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生态学杂志 ›› 2023, Vol. 42 ›› Issue (8): 1880-1889.doi: 10.13292/j.1000-4890.202306.026

• 研究报告 • 上一篇    下一篇

甜玉米-大豆间作和施氮对红壤旱地田间杂草群落的影响

徐刚1,陈忠平2,俞霞1,肖世豪1,蔡如深1,潘语卓1,鲁美娟3,杨文亭1*


  

  1. 1江西农业大学作物生理生态与遗传育种教育部重点实验室, 南昌 330045; 2江西省农业技术推广中心, 南昌 330046; 3江西农业大学国土与资源环境学院, 南昌 330045)

  • 出版日期:2023-08-10 发布日期:2023-07-27

Effects of sweet corn-soybean intercropping and nitrogen application on weed communities in upland red soil.

XU Gang1, CHEN Zhongping2, YU Xia1, XIAO Shihao1, CAI Rushen1, PAN Yuzhuo1, LU Meijuan3, YANG Wenting1*#br#

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  1. (1Key Laboratory of Crop Physiology, Ecology and Genetic Breeding, Ministry of Education, Jiangxi Agricultural University, Nanchang 330045, China; 2Agricultural Technology Extension Center of Jiangxi Province, Nanchang 330046, China; 3College of Territorial Resources and Environmental, Jiangxi Agricultural University, Nanchang 330045, China).

  • Online:2023-08-10 Published:2023-07-27

摘要: 生物多样性是生态防控杂草的重要措施之一。本研究通过两年(2019—2020年)田间定位试验,对春季和秋季甜玉米苗期、孕穗期和收获期田间杂草的种类及密度进行了监测,探讨不同种植模式(甜玉米-大豆,CS;甜玉米单作,MC;大豆单作,MS)和施氮水平(0 kg·hm-2,N0;150 kg·hm-2,N1;300 kg·hm-2,N2)对田间杂草种群和群落结构的影响。结果表明:两年共收集杂草15科34种。马唐(Digitaria sanguinalis)是所有处理中的优势种,在不同种植模式中占所有杂草密度的34.60%~54.95%。稗草(Echinochloa crusgalli)在CSN0中是优势种,占比24.52%。马松子(Melochia corchorifolia)在MCN1中是优势种,占比13.96%。狗尾草(Setaria viridis)在CSN1、MCN0和MCN2处理下为优势种,占比为11.26%、13.76%和17.27%。牛筋草(Eleusine indica)在CSN2、MCN1和MCN2处理下为优势种,占比为10.72%、10.81%和16.40%。相比不施氮,施氮降低了2019年春季CS及春季和秋季MC模式下杂草平均密度。多因素方差分析表明,甜玉米生育期对两年的杂草平均密度、2020年种类数、2019年密度种类指数及2020年Simpson指数、Shannon指数和丰富度指数有显著影响;施氮显著影响了2019年的杂草密度种类指数。去趋势排序分析表明,杂草群落组成的变化与甜玉米生长季节及生育期密切相关,而种植模式及施氮对杂草群落组成的影响规律不一致。综合来看,施氮降低了甜玉米田间杂草密度,间作种植能够部分抑制作物苗期杂草丰富度,施氮条件下的甜玉米间作大豆种植模式有利于防控杂草。


关键词: 杂草防控, 甜玉米, 大豆, 间作, 施氮

Abstract: Biodiversity is one of the important measures for ecological control of weeds. In this study, a two-year (2019-2020) field experiment was conducted to explore the effects of cropping systems (sweet corn-soybean, CS; sweet corn monocropping, MC; and soybean monocropping, MS) and nitrogen application rates (0 kg·hm-2, N0; 150 kg·hm-2, N1; 300 kg·hm-2, N2) on weed populations and community structure. The species number and density of weeds were counted in sweet corn seedling, booting and harvest stages during spring and autumn sweet corn cropping season. The results showed that a total of 34 weed species from 15 families were recorded in the two years. Crabgrass (Digitaria sanguinalis) was the dominant species in all treatments and accounted for 34.60%-54.95% of total weed density in different planting patterns. Barnyard grass (Echinochloa crusgalli) was the dominant species in CSN0, which accounted for 24.52% of total weed density. Melochia (Melochia corchorifolia) was the dominant species in MCN1, accounting for 13.96% of total weed density. Green bristlegrass (Setaria viridis) was the dominant species in CSN1, MCN0 and MCN2, accounting for 11.26%, 13.76% and 17.27% of total weed density in each planting pattern, respectively. Goose grass (Eleusine indica) was the dominant species in CSN2, MCN1, and MCN2, accounting for 10.72%, 10.81%, and 16.40% of total weed density, respectively. Compared to the treatment without nitrogen application, nitrogen application significantly reduced the average weed density in the CS in spring and in the MC in spring and autumn in 2019. The results of multivariate analysis of variance showed that the growth period of sweet corn had a significant impact on the average density of weeds in two years, the species number in 2020, the density-species index in 2019, and Simpson index, Shannon index and Margalef richness index of weed in 2020. Nitrogen application significantly affected the weed density-species index in 2019. Results of the detrended correspondence analysis showed that the changes of weed community composition were closely related to growing season and growth period of sweet corn, and that cropping system and nitrogen application did not have consistent effects on weed community composition. In conclusion, nitrogen application reduced weed density, while intercropping system could partially inhibit weed species richness in crop seedling stage. Sweet corn-soybean intercropping system under nitrogen application is beneficial to weed control.


Key words: weed control, sweet corn, soybean, intercropping, nitrogen application.