STABILITY ANALYSIS OF SOME SOYBEAN GENOTYPES USING PARAMETRIC AND NONPARAMETRIC METHODS IN MULTI-ENVIRONMENTS

Year 2021, Volume: 26 Issue: 2, 262 - 271, 27.12.2021

Pınar Cubukcu Mehmet Kocatürk Emre İlker Abdullah Kadiroğlu Yasemin Vurarak Yeşim Şahin Mehmet Karakuş Ümran Akgün Yıldırım Abdurrahim Göksoy Mehmet Sincik

https://doi.org/10.17557/tjfc.1033363

Cited By: 5

Abstract

Seed yields of 14 soybean genotypes were evaluated in four locations i.e. Adana, Şanlıurfa, Antalya and İzmir under second crop conditions through summer seasons from 2014 to 2016. The aims of research are to estimate the stability parameters in terms of seed yield of 14 soybean genotypes by used different stability analysis methods across eleven environmental conditions and to study interrelationship among these stability methods. The analysis of variance for seed yield revealed that the genotypes and the environments as well as the genotype x environment interactions (GEI) were statistically significant at P<0.01. Environmental effects were contributed of 51.04% to the total sum of squares whereas GEI and genotype effects were 20.8% and 2.59%, respectively. According to most of stability methods, BATEM 223, BATEM 306, BATEM 317 and KASM 02 were determined to be stable genotypes. These genotypes demonstrated superior adaptability with high yield performances in many environments. Results of correlation analysis indicated that seed yield was positively and significantly correlated with Di2 (P<0.01), Si(6) (P<0.05) and TOP (P<0.01) and showed a negative and significant correlation with Pi (P<0.01) and RS (P<0.01). In addition, the coefficient of regression (bi) had positively significant associated with CVi, αi (P<0.01) and Ri2 (P<0.05).

Keywords

Adaptation, Glycine max, Genotype x environment interaction, stability, yield

Supporting Institution

Tübitak

Project Number

113O082

Thanks

The authors thank TUBITAK for their financial support.

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