碳累积量有限但氮供应增加的多样化种植制度

IF 27.1 1区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES

Nature Sustainability Pub Date : 2025-01-02 DOI:10.1038/s41893-024-01495-4

Bo Yi, Wenjuan Huang, Matt Liebman, Matthew Woods, Marshall D. McDaniel, Chaoqun Lu, Andy VanLoocke, Sotirios Archontoulis, Bryan Petersen, Siyang Jian, Hanna J. Poffenbarger, Gangsheng Wang, Yiqi Luo, Steven J. Hall

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引用次数: 0

摘要

多样化种植制度为减轻传统农业对环境的影响提供了机会，但对土壤有机碳（SOC）固存和氮(N)动态的影响仍存在争议。我们将20年的田间试验和实验室测量结合起来，采用三种稳定同位素机制模型，研究了传统玉米-大豆系统和两种更多样化的系统（除玉米和大豆外，还包括小谷物、豆类和粪肥）的有机碳储量和分解。与普遍认为多样化系统会增加土壤有机碳的假设相反，我们发现0.3 m表层土壤和1 m剖面土壤有机碳和N储量没有差异。多样化的系统显著提高了氮素矿化率和以前玉米投入的旧有机碳的分解。模型显示，随着数月至数年的停留时间，碳分解的增加抵消了碳输入的增加，但增加了氮供应。我们的研究结果强调了这些多样化系统中碳储存和氮供应之间的关键权衡，表明关键的气候效益可能来自氮肥使用的减少，而不是有机碳的封存。可持续和可再生农业通常采用不同的作物轮作系统来减少对环境的影响和固碳。然而，一项长期的实地研究揭示了土壤有机碳储存和氮供应之间的权衡。

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Diversified cropping systems with limited carbon accrual but increased nitrogen supply

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Diversified cropping systems with limited carbon accrual but increased nitrogen supply

Diversified cropping systems offer a chance to mitigate environmental impacts of conventional agriculture, but effects on soil organic carbon (SOC) sequestration and nitrogen (N) dynamics remain debated. We integrated a 20-year field experiment and laboratory measurements with three stable-isotope-enabled mechanistic models to examine SOC stocks and decomposition in a conventional corn–soybean system and two more diversified systems including small grains, legumes and manure inputs, in addition to corn and soybean. Contrary to the prevalent hypothesis that diversified systems increase SOC, we found no differences in 0.3 m topsoil or 1 m profile SOC and N stocks. Diversified systems markedly increased N mineralization rates and decomposition of older SOC from previous corn inputs. Models revealed that increased C decomposition with residence times of months to years counteracted higher C inputs but increased N supply. Our findings highlight a critical trade-off between C storage and N supply in these diversified systems, demonstrating that key climate benefits may arise from decreased N fertilizer use, not SOC sequestration. Sustainable and regenerative agriculture often employs diverse systems of crop rotation to reduce environmental impacts and sequester carbon. A long-term field study, however, reveals a trade-off between soil organic carbon storage and nitrogen supply.

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来源期刊

Nature Sustainability Energy-Renewable Energy, Sustainability and the Environment

CiteScore

41.90

自引率

1.10%

发文量

159

期刊介绍： Nature Sustainability aims to facilitate cross-disciplinary dialogues and bring together research fields that contribute to understanding how we organize our lives in a finite world and the impacts of our actions. Nature Sustainability will not only publish fundamental research but also significant investigations into policies and solutions for ensuring human well-being now and in the future.Its ultimate goal is to address the greatest challenges of our time.