Soil tillage reduction as a climate change mitigation strategy in Mediterranean cereal‐based cropping systems

IF 5 3区农林科学 Q1 SOIL SCIENCE

Soil Use and Management Pub Date : 2024-05-20 DOI:10.1111/sum.13050

Marco Fiorentini, Roberto Orsini, Stefano Zenobi, Matteo Francioni, Chiara Rivosecchi, Marco Bianchini, Biagio di Tella, Paride D'Ottavio, Luigi Ledda, Rodolfo Santilocchi, Paola Deligios

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Abstract

According to climate change projections, global temperatures would increase by 2°C by 2070, and agriculture is expected to be among the most affected sectors, particularly intensive field crops like cereals. Therefore, researchers need to investigate the most cost‐effective agricultural strategies that can prevent production losses and ensure global food security. This study aimed to identify the limiting factors of durum wheat (Triticum turgidum L. subsp. Durum (Desf.) Husn.) yield production under Mediterranean conditions. Durum wheat yield data of over 5 years (2017–2022), from a 30‐year rainfed long‐term experiment conducted in the ‘Pasquale Rosati’ experimental farm of the Polytechnic University of Marche in Agugliano, Italy (43°32’ N, 13°22′ E, 100 a.s.l.) on Calcaric Gleyic Cambisols with a silt‐clay texture, were analysed and compared with the recorded thermo‐pluviometric trend. The field trial included two soil managements (no tillage vs. conventional tillage) and three Nitrogen (N) fertilization levels (0, 90, and 180 kg N ha−1). The most important driver for durum wheat production was N fertilization. However, in the absence of N fertilization, no tillage showed a higher yield (+1.2 t ha−1) than conventional tillage due to the accumulation of organic matter in the soil. When wheat was fertilized with 90 kg N ha−1, no tillage resulted in 25% yield more than conventional tillage (+1.2 t ha−1), but this occurred only when the increase in temperatures was constant from January until harvest (this happened in 3 of 5 years of monitoring). The non‐constant increase in temperature from January to wheat harvest may hamper crop phenological development and reduce the potential yield. The highest fertilization rate (180 Kg N ha−1) resulted in the highest wheat yields regardless of soil management and thermo‐pluviometric trends (5.78 t ha−1). After N fertilization and soil management, the minimum and maximum temperature in February and the maximum temperature in April were crucial for durum wheat production under Mediterranean condition. When there is non‐constant increase in temperature from January to wheat harvest no‐tillage should be preferred over conventional tillage because wheat yields did not reduce under no tillage. Thus, agricultural policies that support the switch from conventional tillage to no‐tillage management should be promoted to enable food security in Mediterranean environments.

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将减少土壤耕作作为地中海谷物种植系统的气候变化减缓战略

根据气候变化预测，到 2070 年，全球气温将上升 2°C，预计农业将是受影响最严重的部门之一，尤其是谷物等密集型大田作物。因此，研究人员需要调查最具成本效益的农业战略，以防止生产损失，确保全球粮食安全。本研究旨在确定地中海条件下硬粒小麦（Triticum turgidum L. subsp.在意大利阿古利亚诺马尔凯理工大学 "帕斯夸莱-罗萨蒂 "实验农场（北纬 43°32'，东经 13°22'，海拔 100 米）进行的一项为期 30 年的雨水灌溉长期试验中，分析了 5 年（2017-2022 年）的硬质小麦产量数据，并将这些数据与记录的温度-水文趋势进行了比较。田间试验包括两种土壤管理方式（免耕与传统耕作）和三种氮肥水平（0、90 和 180 千克氮/公顷）。氮肥是硬粒小麦生产最重要的驱动因素。然而，在不施氮肥的情况下，由于土壤中有机质的积累，免耕比常规耕作产量更高（+1.2 吨/公顷-1）。当小麦每公顷施 90 千克氮肥时，免耕比常规耕作增产 25%（每公顷增产 1.2 吨），但这只发生在从 1 月到收获期间温度持续上升的情况下（在 5 年的监测中，有 3 年发生了这种情况）。从 1 月到小麦收割期间气温的不稳定上升可能会阻碍作物的物候期发育，降低潜在产量。最高施肥量（每公顷 180 千克氮）导致小麦产量最高（5.78 吨/公顷），与土壤管理和温度-水文趋势无关。在施氮肥和土壤管理之后，2 月份的最低气温和最高气温以及 4 月份的最高气温对地中海条件下的硬粒小麦产量至关重要。如果从 1 月到小麦收割期间气温不持续上升，那么免耕应优于传统耕作，因为免耕不会降低小麦产量。因此，应推广支持从传统耕作转向免耕管理的农业政策，以实现地中海环境下的粮食安全。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Soil Use and Management 农林科学-土壤科学

CiteScore

7.70

自引率

13.20%

发文量

审稿时长

3 months

期刊介绍： Soil Use and Management publishes in soil science, earth and environmental science, agricultural science, and engineering fields. The submitted papers should consider the underlying mechanisms governing the natural and anthropogenic processes which affect soil systems, and should inform policy makers and/or practitioners on the sustainable use and management of soil resources. Interdisciplinary studies, e.g. linking soil with climate change, biodiversity, global health, and the UN’s sustainable development goals, with strong novelty, wide implications, and unexpected outcomes are welcomed.