Crops ›› 2025, Vol. 41 ›› Issue (4): 80-86.doi: 10.16035/j.issn.1001-7283.2025.04.010

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Comprehensive Analysis of High Yield and High Quality Sesame Shangzhi 6 Based on GGE Biplot and TOPSIS Method

Lü Shuli(), Tian Zhuangbo, Ding Fang, Lü Zhuoyang   

  1. Shangqiu Academy of Agriculture and Forestry Sciences, Shangqiu 476000, Henan, China
  • Received:2025-01-09 Revised:2025-03-20 Online:2025-08-15 Published:2025-08-12

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Abstract:

In order to accurately evaluate the high and stable yield, adaptability and comprehensive trait of sesame variety Shangzhi 6, and promote the production and breeding utilization of the variety. Based on the field trials data of Shangzhi 6 at 11 experimental sites in the Huang-Huai area for two years, the GGE biplot and TOPSIS method were used to comprehensively analyze it. The results showed that the average contents of fat and protein of Shangzhi 6 were 54.02% and 21.50% in two years, respectively. The comprehensive disease resistance was resistance to stem spot blight and high resistance to blight. In the analysis of high and stable yield, the comprehensive evaluation of high and stable yield of Shangzhi 6 in the two years was better than that of the control variety Yuzhi 4, ranking first and fourth, respectively. In the analysis of suitable planting areas, Shangzhi 6 had high yield performance in two years, and there were many suitable planting sites in the Huang-Huai area. In the comprehensive evaluation of variety yield, quality and disease resistance, Shangzhi 6 ranked first and third respectively in two years, which were better than the control varieties. In summary, Shangzhi 6 has good high and stable yield, excellent quality, strong disease resistance and excellent comprehensive traits. It is suitable for promotion and planting in the Huang-Huai area and similar ecological environments.

Key words: Sesame, Shangzhi 6, GGE biplot, TOPSIS method, Comprehensive analysis

Table 1

Field trial varieties and their institutions in 2021-2022"

2021 2022
代号Code 品种Variety 育种单位Breeding institution 代号Code 品种Variety 育种单位Breeding institution
F1 阜芝303 阜阳市农业科学院 H1 漯芝107 漯河市农业科学院
F2 商芝3号 商丘市农林科学院 H2 商芝6号 商丘市农林科学院
F3 驻19B11 驻马店市农业科学院 H3 商芝7号 商丘市农林科学院
F4 漯芝106 漯河市农业科学院 H4 商芝8号 商丘市农林科学院
F5 皖芝24 安徽省农业科学院作物研究所 H5 宛芝23 南阳市农业科学院
F6 驻19B10 驻马店市农业科学院 H6 信芝H12 信阳市农业科学院
F7 商芝6号 商丘市农林科学院 H7 豫芝4号 驻马店市农业科学院
F8 漯芝100 漯河市农业科学院 H8 驻19B10 驻马店市农业科学院
F9 豫芝4号 驻马店市农业科学院 H9 驻19B11 驻马店市农业科学院
F10 阜芝125 阜阳市农业科学院
F11 商芝7号 商丘市农林科学院
F12 周芝23 周口市农业科学院

Fig.1

The yield performance of Shangzhi 6 in field trials in 2021-2022"

Table 2

The quality and disease resistance of Shangzhi 6 in field trials in 2021-2022"

年份
Year		 脂肪含量
Fat content (%)		 蛋白质含量
Protein content (%)		 茎点枯病Stem spot blight 枯萎病Blight
发病率Morbidity (%) 病情指数Disease index 发病率Morbidity (%) 病情指数Disease index
2021 53.42 21.40 16.15 13.94 0.98 0.78
2022 54.61 21.60 10.27 7.58 0.32 0.05
平均Mean 54.02 21.50 13.21 10.76 0.65 0.42

Table 3

Joint variance analysis of yield of tested varieties in field trials in 2021-2022"

年份Year 变异来源Variation source 自由度df 平方和Quadratic sum 均方Mean square FF-value
2021 区组 10 189 412.17 18 941.22
环境(E) 4 49 226 274.58 12 306 569.00 1927.11**
基因型(G) 11 2 998 014.33 272 546.80 42.68**
基因型×环境(GE) 44 6 787 395.42 154 259.00 24.16**
误差 110 702 463.17 6386.03
总变异 179 59 903 559.66
2022 区组 12 83 628.69 6969.06
环境(E) 5 16 436 428.48 3 287 285.70 856.89**
基因型(G) 8 728 657.05 91 082.13 23.74**
基因型×环境(GE) 40 1 909 013.25 47 725.33 12.44**
误差 96 330 691.98 3444.71
总变异 161 19 488 419.44

Fig.2

Yield GGE biplot in field trials in 2021 and 2022"

Fig.3

Functional analysis of suitable planting areas in GGE biplot of yield in field trials in 2021 and 2022"

Table 4

Comprehensive analysis of the main traits of varieties in the field trials in 2021-2022"

年份
Year		 品种代码
Variety
code		 与最优值距离
Distance from the
optimal value		 与最劣值距离
Distance from
the worst value		 统计量
Statistic		 排序
Sort
2021 F1 1.329 1.359 0.506 7
F2 1.106 1.500 0.576 4
F3 1.121 1.542 0.579 3
F4 1.311 1.016 0.437 10
F5 1.518 1.153 0.432 11
F6 1.009 1.404 0.582 2
F7 1.037 1.878 0.644 1
F8 1.531 1.298 0.459 9
F9 1.430 1.072 0.428 12
F10 1.217 1.417 0.538 6
F11 0.972 1.316 0.575 5
F12 1.405 1.315 0.483 8
2022 H1 1.218 1.185 0.493 6
H2 0.879 1.595 0.645 3
H3 1.235 1.557 0.558 4
H4 1.537 1.340 0.466 7
H5 1.679 0.924 0.355 9
H6 1.282 1.362 0.515 5
H7 1.559 1.154 0.425 8
H8 0.711 1.841 0.721 1
H9 0.769 1.784 0.699 2
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