钵苗机插水稻群体动态特征及高产形成机制的探讨

doi:10.3864/j.issn.0578-1752.2014.05.004

中国农业科学 ›› 2014, Vol. 47 ›› Issue (5): 865-879.doi: 10.3864/j.issn.0578-1752.2014.05.004

• 耕作栽培·生理生化·农业信息技术 • 上一篇下一篇

钵苗机插水稻群体动态特征及高产形成机制的探讨

胡雅杰1, 邢志鹏1, 龚金龙1, 刘国涛1, 张洪程1, 戴其根1, 霍中洋1, 许轲1, 魏海燕1, 郭保卫1, 沙安勤2, 周有炎2, 罗学超2, 刘国林2

1、扬州大学农学院/农业部长江流域稻作技术创新中心/江苏省作物遗传生理重点实验室，江苏扬州 225009；
2、江苏省兴化市农业局，江苏兴化 225700

收稿日期:2013-09-13 出版日期:2014-03-01 发布日期:2013-11-28
通讯作者: 张洪程，Tel：0514-87979220；E-mail：hczhang@yzu.edu.cn
作者简介:胡雅杰，E-mail：yajiehu@163.com
基金资助:
国家“十二五”科技支撑计划（2011BAD16B03）、超级稻配套栽培技术开发与集成（农业部专项）、江苏省科技支撑计划（BE2012301，BE2013394）、江苏省农业科技自主创新基金（CX[12]1003.9）、扬州大学“新世纪人才工程”

Study on Population Characteristics and Formation Mechanisms for High Yield of Pot-Seedling Mechanical Transplanting Rice

1、College of Agriculture, Yangzhou University/Innovation Center of Rice Cultivation Technology in the Yangtze Valley, Ministry of Agriculture/Key Laboratory of Crop Genetics and Physiology of Jiangsu Province, Yangzhou 225009, Jiangsu;
2、Bureau of Agriculture of Xinghua County of Jiangsu Province, Xinghua 225700, Jiangsu

Received:2013-09-13 Online:2014-03-01 Published:2013-11-28

摘要/Abstract

摘要： 【目的】旨在阐明钵苗机插水稻产量构成特征和群体动态特征以及高产形成机制。【方法】2010年选用24个不同单穗重粳稻品种统一高产栽培，以成熟期平均单穗重聚类分析划分3种穗型，并每种穗型筛选2个具有代表性品种。2011—2012年采用大穗型品种甬优8号和甬优2640，中穗型品种武运粳24号和宁粳3号，小穗型品种淮稻5号和淮稻10号为试验材料，在江苏省兴化市钓鱼镇进行大田试验，以毯苗机插水稻为对照，系统研究钵苗机插水稻产量及其产量构成、群体茎蘖动态、叶面积指数动态和干物质积累动态特征，并从秧苗素质、栽后物质积累、阶段光合物质生产、光合势、群体生长率、净同化率、株型特征、茎鞘物质输出与转运、根系活力等方面深入探讨钵苗机插水稻高产形成机制。【结果】钵苗机插水稻产量显著或极显著高于对照，大穗型品种增产8.71%—11.11%，中穗型品种增产6.85%—7.89%，小穗型品种增产5.30%—6.34%。钵苗机插水稻产量的提高主要原因是在足够穗数的基础上，显著或极显著增加每穗粒数，进而提高群体颖花量，同时保持稳定的结实率和千粒重。与对照相比，钵苗机插水稻群体茎蘖数栽后增长快，高峰苗适宜，拔节后群体茎蘖数消减缓慢，最终有效穗数足，成穗率高；群体叶面积指数和干物质积累量，有效分蘖临界叶龄期钵苗机插水稻显著高于对照，拔节期两者相当，孕穗后钵苗机插水稻显著或极显著高于对照，成熟期叶面积指数钵苗机插水稻较对照高出5.17%—11.00%，干物质积累量钵苗机插水稻较对照高出5.36%—9.20%。钵苗机插水稻高产形成机制为带土带蘖栽插，秧苗素质高，群体起点质量优，活棵早，分蘖快，低位分蘖多，栽后地上和地下部物质积累多，为争足穗、促壮秆和攻大穗奠定生物学基础；抽穗期株型紧凑，叶系配置优，叶面积大，比叶重高，基部茎秆粗壮，粒叶比高，形成高光效高质量群体；生育后期根系活力强，叶面积衰减慢，光合势大，群体生长率和净同化率高，干物质积累多，灌浆充实量大，茎鞘物质输出与转运合理。【结论】钵苗机插水稻群体起点质量高，栽后分蘖早生发快，群体生长优势明显，特别是生育中后期光合生产能力强，物质积累多。钵苗机插水稻产量构成特征表现为“穗数足、穗型大、粒数多”。

关键词: 水稻 , 钵苗机插 , 产量构成特征 , 群体动态特征 , 高产形成机制

Abstract: 【Objective】The characteristics of yield formation and population dynamics and mechanisms of high-yielding formation were identified in pot seedling of mechanical transplanting japonica rice.【Method】Twenty-four japonica rice cultivars which have different weights of single panicle were grown by unified high-yielding cultivation in 2010, and were divided into three panicle types by clustering analysis with average single panicle in maturity. Three panicle types of japonica rice cultivars including large panicle type (LPT, Yongyou 2640 and Yongyou 8) and medium panicle type (MPT, Wuyunjing 24 and Ningjing 3) and small panicle type (SPT, Huaidao 5 and Huaidao 10) were field-grown from 2011 to 2012 in Diaoyu town, Xinghua county, Jiangsu province, China. By setting carpet seedling of mechanical transplanting rice (CS) as CK, the yield and yield formation, number of population stem and tiller, leaf area index (LAI) and dry matter accumulation of pot seedling of mechanical transplanting rice (PS) were investigated, and high-yielding formation mechanisms of PS were also explored in respect of seedling quality, matter accumulation after transplanting, plant type, staged photosynthetic matter production, photosynthetic potential (PP), crop growing rate (CGR) and net assimilation rate (NAR), matter transport in stem and sheath and root activity. 【Result】 Yield was significantly or very significantly higher in PS than CS. The range of increased yield was 8.71%-11.11% in large panicle-type variety, medium panicle-type variety was 6.85%-7.89%, and small panicle-type variety was 5.30%-6.34%. The increased yield was mainly attributed to higher total spikelets in PS, which owning to sufficient panicle and expanding spikelets per panicle. Compared with CS, PS had earlier tiller, suitable peak seedling tillers, slower reducing rate of tillers after jointing, enough effective panicles and higher ratio of productive tillers to total tillers at maturity. Leaf area index and dry matter accumulation in PS was significantly higher at the critical stage for effective tiller and very significantly greater at and after booting stage, and higher 5.17%-11.00% and 5.36%-9.20% at maturity than CS. The mechanisms of high-yielding formation in PS was that: After transplanting, there had strong seedling, better population started quality, earlier seedling establishment, faster tiller, more tillers of low position and greater dry matter weight of aboveground and root; They formed higher photosynthetic efficiency and quality population at heading, which had tighter plant type, better canopy, bigger leaf area, higher specific leaf weight, stronger stem and sheath, greater grain-leaf ratio; At the late growing stage, there had stronger root activity, slower decreasing rate of leaf area, higher photosynthetic potential and crop growing rate and net assimilation rate, greater dry matter accumulation, more coordinated matter export and translocation of stem and sheath.【Conclusion】With better population started quality and earlier tiller, pot seedling of mechanical transplanting rice had obvious advantages, especially, higher photosynthetic matter production and greater dry matter accumulation at the middle and late growing stages, which the yield formation characteristics were sufficient panicle, larger panicle type and more spikelets per panicle

Key words: rice , pot seedling of mechanical transplanting , yield formation characteristics , population characteristics , high- yielding formation mechanism

胡雅杰1, 邢志鹏1, 龚金龙1, 刘国涛1, 张洪程1, 戴其根1, 霍中洋1, 许轲1, 魏海燕1, 郭保卫1, 沙安勤2, 周有炎2, 罗学超2, 刘国林2. 钵苗机插水稻群体动态特征及高产形成机制的探讨[J]. 中国农业科学, 2014, 47(5): 865-879.

HU Ya-Jie-1, XING Zhi-Peng-1, GONG Jin-Long-1, LIU Guo-Tao-1, ZHANG Hong-Cheng-1, DAI Qi-Gen-1, HUO Zhong-Yang-1, XU Ke-1, WEI Hai-Yan-1, GUO Bao-Wei-1, SHA An-Qin-2, ZHOU You-Yan-2, LUO Xue-Chao-2, LIU Guo-Lin-2. Study on Population Characteristics and Formation Mechanisms for High Yield of Pot-Seedling Mechanical Transplanting Rice[J]. Scientia Agricultura Sinica, 2014, 47(5): 865-879.

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[30]张洪程, 吴桂成, 李德剑, 肖跃成, 龚金龙, 李杰, 戴其根, 霍中洋, 许轲, 高辉, 魏海燕, 沙安勤, 周有炎, 王宝金, 吴爱国. 杂交粳稻13.5 t hm-2 超高产群体动态特征及形成机制的探讨. 作物学报, 2010, 36(9): 1547-1558.

Zhang H C, Wu G C, Li D J, Xiao Y C, Gong J L, Li J, Dai Q G, Huo Z Y, Xu K, Gao H, Wei H Y, Sha A Q, Zhou Y Y, Wang B J, Wu A G. Population characteristics and formation mechanism for super-high-yielding hybrid japonica rice (13.5 t ha-1). Acta Agronomica Sinica, 2010, 36(9): 1547-1558. (in Chinese)

[31]张洪程, 郭保卫, 陈厚存, 周兴涛, 张军, 朱聪聪, 陈京都, 李桂云, 吴中华, 戴其根, 霍中洋, 许轲, 魏海燕, 高辉, 杨雄. 水稻有序摆、抛栽的生理生态特征及超高产形成机制. 中国农业科学, 2013, 46(3): 463-475.

Zhang H C, Guo B W, Chen H C, Zhou X T, Zhang J, Zhu C C, Chen J D, Li G Y, Wu Z H, Dai Q G, Huo Z Y, Xu K, Wei H Y, Gao H, Yang X. Eco-physiological characteristics and super high yield formation mechanism of ordered transplanting and optimized broadcasting rice. Scientia Agricultura Sinica, 2013, 46(3): 463-475. (in Chinese)

钵苗机插水稻群体动态特征及高产形成机制的探讨

Study on Population Characteristics and Formation Mechanisms for High Yield of Pot-Seedling Mechanical Transplanting Rice

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