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Safflower productivity and oil yield affected by water limitation and nanofertilizers

By: Kazem Ghassemi-Golezani, Nafiseh Afkhami

Key Words: Nano-fertilizer, Oil content, Safflower, Water limitation, Yield components

J. Bio. Env. Sci. 12(5), 425-431, May 2018.

Certification: jbes 2018 0063 [Generate Certificate]

Abstract

This research was arranged as split plot experiment based on randomized complete block design with three replications in 2017, to investigate the responses of safflower (Carthamus tinctorius L.) to the different levels of irrigation (I1, I2, I3, I4: Irrigation after 70, 100, 130 and 160mm evaporation, for normal irrigation and mild, moderate and severe water deficits, respectively) and foliar sprays of water (control) and nano-fertilizers (SiOand Mn2O3). Means of plant biomass, yield components, oil percentage and grain and oil yields were decreased under moderate and severe water limitations. However, foliar sprays of nano-SiO2 and nano-Mn2O3 increased grain and oil yields via enhancing plant biomass, grains per plant, 1000 grains weight and oil content under different irrigation intervals, especially under stressful conditions. Therefore, foliar application of nano-fertilizers can be used to improve safflower productivity and oil yield under normal and limited irrigation conditions.

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Safflower productivity and oil yield affected by water limitation and nanofertilizers

Ashrafi A, Razmju C. 2014. Effect of seed priming and irrigation on grain yield, biological yield, oil and protein content of seeds of different varieties of safflower (Carthamus tinctorius L.). Journal of Agricultural Research and Development 103, 61–68.

Bhardwaj HL, Hamama AA. 2003. Accumulation of glucosinolate, oil and erucic acid in developing Brassica seeds. Industrial Crops and Products 17, 47–51.

Coşge B, Kiralan M, Hassanien MFR. 2015. Impact of harvest times on the quality characteristics of oils recovered from different safflower (Carthamus tinctorius) cultivars sown in spring and autumn. European Food Research and Technology 242, 371-381.

Dordas CA, Sioulas C. 2008. Safflower yield, chlorophyll content, photosynthesis, and water use efficiency response to nitrogen fertilization under rainfed conditions.  Industrial Crops and Products 27, 75-85.

Ghassemi-Golezani K, Afkhami N. 2018. Changes in some morpho-physiological traits of safflower in response to water deficit and nano-fertilizers. Journal of Biodiversity and Environmental Sciences (In press).

Ghassemi-Golezani K, Ghanehpoor S, Dabbagh Mohammadi-Nasab A. 2009. Effects of water limitation on growth and grain filling of faba bean cultivars. Journal of Food, Agriculture and Environment 7, 442-447.

Ghassemi-Golezani K, Hassanpour-Bourkheili S, Bandeh-Hagh A, Abriz SF. 2014. Seed hydropriming, a simple way for improving mung-bean performance under water stress. International Journal of Biosciences 4, 12-18.

Ghassemi-Golezani K, Maghferati R, Zehtabsalmasi S, Dastborhan S. 2016. Influence of water deficit and nitrogen supply on grain yield and yield components of safflower. Advanced Biomedical Research 7, 132-136.

Ghassemi-Golezani K, Mustafavi SH, Shafagh-Kalvanagh J. 2012. Field performance of chickpea cultivars in response to irrigation disruption at reproductive stages. Research on Crops 13, 107-112.

Gilbert J, Knights SE, Potter TD. 2008. International safflower production. Agri-MC Marketing and Communication 10, 1–7.

Golparvar A, Ghasemi A. 2007. Study the drought tolerance of spring safflower cultivars in Isfahan area. Journal of Research in Agricultural Sciences 4.

Istanbulluoglu A, Gocmen E, Gezer E, Pasa C, Konukcu F. 2009. Effect of water stress at different development stages on yield and water productivity of winter and summer safflower (Carthamus tinctorius). Agricultural Water Management 96, 1429-1434.

Janmohammadi M, Amanzadeh T, Sabaghnia N, Ion V. 2016a. Effect of nano-silicon foliar application on safflower growth under organic and inorganic fertilizer regimes. Botanica Lithuanica 22, 53-64.

Janmohammadi M, Seifi A, Pasandi M, Sabaghnia N. 2016b. The impact of organic manure and nano-inorganic fertilizers on the growth, yield and oil content of sunflowers under well-watered Conditions. Biologija 62, 227–241.

Karunakaran G, Suriyaprabha R, Manivasakan P, Yuvakkumar R, Rajendran V, Prabu P, Kannan N. 2013. Effect of nanosilica and silicon sources on plant growth promoting rhizobacteria, soil nutrients and maize seed germination. IET Nanobiotechnology 7, 70-77.

Khan HR, McDonald GK, Rengel Z. 2003. Zn fertilization improves water use efficiency, grain yield and seed Zn content in chickpea. Plant and Soil   249, 389-400.

Mohammadi M, Ghassemi-Golezani K, Chaichi MR, Safikhani S. 2018. Seed oil Accumulation and Yield of Safflower Affected by Water Supply and Harvest Time. Agronomy Journal 110, 586-593.

Prasad PVV, Staggenborg SA, Ristic Z. 2008. Impacts of drought and/or heat stress on physiological, developmental, growth, and yield processes of crop plants. Response of crops to limited water: Understanding and modeling water stress effects on plant growth processes p. 301-355.

Rauf S. 2008. Breeding sunflower (Helianthus annuus L.) for drought tolerance. Communications in Biometry and Crop Science 3, 29-44.

Saqib M, Zörb C and Schubert S. 2008. Silicon-mediated improvement in the salt resistance of wheat (Triticum aestivum) results from increased sodium exclusion and resistance to oxidative stress. Functional Plant Biology 35, 633-639.

Sarkar D, Mandal B, Kundu MC. 2007. Increasing use efficiency of boron fertilisers by rescheduling the time and methods of application for crops in India. Plant and soil 301, 77-85.

Senkal BC, Kiralan M, Ramadan MF. 2016. Impact of harvest times on the quality characteristics of oils recovered from different safflower (Carthamus tinctorius) cultivars sown in spring and autumn. European Food Research and Technology 242, 371-381.

Sharma CP, Khurana N, Chatterjee C. 1995. Manganese stress changes physiology and oil content of linseed Linum usitatissimum L. Indian Journal of Experimental Biology 33, 701-707.

Siddiqui MH, Al-Whaibi MH, Firoz M, Al-Khaishany MY. 2015. Role of nanoparticles in plants.  Nanotechnology and Plant Sciences 10, 19-35.

Soleimanzadeh H, Gooshchi F. 2012. Effect of rapid canopy development on grain yield of safflower in the north of Iran. World Applied Sciences Journal 18, 1-5.

Tahmasebpour B, Aharizad S, Shakiba M, Bedostani AB. 2011. Safflower genotypes responses to water deficit. International Journal of AgriScience 1, 97-106.

Xie Y, Niu J, Gan Y, Gao Y, Li A. 2014. Optimizing phosphorus fertilization promotes dry matter accumulation and P remobilization in oilseed flax. Crop Science 54, 1729–1736.

Kazem Ghassemi-Golezani, Nafiseh Afkhami.
Safflower productivity and oil yield affected by water limitation and nanofertilizers.
J. Bio. Env. Sci. 12(5), 425-431, May 2018.
https://innspub.net/jbes/safflower-productivity-oil-yield-affected-water-limitation-nanofertilizers/
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