预测非洲军团虫发生和种群动态的系统动力学模型

IF 6 1区 农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY Agriculture, Ecosystems & Environment Pub Date : 2024-11-26 DOI:10.1016/j.agee.2024.109378
Bonoukpoè Mawuko Sokame , Brian Kipkorir , Komi Mensah Agboka , Saliou Niassy , Yeneneh Belayneh , Maged Elkahky , Henri E.Z. Tonnang
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引用次数: 0

摘要

本研究开发了一个全面的系统动力学模型,用于预测和管理非洲军虫(Spodoptera exempta)的爆发,非洲军虫是非洲各地谷类作物的主要威胁。我们采用系统动力学方法及其原型(因果循环图 (CLD)、强化 (R) 和平衡 (B))来分析害虫的种群动态。研究使用 VENSIM 建模平台(Ventana Systems Inc.该研究整合了从 1980 年到 2023 年的大量数据,包括非洲军团虫的生命周期阶段、气候变量和干预策略,以模拟潜在的爆发情景,并评估各种控制措施的影响。该模型展示了准确捕捉非洲军团虫单生和群生阶段的能力,显示了不同的气候条件如何影响这些阶段并影响非洲各地区的爆发模式。研究结果表明,降水和湿度是影响非洲军团虫爆发的关键因素,这些因素的变化会显著影响害虫的种群动态。模型中的情景分析表明,害虫综合治理(IPM)策略结合了生物防治、文化实践和化学方法,可以有效减少非洲军团虫的数量,减轻对作物的损害。这种方法不仅有助于管理当前的虫害,还能减少对化学农药的依赖,从而促进农业的可持续发展。该模型的模拟深入揭示了军虫爆发的时间和强度,并说明了不同的干预措施如何改变这些动态变化。例如,该研究强调了早期干预的有效性和延迟行动的潜在后果,突出了在害虫管理中及时做出知情决策的重要性。这项研究提供了一种在不同气候条件下预测虫害爆发和评估各种控制策略有效性的方法,从而加深了人们对非洲军虫生态学和管理的了解。通过结合现实世界的数据和模拟现实场景,该模型为研究人员、政策制定者和农民制定有针对性的、有效的和可持续的害虫管理策略提供了宝贵的资源。这项研究以其独特的方式将生物、生态和虫害综合防治战略结合在一起,为应对 S. exempta 在非洲爆发所带来的挑战提供了一种整体方法。这项工作意义重大,有可能加强受非洲军虫影响地区的粮食安全和经济稳定,从而支持在不断变化的全球气候中管理农业害虫的更广泛努力。
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A system dynamics model for predicting African armyworm occurrence and population dynamics
This study develops a comprehensive system dynamics model to predict and manage African armyworm (Spodoptera exempta) outbreaks, a major threat to cereal crops across Africa. We applied system dynamics approache with its archetypes (causal loop diagram (CLD), reinforcing (R) and balancing (B)) to analyse the population dynamics of the pest. The VENSIM modelling platform (Ventana Systems Inc., DSS 8.2) was used to implement the models and carry out the simulations. The research integrates extensive data from 1980 to 2023, encompassing the African armyworm's life cycle stages, climatic variables, and intervention strategies, to simulate potential outbreak scenarios and evaluate the impacts of various control measures. The model demonstrates the ability to accurately capture the solitary and gregarious phases of the armyworm, showing how different climatic conditions influence these phases and affect the outbreak patterns across various African regions. The findings reveal that precipitation and humidity are critical factors affecting African armyworm outbreaks, with variations in these elements significantly influencing the pest population dynamics. Scenario analysis within the model indicates that integrated pest management (IPM) strategies, which combine biological control, cultural practices, and chemical methods, can effectively reduce armyworm populations, and mitigate crop damage. This approach not only helps manage current infestations but also contributes to sustainable agricultural practices by reducing reliance on chemical pesticides. The simulations of the model provide insights into the timing and intensity of armyworm outbreaks and illustrate how different interventions can alter these dynamics. For instance, the study highlights the effectiveness of early intervention and the potential consequences of delayed action, underscoring the importance of timely and informed decision-making in pest management. This research advances the understanding of African armyworm ecology and management by providing an approach that can predict outbreaks and evaluate the effectiveness of various control strategies under different climatic conditions. By incorporating real-world data and simulating realistic scenarios, the model offers a valuable resource for researchers, policymakers, and farmers in developing targeted, effective, and sustainable pest management strategies. This study stands out for its unique integration of biological, ecological, and IPM strategies, providing a holistic approach to addressing the challenges posed by S. exempta outbreaks in Africa. The implications of this work are significant, offering potential to enhance food security and economic stability in regions affected by the African armyworm, thereby supporting broader efforts to manage agricultural pests in a changing global climate.
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来源期刊
Agriculture, Ecosystems & Environment
Agriculture, Ecosystems & Environment 环境科学-环境科学
CiteScore
11.70
自引率
9.10%
发文量
392
审稿时长
26 days
期刊介绍: Agriculture, Ecosystems and Environment publishes scientific articles dealing with the interface between agroecosystems and the natural environment, specifically how agriculture influences the environment and how changes in that environment impact agroecosystems. Preference is given to papers from experimental and observational research at the field, system or landscape level, from studies that enhance our understanding of processes using data-based biophysical modelling, and papers that bridge scientific disciplines and integrate knowledge. All papers should be placed in an international or wide comparative context.
期刊最新文献
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