油菜品种、越冬调控和病虫害防控对直播油菜产量的影响

doi:10.3864/j.issn.0578-1752.2025.21.003

中国农业科学 ›› 2025, Vol. 58 ›› Issue (21): 4333-4345.doi: 10.3864/j.issn.0578-1752.2025.21.003

• 耕作栽培·生理生化·农业信息技术 • 上一篇下一篇

油菜品种、越冬调控和病虫害防控对直播油菜产量的影响

杨龙¹(), 张学昆¹^,²(), 陈爱武³(), 李莓², 程泰³, 马伍慧¹, 许本波¹, 徐劲松¹

¹ 长江大学农学院/农业农村部长江中游作物绿色高效生产重点实验室（部省共建）/涝渍灾害与湿地农业湖北省重点实验室，湖北荆州 434025
² 湖南省农业科学院作物所/岳麓山实验室，长沙 410128
³ 湖北省油菜办公室，武汉 430070

收稿日期:2025-06-26 接受日期:2025-09-30 出版日期:2025-11-01 发布日期:2025-11-06
通信作者:
张学昆，E-mail：zhang.xk@139.com
联系方式: 杨龙，E-mail：3032419907@qq.com。陈爱武，E-mail：chenaw21@sohu.com。杨龙和陈爱武为同等贡献作者。
基金资助:
农业生物育种重大项目(2023ZD04042); 农业农村部长江中游油菜单产提升技术集成示范基金项目(152304045); 湖北省科技服务油菜产业链“515”行动(协同推广)

Effects of Variety, Over-Winter Regulation, and Pest and Disease Control on Rapeseed Yield

YANG Long¹(), ZHANG XueKun¹^,²(), CHEN AiWu³(), LI Mei², CHENG Tai³, MA WuHui¹, XU BenBo¹, XU JinSong¹

¹ College of Agronomy, Yangtze University/Key Laboratory of Green and Efficient Crop Production in the Middle Reaches of Yangtze River, Ministry of Agriculture and Rural Affairs/Hubei Key Laboratory of Waterlogging Disaster and Agricultural Use of Wetland, Jingzhou 434025, Hubei
² Yuelushan Laboratory/Hunan Crop Research Institute, Changsha 410128
³ Rapeseed Office of Hubei Province, Wuhan 430070

Received:2025-06-26 Accepted:2025-09-30 Published:2025-11-01 Online:2025-11-06

摘要/Abstract

摘要：

【目的】油菜是我国第一大油料作物，提高油菜单位面积产量是增加油菜籽有效供给和提高种植效益的关键途径。在机械化直播条件下，进一步明确品种、越冬调控、病虫害防控等主要技术因素对单产的影响，可为我国油菜单产提升提供理论依据。【方法】选用9个高产优质油菜品种，于2021—2023年开展2年共22个试验点（主产县）的机械化直播种植试验，系统研究减量追施氮肥条件下，油菜品种、种子处理、越冬调控、新型菌核病防控等因素对单产的影响。【结果】采用种子处理（迈舒平包衣防虫，D1）、越冬调控（D2）和新型菌核病防控（氟唑菌酰羟胺，D3）3种组合处理技术均能显著提高减氮追肥（尿素45 kg·hm^-2）下油菜的单产，与传统减损技术模式（种子不包衣+不越冬调控及咪鲜胺防治菌核病+追施尿素，CK）的112.5 kg·hm^-2相比，分别显著增产6.2%、6.4%和10.9%，产量分别达2 594.2、2 600.4、2 708.9 kg·hm^-2，但菌核病发病率仅D3极显著降低49.1%。不同技术组合后对单产提升具有显著的互作效应，种子处理和越冬调控分别与新型菌核病防控技术结合后，比传统技术分别显著增产15.7%和16.1%，产量达2 820.0和2 834.2 kg·hm^-2，菌核病发病率分别下降55.6%、55.3%。油菜品种基因型与技术间也存在显著的互作效应，采用新技术能超过该品种的国家区试产量，如阳光131、大地199、中油杂39 3个品种区试产量分别为2 341.2、3 085.5、2 982.0 kg·hm^-2，在优化调控技术组合下分别比该品种区试产量增产11.7%、5.0%、3.5%。将油菜品种区试产量和抗病性、不同技术组合等因素与试验产量进行多元逐步回归分析，结果显示品种的区试千粒重、区试产量、新型菌核病防控和减少冬季尿素追肥量是决定产量水平的最关键因素。典型相关分析进一步证实，品种区试产量、区试千粒重和区试角果数决定产量水平，而氟唑菌酰羟胺和迈舒平对增产率具有非常重要的作用，新型菌核病防控技术和越冬抗逆调控与降低菌核病发病率有关。【结论】在油菜机械化生产中，品种的区试产量是影响油菜产量水平的关键因素，利用氟唑菌酰羟胺防治菌核病是当前降低菌核病损失的有效因素，种子处理、越冬调控与菌核病新型防控技术相组合能进一步发挥油菜品种的产量潜力。建议生产上选择高产优质品种，配套种子处理和越冬调控、氟唑菌酰羟胺等减损技术，实现油菜单产显著提升。

关键词: 油菜, 产量, 品种, 菌核病, 氟唑菌酰羟胺, 种子处理, 越冬调控

Abstract:

【Objective】Rapeseed (Brassica napus L.) is the first major oil-bearing crop in China. Enhancing rapeseed yield per unit area is the key to increase its effective supply and economic benefits. Under the condition of mechanical direct seeding, further clarifying the impacts of major technical factors, such as variety selection, overwintering regulation, and disease and pest control, on the yield per unit area could provide a theoretical basis for the improvement of rapeseed yield per unit area in China. 【Method】Nine high-yield and high-quality rapeseed varieties were selected, and mechanical direct-seeding experiments were conducted at 22 experimental sites (major rapeseed-producing counties) over 2 years from 2021 to 2023. A systematic study was carried out to investigate the impacts of factors such as rapeseed variety, seed treatment, overwintering regulation, and Sclerotinia sclerotiorum control on the yield per unit area under the condition of reduced topdressing application of nitrogen fertilizer. 【Result】The application of three combined treatment techniques, namely seed treatment (Maishuping coating for pest prevention, D1), overwintering regulation (D2), and novel Sclerotinia sclerotiorum control (fluxapyroxad, D3), all significantly increased the yield per unit area of rapeseed under reduced nitrogen topdressing (urea 45 kg·hm^-2). Compared with the traditional loss-reduction technology mode (uncoated seeds+no overwintering regulation and prochloraz for Sclerotinia sclerotiorum control+urea topdressing, CK), with a yield of 112.5 kg·hm^-2, the yields under D1, D2 and D3 treatments increased significantly by 6.2%, 6.4%, and 10.9%, respectively, while the corresponding yields reached 2 594.2, 2 600.4 and 2 708.9 kg·hm^-2, respectively. However, only the incidence of Sclerotinia sclerotiorum was extremely significantly reduced by 49.1% under the D3 treatment. Different technical combinations exhibited significant interaction effects on yield per unit area improvement. When seed treatment and overwintering regulation were combined with the novel Sclerotinia sclerotiorum control technology respectively, the yields were significantly 15.7% and 16.1% higher than those under the traditional technology, respectively, reaching 2 820.0 and 2 834.2 kg·hm^-2, respectively, while the incidence of Sclerotinia sclerotiorum decreased by 55.6% and 55.3%, respectively. Additionally, there was a significant interaction effect between rapeseed variety genotypes and technology. The application of new technologies could exceed the national regional trial yields of the corresponding varieties. For instance, the regional trial yields of Yangguang 131, Dadi 199 and Zhongyouza 39 were 2 341.2, 3 085.5, and 2 982.0 kg·hm^-2, respectively. Under optimized combinations of regulatory technology, the yields were 11.7%, 5.0% and 3.5% higher than their respective regional trial yields, respectively. A multiple stepwise regression analysis was conducted between the experimental yield and factors including the regional trial yield, disease resistance of rapeseed varieties, as well as different technological combinations, and the results revealed that the critical factors determining yield levels were the 1000-seed weight in regional trials, regional trial yield of varieties, novel Sclerotinia sclerotiorum control, and reduced winter urea topdressing rate. Canonical correlation analysis further confirmed that the regional trial yield, regional trial 1000-seed weight, and regional trial silique number of varieties determined the yield levels. Meanwhile, fluxapyroxad and Maishuping played a very important role in enhancing yield increase rates. Additionally, the novel Sclerotinia sclerotiorum control technology and overwintering stress resistance regulation were related to reducing the incidence of Sclerotinia sclerotiorum. 【Conclusion】In the mechanical production of rapeseed, the regional trial yield of varieties was a key factor affecting the rapeseed yield levels. The use of fluxapyroxad to control Sclerotinia sclerotiorum was an effective factor for reducing the yield loss caused by Sclerotinia sclerotiorum at present. The combination of seed treatment, overwintering regulation and the novel Sclerotinia sclerotiorum control technology could further exert the yield potential of rapeseed varieties. It was suggested that in practical production, high-yield and high-quality varieties should be selected, and loss-reduction technologies, such as supporting seed treatment, overwintering regulation and fluxapyroxad, should be matched to achieve a significant improvement in rapeseed yield per unit area.

Key words: rapeseed, yield, variety, Sclerotium disease, pydiflumetofen, seed treatment, over-winter regulation

杨龙, 张学昆, 陈爱武, 李莓, 程泰, 马伍慧, 许本波, 徐劲松. 油菜品种、越冬调控和病虫害防控对直播油菜产量的影响[J]. 中国农业科学, 2025, 58(21): 4333-4345.

YANG Long, ZHANG XueKun, CHEN AiWu, LI Mei, CHENG Tai, MA WuHui, XU BenBo, XU JinSong. Effects of Variety, Over-Winter Regulation, and Pest and Disease Control on Rapeseed Yield[J]. Scientia Agricultura Sinica, 2025, 58(21): 4333-4345.

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因变量（Y） Dependent variable		非标准化系数 Unstandardized coefficient		标准化系数 Standardized coefficient	自变量单独检验统计量 t	回归系数显著性 P	方差膨胀因子 VIF
因变量（Y） Dependent variable		回归系数与截距 B	标准误 Standard error	常数为0时的回归系数值 Beta	自变量单独检验统计量 t	回归系数显著性 P	方差膨胀因子 VIF
产量 Yield	常数 Constant	86.469	18.441	-	4.689	0**	-
	追施氮量 Urea	-2.354	0.960	-0.187	-2.454	0.015*	1.196
	氟唑菌酰羟胺 Pydiflumetofen	0.221	0.065	0.260	3.401	0.001**	1.197
	区试产量 Regional trials yield	0.312	0.072	0.304	4.332	0**	1.013
	区试千粒重 Regional trials 1000 seeds weight	10.920	3.456	0.223	3.160	0.002**	1.020
	R²	0.323
	调整R² Adjust R²	0.304
	F	F (4,139)=16.598, P=0.000

油菜品种、越冬调控和病虫害防控对直播油菜产量的影响

Effects of Variety, Over-Winter Regulation, and Pest and Disease Control on Rapeseed Yield

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减损技术因子Field loss control factors
处理 Treatment	氮肥追施量 Nitrogen topdressing level (kg·hm^-2)	种子处理 Seed treated with thiamethoxam (mL·hm^-2)	有机水溶肥冬季调控 Over-winter regulation with Organic water-soluble fertilizer (mL·hm^-2)	咪鲜胺传统防病技术 Traditional technology with Prochloraz (mL·hm^-2)	氟唑菌酰羟胺菌核病防治 Sclerotinia control with pydiflumetofen (mL·hm^-2)
CK	112.5	0	0	1500	0
D1	45	30	0	1500	0
D2	45	0	1500	1500	0
D3	45	0	0	0	750
D4	45	30	0	0	750
D5	45	0	1500	0	750

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