中国农业科学 ›› 2021, Vol. 54 ›› Issue (20): 4286-4298.doi: 10.3864/j.issn.0578-1752.2021.20.004
聂军军1(),代建龙1,杜明伟2,张艳军1,田晓莉2,李召虎2(),董合忠1()
收稿日期:
2020-12-26
接受日期:
2021-04-09
出版日期:
2021-10-16
发布日期:
2021-10-25
通讯作者:
李召虎,董合忠
作者简介:
聂军军,E-mail: 基金资助:
NIE JunJun1(),DAI JianLong1,DU MingWei2,ZHANG YanJun1,TIAN XiaoLi2,LI ZhaoHu2(),DONG HeZhong1()
Received:
2020-12-26
Accepted:
2021-04-09
Online:
2021-10-16
Published:
2021-10-25
Contact:
ZhaoHu LI,HeZhong DONG
摘要:
集中成熟是棉花机械收获的基本要求,系指整株棉花的棉铃集中在一个较短的时间段内成熟吐絮的现象,而集中成熟栽培则是指实现棉花优化成铃、集中吐絮的栽培管理技术和方法。经过多年研究和实践,我国棉花集中成熟栽培的理论和技术业已形成,成为现代植棉理论与技术的重要内容。本文对棉花集中成熟的概念与内涵、关键栽培技术及其生理生态学机理进行了创新性总结。棉花集中成熟栽培要从播种开始,通过单粒精播技术实现一播全苗、壮苗,为集中成熟创造稳健的基础群体;在全苗壮苗基础上,以集中成熟为目标,根据当地的生态条件和生产条件,综合运用水、肥、药调控棉花个体和群体生长发育,构建集中结铃的株型和集中成熟的高效群体结构,实现优化成铃、集中吐絮。单粒精播能够创造适宜的顶土压力和出苗前的黑暗环境,诱导棉苗顶端弯钩形成和下胚轴增粗关键基因表达,促进弯钩形成、下胚轴稳健生长和顶土出苗;出苗后具有独立的生长空间,相互影响小,形成壮苗。密植与化控降低了叶枝叶的光合作用,诱导激素代谢关键基因表达,改变了内源激素含量和分布,抑制了叶枝和主茎顶端生长,实现了免整枝并促进了集中结铃;分区灌溉诱导叶片合成大量茉莉酸,其作为信号分子通过韧皮部运输到灌水区根系,促进水孔蛋白基因表达,提高了根系吸水能力和水分利用率;膜下分区滴灌、水肥协同管理,进一步提高了棉花光合产物向产品形成器官的分配比例和棉株化学脱叶率,促进了集中成熟和高效脱叶,在节水减肥的前提下,产量不减,机采籽棉含杂率显著降低。棉花集中成熟栽培理论与技术是新时代棉花栽培学研究的新成果,是现代棉业发展的重要科技支撑。展望未来,应在深入研究棉花集中成熟栽培生理生态学机制的基础上,选用更加配套的棉花新品种,创新关键栽培技术,研制新的配套物质装备,促进良种良法配套、农艺农机高度融合。同时,还应加强农艺技术与现代智慧植棉技术的有机结合,进一步提高棉花集中成熟栽培的科学性和有效性,为轻简高效植棉提供更加有力的理论和技术支撑。
聂军军,代建龙,杜明伟,张艳军,田晓莉,李召虎,董合忠. 我国现代植棉理论与技术的新发展——棉花集中成熟栽培[J]. 中国农业科学, 2021, 54(20): 4286-4298.
NIE JunJun,DAI JianLong,DU MingWei,ZHANG YanJun,TIAN XiaoLi,LI ZhaoHu,DONG HeZhong. New Development of Modern Cotton Farming Theory and Technology in China - Concentrated Maturation Cultivation of Cotton[J]. Scientia Agricultura Sinica, 2021, 54(20): 4286-4298.
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