Yield of Safflower (Carthamus tinctorius L.) Cultivars in Response to Phosphorus Application and Its Efficiency Indices

Document Type : Research Article

Authors

1 Soil and Water Research Department, Safiabad Agricultural Research and Education and Natural Resources Center, Agricultural Research, Education and Extension Organization, AERRO, Dezful

2 Agricultural Engineering Research Department, Safiabad Agricultural Research and Education and Natural Resources Center, Agricultural Research, Education and Extension Organization, AERRO, Dezful

3 Soil and Water Research Institute, Agricultural Research, Education and Extension Organization, AERRO, Karaj

Abstract

Introduction: Phosphorus is the third most important nutrient in crop production after nitrogen and potassium. It is involved in all biochemical processes, energetic compounds, and energy transfer mechanisms. Phosphorus participates in the cellular proteins and cell membrane and nucleic acids. In addition, this element is essential for seed formation and root development. Also, this element recovery in the first year of application estimates to be 8 to 30%, and after 30 years rarely reaches to 50% and its rest is stabilized in the soil and accumulates inaccessibly for most plants. Therefore, in the last two decades, scientists have used various methods to improve the efficiency of phosphorus, including the selection and genetic modification of plants and the adopting agricultural practices such as determining the optimal amount of phosphorus, the right time and method of application and the right fertilizer source. In addition, due to the growing trend of vegetable oil consumption and the high cost of supplying the required oil through imports, the purpose of this study was to determine the optimal rate of phosphorus and selecting the appropriate efficient cultivar in order to extend oilseed crops cultivation.
Materials and Methods: In order to study the response of safflower cultivars (Carthamus tinctorius L.), to phosphorus rates and their efficiency indices, a factorial experiment was conducted in a randomized complete block design with three replications during 2012-13 and 2014-15 at Safiabad Agricultural Research Center of Dezful, Khuzestan, Iran. The first factor included five phosphorus levels (0, 50,100, 150 and 200 kg ha-1 as Triple Super Phosphate "TSP"), and the second factor included two cultivars (Goldasht and Soffeh). Safflower seeds were planted by setting up a sugar beet planter, in a row with a distance of 50 cm between rows and a distance of 5 cm between plants. Urea and potassium sulfate were uses at 300 and 100 kg ha-1, respectively. One-third of nitrogen and all phosphorus and potassium were used pre planting. The rest of urea fertilizer was applied as top dressing in two equal splitting rates (beginning of stem and early flowering stages). Before harvesting in each replication, the number of fertile heads per square meter (in three boxes of one square meter per plot), and the number of full grains (counting full grains in 20 heads), and after harvesting the weight of 1000 seeds (with three times counts were calculated in three random groups of 1000 seeds per plot). Finally, number of fertile heads per square meter, number of seeds per heads, 1000-seed weight, seed and oil yields, seed phosphorus uptake, and phosphorus efficiency indices were measured.
Results and Discussion: The results showed that the interaction of treatments was significant on the number of fertile heads per square meter and number of seeds per head. In both cultivars, with increasing phosphorus application, the mentioned traits increased significantly. The highest number of fertile heads (252 pieces), and the number of seeds per head (23.17 pieces), were obtained at the level of 150 kg phosphorus ha-1. The interaction between year and phosphorus on 1000-seed weight and seed yield and the interaction between year and cultivar on 1000-seed weight were significant. The highest 1000-seed weight (42.41 g), and seed yield (2184 kg ha-1), were obtained by application of 100 kg phosphorus ha-1. Seed and oil yields of Soffeh cultivar (1979 and 599 kg ha-1, respectively), was superior to Goldasht cultivar. Also, the results showed that Goldasht cultivar had higher utilization efficiency (248 kg kg-1), compared to Soffeh cultivar (218 kg kg-1). Phosphorus application significantly reduced use and uptake efficiency indices (69% and 85%, respectively). So that the treatment without phosphorus application had the highest use and uptake efficiency (1 kg kg-1). The difference between use and uptake efficiency at the level of 50 kg phosphorus ha-1 with other phosphorus levels was about 19% and 25%, respectively.
Conclusions: In general, due to the highest benefit-to-cost ratio (35.51) and use and uptake efficiency indices (0.69 and 0.7 kg .kg-1, respectively), application of 50 kg ha-1 of phosphorus fertilizer and Soffeh cultivar is recommended.

Keywords

References

  1. Abbadi, J., and Gerendas, J. 2011. Effects of phosphorus supply on growth, yield, and yield components safflower and sunflower. Journal of Plant Nutrition 34: 1769-1787.
  2. Abbadi, J. 2017. Phosphorous use efficiency of safflower and sunflower grown in different soils. World Journal of Agricultural Research 5 (4): 212-220.
  3. Abbadi, J., Dittert, K., Steingrobe, B.,and Claassen, N. 2017. Mechanisms of phosphorous uptake efficiency of safflower and sunflower grown in different soils. Research in Plant Sciences 5 (1): 26-42.
  4. Afzal, O., Asif, M., Ahmed, M., Awan, F. K., Aslam, M. A., Zahoor, A., Bilal, M., Shaheen, F. A., Zulfiqar, M. A., and Ahmed, N. 2017. Integrated nutrient management of safflower (Carthamus tinctorius L.) under rainfed conditions. American Journal of Plant Science 8: 2208-2218.
  5. Ahmadpour Abnavi, S., Ramroudi, M., and Galavi, M. 2019. Effect of biological and chemical phosphorus fertilizer on yield and yield components of safflower (Carthamus tinctorius L.) under low irrigation condition. Agricultural Science and Sustainable Production 29 (1): 269-284. (in Persian).
  6. Akhtar, M. Sh., Oki, Y., and Adachi, T. 2008. Phosphorus and biomass distribution and Pefficiency by Diversa Brassica cultivars exposed to adequate and p- stress environment. Journal of Environmental Science and Technology 1: 111-119.
  7. Ali Ahyaei, M., and Bebahani Zadeh, A. A. 1993. Description of Soil Chemical Analysis Methods. Technical Journal 893. Soil and Water Research Institute. (in Persian).
  8. Alizadeh, K., and Carapetian, J. 2006.Genetic variation in a safflower germplasm grown in rainfall cold drylands. Agronomy Journal 5: 50-52.
  9. Arsalan, B., and Cuplan, E. 2018. Identification of suitable safflower genotypes for the development of new cultivars with high seed yield, oil content and oil quality. Azarian Journal of Agricultural 5 (5): 133-141.
  10. Blackwell, M., Darch, T., and Haslam, R. 2019. Phosphorus use efficiency and fertilizers: future opportunities for improvements. Frontiers of Agricultural Science and Engineering 6 (4): 332-340.
  11. Balcha, A. 2014. Effect of phosphorus rates and varieties on grain yield, nutrient uptake and phosphorus efficiency of Tef [(Eragrostis tef (Zucc)] Trotter. American Journal of Plant Science 5: 262-267.
  12. Bonfim -Silva, E. M., Dourado, L. G. A., Soares, D. S., Santos, T. M., da Silva, T. J. A., and Fenner, W. 2019. Reactive natural phosphate in safflower fertilization in Cerrado Oxisol. Journal of Agricultural Science 11 (15). 142-135.
  13. Bonfim-Silva, E. M., Miranda, L. F. S., Das Neves, L. C. R., FreitasSousa, H. H., and Jose, J. V. 2017. Phytometric and productive characteristics of safflower submitted to phosphate fertilization in the Oxisol of the Brazilian Cerrado. American Journal of Plant Science 8 (1): 2966-2976.
  14. da Anicesio, E. C. A., Bonfim- Silva, E. M., da Silva, T. J. A., and Koetz, M. 2015.Dry mass, nutrient concentration and accumulation in safflower (Carthamus tinctorius L.) influenced by nitrogen and potassium fertilizations. Australian Journal of Crop Science 9 (6): 552-560.
  15. J. da Silva, C., da Silva, A. C., Zoz, T., Victor, B., Toppa, E., Silva, P. B., and Zanotto, M. D. 2015. Genetic divergence among accessions of Carthamus tinctorius L. by morphoagronomic traits. African Journal of AgriculturalResearch10 (25): 4825-4830.
  16. Devi, K. N., Singh, L. N. K., Devi, T. S., Devi, H. N., Singh, T. B., Singh, K. K., and Singh, W. M. 2012. Response of soybean (Glycine max (L.) Merrill) to sources and levels of phosphorus. Journal of Agricultural Science 4 (6): 44-53.
  17. Duan, H. Y., Shi, L., Ye, X. S., Wang, Y. H., and Xu, F. S. 2009. Identification of phosphorus efficient germplasm in oilseed rape. Journal of Plant Nutrition 32: 1148-1163.
  18. Ebrahimian, A., and Soleymani, A. 2013.Growth length and dry matter yield in different stages of safflower as affected by nitrogen, phosphorus and potassium fertilizers. International Journal of Agronomy and Plant Production 4 (5): 963-969.
  19. Emami, A. 1996. Plant Analysis Methods. Volume I, Technical Journal No. 982, Soil and Water Research Institute. (in Persian).
  20. Ghaderi, J., and Nourgholipour, F. 2020. Effects of Phosphorus on grain yield and phosphorus efficiency indices in canola cultivars in Kermanshah region. Journal of Water and Soil (Agricultural Sciences and Technology) 34 (2): 439-453. (in Persian with English abstract).
  21. Golzarfar, M., Shiranirad, A. H., Delkhosh, B., and Bitarafan, Z. 2012. Safflower (Carthamus tinctorius L.) response to different nitrogen and phosphorus fertilizer rates in two planting seasons. Zemdirbyste-Agriculture 99 (2): 159-166.
  22. HaghighatiMalek, A., and Ferri, F.2014. Effects of nitrogen and phosphorus fertilizers on safflower yield in dry lands condition. International Journal of Research in Agricultural Sciences 1 (1): 2348-23.
  23. Hashemi dezfuli, A. H., Koocheki, A., and Banayan, M (Translation). 1995. Maximizing Crop Yields. Mashhad University, Iran. (in Persian).
  24. Heidari, M., Sobhkizi, A. R., Mahmoody, M., and Noori, M. 2014. Evaluation of phosphorus fertilizer and azospirllum on number of head, number of branch and plant height on safflower. International Journal of Biosciences 5 (1): 455-460.
  25. Heshmati, S., Amini Dehghi, M., and Fathi Amirkhiz. 2017. Effects of biological and chemical phosphorus fertilizer on grain yield, oil seed and fatty acids spring safflower in water deficit conditions. Iranian Journal of Field Crop Science 48 (1): 159-169. (in Persian with English abstract).
  26. Hosseini, Z. 2007. Description of Common Methods in Food Analysis. Shiraz University, Iran. (in Persian).
  27. Hunter, P. J., Teakle, G. R., and Bending, G. D. 2014. Root traits and microbial community interaction on relation availability and acquisition, with particular reference to Brassica. Frontiers in Plant Science 5: 1-18.
  28. Jalilian, J., and Heydarzadeh, S. 2015. The effect of cover plants, organic and chemical fertilizers on the qualitative and qualitative characteristics of safflower (Carthamus tinctorius) . Journal of Agricultural Knowledge and Sustainable Production 25 (4): 71-85. (in Persian with English abstract).
  29. Kassray, R. 1993. An Overview of The Science of plant Nutrition (Translation). Tabriz University, Iran. (in Persian).
  30. Killi, F., Kanar, Y., and Tekeli, F. 2016. Evaluation of seed and oil yield with some yield components of safflower varieties in Kahramanmaras (Turkey) conditions. International Journal of Environmental and Agricultural Research 2 (7): 136-140.
  31. Mirzashahi, K., Salimpour, S., and Paknejad, A. R. 2015. Fertilizer recommendations for crops and gardens in northern Khuzestan. Technical Journal, No. 536. Soil and Water Research Institute, Karaj, Iran. (in Persian).
  32. Noushahi, H. A., Hussain, M., Bilal, M., Salim, M. A., Idress, F., Jawad, M., Rizwan, M., Atta, B., and Tanveer, K. 2019. Improving phosphorus use efficiency by agronomical and genetic means. World Journal of Agricultural Science 15 (2): 47-53.
  33. Ozturk, L., Eker, S., Torun, B., and Cakmak, I. 2005.Variation in phosphorus efficiency among 73 bread and durum wheat genotypes grown in phosphorus- deficient calcareous soil. Plant and Soil 269: 69-80.
  34. Paludo, J. S., Bonfim-Silva, E. M., Silva, T. J. A., Zanatto, M. D., Fenner, W., and Koetz, M. 2017. Reproductive components of safflower genotype submitted of bulk density levels in the Brazilian Cerrado. American Journal of Plant Science 8 (1): 2069-2082.
  35. Park, J. H., Bolan, N., Megharaj, M., and Naidu, R. 2011. Isolation of phosphate solubilizing bacteria, and their potential for lead immobilization in soil. Journal of Hazardous Materials 185: 829-36.
  36. PRII. 1996. Internal Report. Potash Research Institute of India. Gurgaon, Haryana, India.
  37. Rose, T. J. M., and Wissuwa, M. 2012. Rethinking internal phosphorus utilization efficiency: a new approach is needed to improve PUE in grain crops. Advances in Agronomy116: 185-217.
  38. Sepehr, E. 2008. Investigation of mechanisms of response of cereals to phosphorus deficiency. PhD Thesis, Faculty of Agriculture, Tarbiat Modares University, Tehran, Iran.
  39. Sofy, S. O., Hama, S. J., and Hamma-Umin, B. O. 2020. Influence of phosphorus fertilizer on yield and oil of safflower (Carthamus tinctorius) varieties under rainfed condition. Applied of Ecology and Environmental Research 18 (2): 3409-3418.
  40. Tehrani, M. M., Balali, M. R., Moshiri, F., and Daryashenas, A. 2012. Recommendation and the estimation of mineral fertilizers in Iran: Challenges and Solutions. Research of Soil 26 (2): 123-144.
  41. Vafaie, A., Ebadi, A., Rastgou, B., and Moghadam, S. H. 2013.The effects of potassium and magnesium on yield and some physiological traits of safflower (Carthamus tinctorius L.). International Journal of Agricultural and Crop Sciences 5 (17): 1895-1900.
  42. Wang, X., Shen, J., and Liao, H. 2010. Acquisition or utilization, which is more critical for enhancing phosphorus efficiency in modern crops? Plant Science 179 (4): 302-306.
  43. Wei, Y., Zhao, Y., Fan, Y., Lu, Q., Li, M., and Wei, Q. 2017. Impact of phosphate solubilizing bacteria inoculation methods on phosphorus transformation and long-term utilization in composting. Bioresource Technology 241: 134-41.
  44. Yang, G., Zuo, Q., Tang, Y., Shi, J. F., Hui, F. H., and Leng, D. H. 2010. Phosphorus absorbtion and utilization of rapeseed (Brassica napus L.) cultivars.
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Iranian Journal of Field Crops Research
Volume 18, Issue 4 - Serial Number 60
January 2021
Pages 477-488

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History

  • Receive Date: 26 October 2020
  • Revise Date: 26 December 2020
  • Accept Date: 03 January 2021
  • First Publish Date: 03 January 2021

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