Effects of combined nitrogen and manure management on yield and nitrate dynamics in winter wheat-summer fallow rotation system

IF 6.1 1区农林科学 Q1 SOIL SCIENCE Soil & Tillage Research Pub Date : 2024-11-25 DOI:10.1016/j.still.2024.106363

Wenguang Li , Fan Shi , Shusheng Yi , Tianyu Feng , Wei Zheng , Bingnian Zhai , Fenglian Lv

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Abstract

Nitrogen (N) leaching as the major N loss pathway in intensive agricultural systems. However, a comprehensive evaluation for the effects of organic fertilizer substitution on nitrate residue and leaching losses during the fallow season is not available in winter wheat-summer fallow rotation system. The present dryland wheat fertilization experiment conducted from 2014−2019 adopted a split-plot design, with manure dosage (i.e., M₀; NPK group and M₁; MNPK group) as the main plots and nitrogen fertilizer dosage as the subplot (i.e., N₀, N₇₅, N₁₅₀, N₂₂₅, N₃₀₀). In short, the peaks of NO₃⁻ in the 0−200 cm profile gradually move toward the deep soil layer with increasing years of fertilization, and the number of peaks also gradually increases. Increasing the N rate always leads to a sharp increase in nitrate residue in the 0−200 cm profile at the harvest stage (HNR) and sowing stage (SNR) and results in a large amount of nitrate leaching loss (ΔNR) during the summer fallow season, especially when the N rate was> 150 kg ha⁻¹. Compared to NPK, MNPK significantly increased SNR and ΔNR by 38.1 % and 171 %, respectively, but decreased HNR by 36.2 %. ΔNR was positively related to fallow season precipitation and soil water storage changes during the fallow season in the 0–200 cm profile. When the N rate was> 150 kg ha⁻¹, the growth rate of grain yield slowed down or even decreased, and the annual average yields of N₇₅, N₁₅₀, N₂₂₅, and N₃₀₀ were 36.3 %, 51.5 %, 55.4 %, and 47.6 % higher than that of N₀, respectively. The average grain yield of MNPK was 13.9 % higher than that of NPK. Therefore, manure combined with 150 kg ha⁻¹ N fertilizer is the best fertilization strategy to ensure high productivity of dryland wheat, control nitrate residue, and reduce nitrate leaching loss during the summer fallow season. This results provided valuable information for the application prospect of N fertilizer reduction combined with manure in dryland agriculture.

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氮肥综合管理对冬小麦-夏季休耕轮作系统产量和硝酸盐动态的影响

氮（N）淋失是集约化农业系统中氮损失的主要途径。然而，在冬小麦-夏季休耕轮作体系中，有机肥替代对休耕期硝酸盐残留和淋失的影响还没有全面的评价。本旱地小麦施肥试验于 2014-2019 年进行，采用分小区设计，以粪肥用量（即 M0；NPK 组和 M1；MNPK 组）为主小区，氮肥用量（即 N0、N75、N150、N225、N300）为副小区。总之，随着施肥年限的增加，0-200 厘米剖面中的 NO3- 峰值逐渐向土壤深层移动，峰值数量也逐渐增加。增加氮肥施用量总会导致收割期（HNR）和播种期（SNR）0-200 厘米剖面中硝酸盐残留量急剧增加，并导致夏季休耕期大量硝酸盐淋失（ΔNR），尤其是当氮肥施用量为 150 千克/公顷时。与氮磷钾相比，MNPK 可显著提高 SNR 和 ΔNR 分别为 38.1 % 和 171 %，但 HNR 却降低了 36.2 %。ΔNR与休耕期降水量和休耕期 0-200 厘米剖面土壤储水量变化呈正相关。当氮肥用量为 150 kg ha-1 时，谷物产量的增长速度减缓甚至下降，N75、N150、N225 和 N300 的年平均产量分别比 N0 增加 36.3%、51.5%、55.4% 和 47.6%。MNPK 的平均谷物产量比 NPK 高 13.9%。因此，粪肥与 150 kg ha-1 氮肥的结合是确保旱地小麦高产、控制硝酸盐残留和减少夏季休耕期硝酸盐淋失的最佳施肥策略。这一结果为氮肥减量与粪肥结合在旱地农业中的应用前景提供了有价值的信息。

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来源期刊

Soil & Tillage Research 农林科学-土壤科学

CiteScore

13.00

自引率

6.20%

发文量

266

审稿时长

5 months

期刊介绍： Soil & Tillage Research examines the physical, chemical and biological changes in the soil caused by tillage and field traffic. Manuscripts will be considered on aspects of soil science, physics, technology, mechanization and applied engineering for a sustainable balance among productivity, environmental quality and profitability. The following are examples of suitable topics within the scope of the journal of Soil and Tillage Research: The agricultural and biosystems engineering associated with tillage (including no-tillage, reduced-tillage and direct drilling), irrigation and drainage, crops and crop rotations, fertilization, rehabilitation of mine spoils and processes used to modify soils. Soil change effects on establishment and yield of crops, growth of plants and roots, structure and erosion of soil, cycling of carbon and nutrients, greenhouse gas emissions, leaching, runoff and other processes that affect environmental quality. Characterization or modeling of tillage and field traffic responses, soil, climate, or topographic effects, soil deformation processes, tillage tools, traction devices, energy requirements, economics, surface and subsurface water quality effects, tillage effects on weed, pest and disease control, and their interactions.