大豆开花落花及时空分布的观察研究

doi:10.3864/j.issn.0578-1752.2013.08.003

Abstract

Abstract: 【Objective】 The whole progress of flowering and flower dropping of soybean were observed, and the characteristics and rules of different varieties were analyzed to provide an evidence for high yield breeding and cultivation. 【Method】 Under the conditions of field experiment, the flowering and flower dropping nodes of 72 individuals of six soybean varieties were observed daily (42 days). 【Result】 Flowering process showed a significant ladder of four stages: early florescence is short (about 3 days), less than 4 flowers per day, the flower amount at this stage is 5.73, 4.09% of the total, concentrated in the middle of plants. At full-bloom stage, the daily flowering 5-12 flowers, the duration is longer (12-18 days), the flowering amount of this stage is 108.75, 77.60% of total, the flowering section extends from the middle to the upper and lower ends, and middle-up. At slow florescence stage, the daily flowering 1-5 flowers, the duration is different among varieties, the flowering amount at this stage is 21.24, 15.16% of total, distributed in various nodes of the plant. At late florescence stage, the daily flowering less than 1 flower, until flowering end, the flowering amount is 4.42, scattered on the plants. Flower dropping generally occurs from early florescence 3 days later to late florescence or after late florescence, the flower dropping section throughout the flower section on the plants, the flower-dropping rate at the full flowering stage (36.97%) is less than at the initial flowering stage (51.76%), its slow flowering stage (65.54%), and its final flowering stage (77.96%). The peak of the abnormal abscission about 3-9 flowers daily is correlated with the rainy day and scant sunlight in that periods. In determinate podding habit varieties, the earliest flowering section is in the middle of the plants, and then extend to upper and lower sections, then extend to the bottom 3-7 days later and extend to the top 9-15 days later after flowering. In semi-determinate podding habit varieties, the earliest flowering section is in the middle and lower parts (7th-10th node), and then extend to upper and lower sections, then extend to the bottom 3-7 days and extend to the top 24-26 days later after initial flowering. 【Conclusion】 The flowering amount, flowering node, duration and abscission rate are all different in early florescence, full-bloom stage, slow florescence and late florescence of soybean.

Key words: soybean , flowering , flower drop , temporal and spatial distribution

ZHAO Shuang-Jin, TANG Xiao-Dong, ZHAO Xin, FENG Yan, ZHAO Cong-Cong, ZHANG Meng-Chen. Observation and Research on the Temporal and Spatial Distribution of Flowering and Flower Dropping of Soybean[J].Scientia Agricultura Sinica, 2013, 46(8): 1543-1554.

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References

[1]孙醒东. 大豆. 北京: 科学出版社, 1956.

Sun X D. Soybean. Beijing: Science Press, 1956. (in Chinese)

[2]盖钧镒. 有限与无限结荚习性夏大豆开花结荚特性的研究. 南京农学院学报, 1984, 4: 6-17.

Gai J Y. Bloom and pod set in determinate and indeterminate summer soybeans. Journal of Nanjing Agricultural University, 1984, 4: 6-17. (in Chinese)

[3]祝其昌. 大豆结荚习性的研究: 1.不同结荚习性的本质区别与分类. 大豆科学, 1984, 4(3): 318-325.

Zhu Q C. Studies on the growth habit of soybean: 1. The substantial difference of different habits of soybean and their classification. Soybean Science, 1984, 4(3): 318-325. (in Chinese)

[4]宋书宏, 董钻. 不同大豆品种开花结荚习性比较. 中国农业科学, 2002, 35(11): 1420-1423.

Song S H, Dong Z. Comparative study on blooming sequence and podding habit of soybeans. Scientia Agricultura Sinica, 2002, 35(11): 1420-1423. (in Chinese)

[5]苏黎, 董钻, 宋书宏. 大豆不同类型品种开花次序观察再报. 杂粮作物, 2004, 2(24): 84-85.

Su L, Dong Z, Song S H. The second report of blooming sequence of different soybeans. Rain Fed Crops, 2004, 2(24): 84-85. (in Chinese)

[6]马国辅, 梁振富, 金家慎. 大豆落花落莢的调查研究. 中国农业科学, 1960, 5: 18.

Ma G F, Liang Z F, Jin J S. Investigation and research on flower and pod drop of soybean. Scientia Agricultura Sinica, 1960, 5: 18. (in Chinese)

[7]高煜珠, 黄湘云, 杨鹤峯. 大豆花荚脱落的初步研究. 植物生理学通讯, 1958, 5: 9-14.

Gao Y Z, Huang X Y, Yang H F. The preliminary study on flower and pod drop of soybean. Plant Physiology Communications, 1958, 5: 9-14. (in Chinese)

[8]赫冲. 关于大豆落花落荚问题的研究. 辽宁农业科学, 1960, 3: 225-233.

He C. The research on flower and pod drop of soybean. Liaoning Agricultural Sciences, 1960, 3: 225-233.

[9]郑殿峰, 赵黎明, 于洋, 冯乃杰, 赵玖香. 植物生长调节剂对大豆花荚脱落及产量的影响. 大豆科学, 2008, 5: 783-786.

Zheng D F, Zhao L M, Yu Y, Feng N J, Zhao J X. Effects of plant growth regulators(PGRs) on the abscission of flower and pod of soybean. Soybean Science, 2008, 5: 783-786. (in Chinese)

[10]李殿祥, 门文革, 董金秋. 大豆落花落荚的原因及防治对策. 现代化农业, 2010, 4: 23-24.

Li D X, Men W G, Dong J Q. Reasons and prevention countermeasures of flower and pod drop of soybean. Modernizing Agriculture, 2010, 4: 23-24. (in Chinese)

[11]Fehr W R, Caviness C E. Stages of soybean development. Special Report 80. Ames. Iowa State University Science Technology, 1977: 11.

[12]陈洁敏, 赵九洲, 杨方人, 赵淑英. 播期对大豆开花及产量的影响. 大豆科学, 1998, 17(3): 225-229.

Chen J M, Zhao J Z, Yang F R, Zhao S Y. Effect of sowing dates on blooming model and grain yield of soybean. Soybean Science, 1998, 17(3): 225-229. (in Chinese)

[13]李国辉, 王秋月, 介跃建. 分布拟合法分析大豆开花规律的研究. 哲里木畜牧学院学报, 1999, 9(2): 15-18.

Li G H, Wang Q Y, Jie Y J. Analysing the regular of soybenan flowering with the method of distribution fitting. Journal of Zhelimu Animal Husbandry College, 1999, 9(2):15-18. (in Chinese)

[14]章建新, 李金霞, 崔可夫, 周婷. 不同熟期大豆品种花荚形成和时空分布. 新疆农业大学学报, 2012, 35(2): 93-98.

Zhang J X, Li J X, Cui K F, Zhou T. Formation of flower and pod and space-time distribution of soybean varieties in different maturation periods. Journal of Xinjiang Agricultural University, 2012, 35(2): 93-98. (in Chinese)

[15]章建新, 周婷, 贾珂珂. 超高产大豆品种花荚形成及其时空分布. 大豆科学, 2012, 35(5): 739-743.

Zhang J X, Zhou T, Jia K K. Formation and space-time distribution of flowers and pods for super-high-yielding soybeans. Soybean Science, 2012, 35(5): 739-743. (in Chinese)

[16]李金霞. 高产春大豆豆荚光合特性及开花、成荚规律[D]. 乌鲁木齐: 新疆农业大学, 2010.

Li J X. Disciplinarian of high yield spring soybean photosynthesis speciality and flowering or podding[D]. Urumqi: Xinjiang Agricultural University, 2010. (in Chinese)

[17]胡润芳, 林国强. 菜用大豆落花落荚率与品种生育阶段的关系. 中国农学通报, 2009, 25(20): 108-109.

Hu R F, Lin G Q. The relationship between the flower and pod abscission rate of vegetable soybean and the reproductive stage of species. Chinese Agricultural Science Bulletin, 2009, 25(20): 108-109. (in Chinese)

[18]祝其昌. 密度与肥力对大豆主要性状落花落荚率及产量的影响. 东北农学院学报, 1960, 1: 1-17.

Zhu Q C. Effects of density and fertility on flower and pod drop and yield of soybean. Journal of Northeast Agricultural University, 1960, 1: 1-17. (in Chinese)

[19]康军科, 王可珍, 文定军, 张华. 大豆落花落荚及荚而不实的原因及预防措施. 陕西农业科学, 2007, 4: 100-101.

Kang J K, Wang K Z, Wen D J, Zhang H. The cause and preventive measure of blossom and pod drop and pods without peas of soybean. Shaanxi Journal of Agricultural Sciences, 2007, 4: 100-101. (in Chinese)

[20]郑剑英, 张晓荣, 李宇辉, 孙宝刚. 防止大豆落花落荚提高产量的途径, 吉林农业, 2011, 7: 142.

Zheng J Y, Zhang X R, Li Y H, Sun B G. The ways of prevent the flower and pod drop and increase yield. Jilin Agriculture, 2011, 7: 142. (in Chinese)

[21]徐明莉, 李辉, 汪径壮, 范仁英, 徐志平, 魏树军, 李锋. 浅析减少大豆落花落荚的有效途径. 杂粮作物, 2010, 30(4): 291-292.

Xu M L, Li H, Wang J Z, Fan R Y, Xu Z P, Wei S J, Li F. Analysis the effective way of reduce the blossom and poddrop of soybean. Rain Fed Crops, 2010, 30(4): 291-292. (in Chinese)

[22] 王会, 刘杰, 邹积田. 半干旱区高油大豆花荚脱落原因及综防措施. 北京农业, 2008, 15: 24-26.

Wang H, Liu J, Zou J T. Reasons and measures with the shedding of flowering and pod of high oil soybean in the semi-arid area. Beijing Agriculture, 2008, 15: 24-26. (in Chinese)

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