极晚播小麦根蘖发育及产量形成对密氮互作的响应

doi:10.13292/j.1000-4890.202601.013

摘要/Abstract

摘要： 为探究密氮互作对极晚播小麦根蘖发育及产量形成的影响，于2022年11月—2024年6月在山西农业大学小麦研究所洪堡国家试验基地开展田间定位试验。以济麦22为供试材料，裂区设计，主区为密度：设525×10⁴ 株·hm^-2（D1）、600×10⁴ 株·hm^-2（D2）、675×10⁴ 株·hm^-2（D3）3个水平；氮肥运筹为副区：设基肥∶返青肥∶拔节肥分别为5∶2∶3（N1）、5∶4∶1（N2）、3∶4∶3（N3）3种方式，分析极晚播小麦单株次生根数、茎蘖数、叶面积指数、地上部干重、产量及产量构成因素对密氮互作的响应。结果表明：同一密度水平灌浆期单株次生根数、叶面积指数均以N3最高，茎蘖数2022—2023年D1、D3处理为N3>N1>N2，D2处理为N3>N2>N1，2023—2024年均为N3>N2>N1，D2、D3处理时地上部干重为N3>N2>N1，两年产量分别表现为N3>N1>N2和N3>N2>N1，均以氮肥比例3∶4∶3时最高。同一氮肥比例灌浆期单株次生根数、茎蘖数、叶面积指数、地上部干重均以D3最高，产量两年均表现为随密度增加先降低后增加，以密度675×10⁴ 株·hm^-2且氮肥比例3∶4∶3时产量最高，其中2022—2023年较其余处理增产2.76%～17.79%，2023—2024年增产8.24%～31.86%。相关性分析表明，产量与灌浆期茎蘖数、叶面积指数及成熟期穗数呈显著正相关，与地上部干重呈极显著正相关。主成分分析表明，种植密度675×10⁴ 株·hm^-2、氮肥比例为3∶4∶3时综合得分最高。综上，适度增密（675×10⁴ 株·hm^-2），合理氮肥运筹（氮肥比例为3∶4∶3）时单株次生根数、茎蘖数较多，叶面积指数、地上部干重增加，产量提高，可作为晋南麦区极晚播小麦高产高效栽培的适宜密氮调控组合。

关键词: 极晚播, 小麦, 密氮互作, 茎蘖发育, 产量

Abstract: To examine the effects of planting density and nitrogen application level on root tiller development and yield formation in extremely-late sowing wheat, a field experiment was conducted from November 2022 to June 2024 at the Hongbu National Experimental Base of the Wheat Research Institute, Shanxi Agricultural University. Using Jimai 22 as the test material, a split-plot design was employed, with the main plot representing three planting densities: 525×10⁴ plants·hm^-2 (D1), 600×10⁴ plants·hm^-2 (D2), and 675×10⁴ plants·hm^-2 (D3). Nitrogen fertilization regimes were applied as subplots, with base fertilizer, green manure, and jointing fertilizer applied at three different ratios: 5∶2∶3 (N1), 5∶4∶1 (N2), and 3∶4∶3 (N3). The effects of planting density and nitrogen application interaction on the number of secondary roots per plant, tiller number, leaf area index, aboveground dry weight, yield and yield components in extremely-late sowing wheat were examined. The results showed that at the same density, both the number of secondary roots per plant and leaf area index during the grain filling stage were highest in N3. The number of tillers was N3>N1>N2 in the D1 and D3 treatments and N3>N2>N1 in the D2 treatment during the 2022-2023 period. In the 2023-2024 period, the annual average followed the order N3>N2>N1. The aboveground dry weight of D2 and D3 treatments was N3>N2>N1. The yield exhibited patterns of N3>N1>N2 in 2022-2023 and N3>N2>N1 in 2023-2024, with the highest yield under the nitrogen fertilizer ratio of 3∶4∶3. During the grain filling stage, under the same nitrogen fertilizer ratio, the numbers of secondary roots, tillers, leaf area index, and aboveground dry weight per plant were the highest in the D3 treatment. Yield decreased and then increased with increasing density in both years, the highest yield was achieved at a density of 675×10⁴ plants per hectare and a nitrogen fertilizer ratio of 3∶4∶3. Among them, the yield increased by 2.76% to 17.79% in 2022-2023 compared with the other treatments, and by 8.24% to 31.86% in 2023-2024. Correlation analysis indicated that yield was significantly positively correlated with the number of stem tillers and leaf area index at the filling stage, with the number of panicles at the mature stage, and with the dry weight of the aboveground part, with a correlation coefficient of 0.91. Principal component analysis indicated that the overall score was highest when the sowing density was 675×10⁴ plants·hm^-2 and the nitrogen fertilizer ratio was 3∶4∶3. In conclusion, moderate density (675×10⁴ plants·hm^-2) and optimal nitrogen fertilizer management (nitrogen fertilizer ratio of 3∶4∶3) can increase the number of secondary roots, tillers per plant, leaf area index, aboveground dry weight, and yield. This combination can serve as an effective nitrogen management strategy for high-yield of efficient extremely-late sowing wheat cultivation in the southern Shanxi region.

Key words: extremely-late sowing, wheat, density and nitrogen interaction, root tiller development, yield

张晶, 张楠, 张慧芋, 解丽丽, 张定一. 极晚播小麦根蘖发育及产量形成对密氮互作的响应[J]. 生态学杂志, 2026, 45(1): 192-201.

ZHANG Jing, ZHANG Nan, ZHANG Huiyu, XIE Lili, ZHANG Dingyi. Response of root tiller development and yield formation of extremely-late sowing wheat to the interactions of planting density and nitrogen application.[J]. Chinese Journal of Ecology, 2026, 45(1): 192-201.

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极晚播小麦根蘖发育及产量形成对密氮互作的响应

Response of root tiller development and yield formation of extremely-late sowing wheat to the interactions of planting density and nitrogen application.

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