用STICS模型模拟土壤与作物间磷动态：温带地区玉米的形式化及多站点评价

IF 4.5 1区农林科学 Q1 AGRONOMY

European Journal of Agronomy Pub Date : 2024-12-20 DOI:10.1016/j.eja.2024.127475

Mounir Seghouani, Matthieu N. Bravin, Patrice Lecharpentier, Alain Mollier

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引用次数: 0

摘要

土壤-作物模型是研究和管理农业生态系统中磷的相关工具。然而，与氮和碳模型相比，P模型存在延迟。在本研究中，我们通过耦合土壤-植物P模型，将STICS模型扩展到模拟P吸收和P反馈。本文旨在描述磷模型，并给出结果，表明该模型能够模拟不同磷输入水平下玉米的磷吸收和生长响应模式。在温带地区。该模型模拟了土壤磷素有效性和作物磷素需求、吸收和分配。这项工作的一个主要独创性在于，它依赖于土壤溶液磷浓度和磷吸收曲线来模拟土壤磷有效性，以及临界磷稀释曲线来模拟作物磷需求。我们根据来自法国大陆不同地点的四个田间施肥试验的数据集评估了该模型。试验包括以3种施用量（P0、P1、P2）对玉米施用矿物肥，诱导不同作物对磷短缺的反应。该模型在预测整个数据集的动态和种植季结束时的磷素吸收方面显示出很强的能力（EF >0.75）。该模型对作物生物量积累（EF >0.5）和叶面积指数的预测结果令人满意。分别考虑各施肥水平，该模型预测P1和P2处理的最终磷吸收量优于P0处理（EF分别为0.74、0.73和0.62）。尽管如此，P0处理对磷吸收和植物生长的预测仍然令人满意。该模型的良好表现是有希望的，因为它表明该模型具有足够的鲁棒性，可以在不同的土壤磷有效性和磷施肥条件下模拟玉米对磷的吸收。讨论了在其他作物品种、土壤和气候条件下的进一步验证。

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Simulating phosphorus dynamics between the soil and the crop with the STICS model: Formalization and multi-site evaluation on maize in temperate area

Soil-crop models are pertinent tools to study and manage phosphorus (P) in agroecosystems. However, P modeling is suffering a delay as compared to nitrogen and carbon. In this study, we extended the STICS model to simulate the P uptake and P feed-back by coupling it with a soil-plant P model. The paper aims at describing the P model and present the results showing the ability of the model to simulate contrasting P uptake and growth response pattern of maize submitted to different level of P inputs. in temperate area. The model simulates the soil P availability and the crop P demand, uptake, and partitioning. A major originality of this work is that it relies on soil solution P concentration and P sorption curves to simulate soil P availability, and critical P dilution curves to simulate crop P demand. We evaluated the model against a dataset coming from four field fertilization trials located at different site in mainland France. The trials consisted of fertilizing maize with a mineral fertilizer at three application rates (P0, P1, P2) which induced contrasted crop responses to P shortage. The model has shown great ability in predicting P uptake both dynamically and at the end of the cropping season for the entire dataset (EF >0.75). The model has satisfactory predictions of crop biomass accumulation (EF >0.5) and leaf area index. Considering each fertilization level separately, the evaluation has shown that the model had predicted the final P uptake of P1 and P2 treatments better than that of P0 treatment (EF of 0.74, 0.73 and 0.62 for P2, P1, and P0, respectively). The predictions made for the P0 treatment remained nonetheless satisfactory for both P uptake and plant growth. The good performance of the model is promising as it shows that the model is sufficiently robust to simulate maize P uptake across a range of soil P availability and P fertilization under contrasting temperate climatic conditions. Further validation on other crop species and soil and climatic conditions is discussed.

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来源期刊

European Journal of Agronomy 农林科学-农艺学

CiteScore

8.30

自引率

7.70%

发文量

187

审稿时长

4.5 months

期刊介绍： The European Journal of Agronomy, the official journal of the European Society for Agronomy, publishes original research papers reporting experimental and theoretical contributions to field-based agronomy and crop science. The journal will consider research at the field level for agricultural, horticultural and tree crops, that uses comprehensive and explanatory approaches. The EJA covers the following topics: crop physiology crop production and management including irrigation, fertilization and soil management agroclimatology and modelling plant-soil relationships crop quality and post-harvest physiology farming and cropping systems agroecosystems and the environment crop-weed interactions and management organic farming horticultural crops papers from the European Society for Agronomy bi-annual meetings In determining the suitability of submitted articles for publication, particular scrutiny is placed on the degree of novelty and significance of the research and the extent to which it adds to existing knowledge in agronomy.