of nitrogen that enters the soil and aquifer is an important issue. The aim of this research was to develop a cropping pattern optimization model by quantitative-qualitative conjunctive use of unconventional surface water (wastewater) and groundwater. The three objectives of the model were maximizing profits from cropping pattern, reducing nitrogen leaching, and improving the rate of aquifer recharge. In order to integrate management of wastewater and irrigation water resources, the nonlinear three-objective optimization model was run for 7 scenarios (one-objective, two-objectives, and three-objectives) in water year 2012-2013, for Varamin irrigation network. The input data required for the model were collected in two ways: regional testing and obtaining information from various institutions.Solving one-objective model by first objective (first scenario: improving the network’s profit) showed the 49 percent improvement in the network’s net profit. The second objective (second scenario: reducing of fertilizer consumption) showed 95% reduction of fertilizer consumption, and the third objective (third scenario: improving the aquifer recharge) showed 120% improvement in the aquifer recharge, in comparison to the current situation. Solving the three-objective model (seventh scenario: combined objectives of improving network’s net profit, reducing fertilizer consumption, and improving the aquifer recharge) showed a reduction of 23% in cultivated area, 71% in nitrogen fertilizer consumption, and 13% in conjunctive withdrawals of wastewater and groundwater. Also, these reductions increase net benefit by 6%, aquifer recharge by 29%, and water productivity by 22%. Therefore, the seventh scenario was chosen as the best scenario. The results of this research could be adopted for optimum use of water resources, increasing farmers’ benefit, and decreasing nitrogen leaching in irrigation network projects. However, it is to be noted that, generally, use of wastewater for irrigation of food crops is not recommended.