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Research Article

Determining the Performance of Some Soybean Genotypes in Middle Black Sea Transitional Zone

Ahmet KINAY *1Mehtap SARIOGLAN1Erdem KARAKOC1
Published 30-09-2020

DOI

http://dx.doi.org/10.22573/spg.ijals.020.s122000100

AUTHOR AFFILIATION

1Tokat Gaziosmanpasa University, Faculty of Agriculture, Department of Field Crops, Tokat, Turkey

ABSTRACT

This research was carried out in 2017 and 2018 to determine the agronomic and chemical quality characteristics of 18 soybean genotypes including seven advanced lines and eleven cultivars under Tokat-Kazova conditions. The feasibility of soybean production in the region has been determined to create a database that may contribute to the oilseed deficit in the future. The phenological (germination, first flowering and physiological maturity) and morphological characteristics (plant height, number of side branches, first pod height, number of pods per plant, number of grains per pod, 1000-seed weight, seed yield, oil ratio, oil yield, protein ratio and yield) were examined in the study. All properties except number of grains per pod were significantly (p<0.01 and p<0.05) different between genotypes. The seed yield varied between 1.82 and 3.00 t ha-1, oil ratio was between 19.73 and 25.20% and protein ratio was between 30.39 and 43.44%. The results of the study revealed that genotypes of 1, 2, 3 and 9 for the seed yield, 1, 7 and 8 for the oil yield and 1, 2 and 9 for the protein yield can be promising under Tokat-Kazova conditions. However, more efficient cultivars are needed due to the insufficient performances of the genotypes investigated.

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KEYWORDS

Glycine max.(L) Merrill, Oil Yield, Protein Yield, Seed Yield
Figure 1. Biplot graph with dispersion of the 18 soybean genotypes for the traits      Figure 1. Biplot graph with dispersion of the 18 soybean genotypes for the traits       Figure 2. Biplot of PCA1 and PCA2 scores obtained from yield and yield components data of 18 genotypes Figure 2. Biplot of PCA1 and PCA2 scores obtained from yield and yield components data of 18 genotypes  
REFERENCES
  1. Abebe T.D., Bauer A. M., & Leon J. (2010). Morphological diversity of Ethiopian barleys (Hordeum vulgare L.) in relation to geographic regions and altitudes. Hereditas 147:154-164
  2. Bakal H., Arıoğlu H., Güllüoğlu L., Kurt C., & Onat B. (2016). The determination of some important agronomical and quality properties of soybean (Glycine max (L.) Merrill) varieties in double cropped conditions. Journal of Field Crops Central Research Institute 25(2): 125-130
  3. Cevik M. (2006). Effect of the sowing depth on the yield, yield components and quality at dry bean varieties. Selcuk University, Turkey
  4. Ertas A. (2017). Determination of yield and yield components of some soybean (Glycine max. (L.) Merrill) varieties under Sanliurfa ecological conditions. Harran University, Turkey
  5. Gaweda D., Haliniarz M., Cierpiala R., & Klüsek I. (2017). Yield, weed infestation and seed quality of soybean (Glycine max (L.) Merrill) under different tillage systems. Journal of Agricultural Sciences. 23: 268-275
  6. Gizlenci S., Ustün A., Acar M., Dok M. and Aygün Y. (2005). Determination of the most suitable optimum sowing time for middle earlier and earlier soybean cultivars in the Middle Blacksea Coastal Region. In: Proceedings of the Turkey VI. Field Crops Congress, 5-9 September, Antalya, pp. 381-386
  7. Günes A. (2006). Effects of different nitrogen doses and application time on yield and yield components of soybean (Glycine max (L.) Merrill ) cultivated as second crop. Harran University, Turkey
  8. Ilker E., Kocaturk M., Kadiroglu A., Altinbas M., Yildirim A., Ozturk G., & Yildiz H. (2018). Stability analyses for double cropping in soybean (Glycine max (L.) Merrill). Turkish Journal of Field Crops 23(2): 80-84
  9. Internet1: Food and Agricultural Organizations (2017). Food and Agriculture Organization, provides free access to food and agriculture data. December, 30, 2019 from http://www.fao.org/faostat/en/#data/QC
  10. Internet2: Turkish Statistical Institute (2019). Turkey oilseeds production. December, 30, 2019 from http://www.tuik.gov.tr/UstMenu.do?metod=temelist
  11. Kacar B. (2012).  Analyses of Soil. Nobel Publishing. Ankara, Turkey.
  12. Liu X., Wu J A., Ren H., Qi Y., Li C., Cao J., Zhang X., Zhang Z., Cai Z., & Gai J. (2017). Genetic variation of world soybean maturity date and geographic distribution of maturity groups. Breed Sci. 67(3): 221-232
  13. Mert M., & Ilker E. (2016). Studies on adaptation abilities of some soybean (Glycine max (L.) Merrill) varieties and lines under main crop conditions of Aksaray region. Journal of Field Crops Central Research Institute 25(2): 176-181
  14. Nonoy B.B., Justin E.A., Michael B.K., Robert M.S., James E.S., George L.G., & Aaron J.L. (2017). Dissecting the genetic basis of local adaptation in soybean. Scientific reports 7, Article number: 17195
  15. Onat B., Bakal H., Gulluoglu L., & Arioglu H. (2017). The effects of high temperature at the growing period on yield and yield components of soybean (Glycine max (L.) Merrill) varieties. Turkish Journal of Field Crops 22(2): 178-186
  16. Singh G., & Shivakumar B.G. (2010). The role of soybean in agriculture. In: B Singh, The Soybean: Botany, Production and Uses, CAB International, UK, pp. 24–47
  17. Tsindi A., Kawuki R., & Tukamuhabwa P. (2019). Adaptation and stability of vegetable soybean genotypes in Uganda. African Crop Science Journal 27(2): 267-280
  18. Unal I. (2007). Determination of some agricultural characteristics of the soybean (Glycine max (L.) Merrill) lines obtained using the hybridization method. Selcuk University, Turkey
  19. Wang X., Feng G., Deng Z., Wang W., & Jin L. (2013). Microsporogenesis and microgametogenesis of male-sterile mutant ms1 in alfalfa. Crop Science 53: 679-687.

ARTICLE HISTORY

Received: June 2020 / Accepted: July 2020 / Published: Sep 2020

COPYRIGHT

© 2020 Kinay, A., et al. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the Original work is properly cited.

COMPETING INTERESTS

The authors have declared that no competing interests exist.

HOW TO CITE THIS ARTICLE

Kinay, A., Sarioglan, M., & Karakoc, E. (2020). Determining the Performance of Some Soybean Genotypes in Middle Black Sea Transitional Zone. Int J Agric Life Sci, 6(3), 293-299. doi: 10.22573/spg.ijals.020.s122000100.


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