Fatemeh Mirzaei; Mohammad Rafieiolhossaini; Nafiseh Rangzan; Mahdi Amirusefi
Abstract
Objective: Quinoa, with its high nutritional value, is highly resistant to a wide range of non-biological stresses. Despite the limited resources and the increasing demand for food products in lands with low or limited fertility, it can be cultivated well and produces a good product.
Methods: This experiment ...
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Objective: Quinoa, with its high nutritional value, is highly resistant to a wide range of non-biological stresses. Despite the limited resources and the increasing demand for food products in lands with low or limited fertility, it can be cultivated well and produces a good product.
Methods: This experiment was conducted with the aim of investigating the simultaneous effect of drought stress and heavy metals on the quinoa plant, in a factorial format in a completely randomized design with 3 replications. The first component involved two levels of soil (contaminated and uncontaminated), and the second factor, three levels of drought stress (100% of field capacity 60% of field capacity, and 30% of field capacity).
Results: Interaction effect of soil type and drought stress was significant on all traits except the fresh weight of shoot and plant height. The lowest amount of fresh and dry weight of roots, dry weight of shoot and weight of thousand seeds was observed in contaminated soil with severe drought stress. Nevertheless, the weight of 1000 quinoa seeds under the influence of moderate drought stress was not significantly different from the condition without drought stress. Examining the simple effects showed that soil contamination with heavy metals caused a decrease of 13.7% in fresh weight of shoot and 30.5% decrease in dry weight of shoot compared to plants grown in uncontaminated soil.
Conclusion: In general, it can be stated that the increase in drought stress has significantly reduced root fresh weight and 1000 seed weight in quinoa, but the percentage and ratio of this reduction in soil contaminated with heavy metals was much higher than that of non-contaminated soil. According to the results of this research, the cultivation of quinoa can be investigated as a promising plant in soils with similar limitations.
Mostafa Ebrahimikia; Matin Jami Moeini; Hamid Marvi; Yousef Hasheminejhad; Mohammad Ghasemzadeh Ganjehie
Abstract
To investigate the effects of row spacing and nitrogen application rate on growth and yield of quinoa, a split plot experiment has been conducted in a randomized complete block design with three replications in Sabzevar during 2018. The studied factors include row spacing at three levels (25, 50, and ...
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To investigate the effects of row spacing and nitrogen application rate on growth and yield of quinoa, a split plot experiment has been conducted in a randomized complete block design with three replications in Sabzevar during 2018. The studied factors include row spacing at three levels (25, 50, and 75 cm) and nitrogen application rate at four levels (0, 50, 100, and 150 kg N ha-1). Results show that the highest content of photosynthetic pigments, panicle length, number of seeds per plant, and biological yield belong to 150 kg N ha-1 treatment. However, the 100 kg N ha-1 treatment has had the highest number of panicles per plant (19.24) and 1000-seed weight (3.51 g). More row spacing has resulted in more chlorophyll contents, plant height, number of panicles, panicle length, and number of seeds per plant, but less 1000-seed weight, seed yield, and biological yield. The decrease in seed yield by increasing the row spacing to 50 and 75 cm has been 18.62 and 50.14%, respectively. The highest seed yield (6644.5 kg ha-1) has been produced via application of 150 kg N ha-1 at a row spacing of 25 cm. With increasing row spacing, nitrogen requirement to produce maximum seed yield declines. Thus, the highest seed yield in 75, 50, and 25 cm rows spacing are produced with the application of 50, 100, and 150 kg N ha-1, respectively. According to the results, the application of 150 kg N ha-1 and row spacing of 25 cm is recommended for planting quinoa, Sajama genotype.
Faezeh Heidari; Jalal Jalilian; esmaeil gholinezhad
Abstract
This experiment was conducted to investigate the effect of foliar application different nano-fertilizers on modulating negativeeffectsof salt stress on quinoa, in factorial experiment based on completely randomized design with three replications in the research farm of Urmia University in the pot during ...
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This experiment was conducted to investigate the effect of foliar application different nano-fertilizers on modulating negativeeffectsof salt stress on quinoa, in factorial experiment based on completely randomized design with three replications in the research farm of Urmia University in the pot during 2018. The first factor was salinity of irrigation water using (Lake Urmia water at three levels: 0, 16 and 32 dS/m and the second factor was nano-fertilizers at five levels: calcium, silicon, zinc, potassium and control (no foliar application). The results showed that salinity stress caused negative effects on all traits affecting quinoa growth. The highest decrease in traits was observed in salinity stress of 32 dS/m. Salinity stress of 32 and 16 dS/m compared to control decreased plant height (20 and 17%), inflorescence number (48 and 36%), root volume (44 and 40%), main root length (41 and 23%), root dry weight (68 and 30%), relative leaf water content (26 and 13%), chlorophyll index (15 and 7%) and 1000-seed weight (31 and 23%), respectively; but increased ionic leakage by 14 and 6%, respectively. Foliar application with nano-fertilizer compared to control increased the yield, yield components and morphological traits. The highest seed yield was obtained under optimum conditions and severe salinity stress (32 dS/m) by foliar application with nano-fertilizer of zinc and silicon, respectively. Under severe salinity stress, foliar application with nano-fertilizer of silicon compared to non-foliar application increased the dry weight of inflorescences, total dry weight and seed yield by 35%, 16% and 43%, respectively, and moderated the effects of salinity stress. Foliar application with nano-fertilizer via enhancing chlorophyll index, relative leaf water content and improving root characteristics, led to increase yield and seed yield components of quinoa. Therefore, it seems that foliar application of nano-fertilizers is suitable to improve the yield of quinoa especially in salinity stress conditions.
Mahdi Amirusefi; Mahmoud Reza Tadayon; Rahim Ebrahimi
Abstract
The present experiment has been conducted as a split plot factorial based on completely randomized block design with three replications in 2018-2019 crop season on a saline farm (with an electrical conductivity of 5.2 dS/m) in Dastgerd area, Isfahan Province. Four levels of irrigation (25%, 50%, 75%, ...
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The present experiment has been conducted as a split plot factorial based on completely randomized block design with three replications in 2018-2019 crop season on a saline farm (with an electrical conductivity of 5.2 dS/m) in Dastgerd area, Isfahan Province. Four levels of irrigation (25%, 50%, 75%, and 100% of FC) compose the main factors and biofertilizer (the control, Nitroxin, Biophosphorus, and their combination) as well as chemical fertilizer in two level of no application and integrated application of nitrogen and phosphorus fertilizers are the sub-factor. Severe drought stress (25% FC irrigation treatment) increase the measured traits (antioxidant enzyme activity including catalase, peroxidase, and superoxide dismutase along with Proline and Malondialdehyde content) in quinoa by about 46%, 52%, 142%, 42%, and 39%, compared to non-stress conditions (100% FC irrigation treatment), respectively. Also, they significantly reduce grain and biological yield in this plant (by about 76% and 49%, respectively). However, at all drought stress levels , the combination of nitroxin and biophosphorus under conditions of simultaneous use of chemical fertilizers of nitrogen and phosphorus shows the maximum effect on moderation of drought stress effects, significantly reducing the activity of antioxidant enzymes and, consequently, increasing yield, compared to other treatments at the same drought level. Overall, the results demonstrate that despite the salinity of the tested soil, quinoa has been able to complete its growth and seed production even under severe drought stress conditions.