模拟受损水生系统中病毒感染的传播和控制:模式的出现

IF 1.4 4区 综合性期刊 Q2 MULTIDISCIPLINARY SCIENCES Iranian Journal of Science and Technology, Transactions A: Science Pub Date : 2023-01-27 DOI:10.1007/s40995-023-01415-9
Smriti Chandra Srivastava, Nilesh Kumar Thakur
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引用次数: 1

摘要

在本文中,我们提出了一个水生系统中猎物(自由生活的活动物种,如鞭毛虫)和捕食者的生态流行病学模型。捕食者的密度受病毒诱导的猎物和毒性的影响。将病毒感染的传播作为简单的质量定律,猎物与捕食者之间的相互作用用Holling II型功能反应来描述。研究了空间系统和非空间系统模型系统的稳定性分析,并用数值模拟验证了理论结果。探讨了水体系统对承载能力非常敏感,能够产生混沌现象。我们观察了不同携带能力和病毒污染传播的Hopf和跨临界分岔情景。结果表明,高携带能力影响水生系统,病毒也影响物种动态。进一步分析了扩散驱动的图灵不稳定性,观察了基于热簇和冷簇的不同图灵模式,强调了时间变化和病毒污染的影响。本研究结果提供了丰富的动态,表明水质差、营养高的病毒、红绿藻、有毒物质等是造成自然物质死亡、水生生境死亡的原因。在很大程度上,它影响环境和人类健康。
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Modeling the Spread and Control of Viral Infection in Damaged Aquatic System: Emergence of Patterns

In this paper, we propose an eco-epidemiological model for prey (free-living motile species, i.e., dinoflagellates) and predator in an aquatic system. The predator’s density is affected by both virus-induced prey and toxicity. The spread of viral infection is taken as simple law of mass, and interaction between prey and predator is described by the Holling type II functional response. Stability analysis of the model system has been studied for spatial and non-spatial systems, and the theoretical results are verified with numerical simulation. It is explored that the aquatic system is very sensitive to carrying capacity and able to generate chaotic phenomena. We have observed the Hopf and transcritical bifurcation scenario for different carrying capacity and transmission of virus contamination. The results show that high carrying capacity affects the aquatic system, and virus also influences the species dynamics. Further, the diffusion-driven Turing instability is analyzed and different hot and cold cluster-based Turing patterns are observed, emphasizing the effect of time variation and virus contamination. The results obtained in this study give a rich dynamics and show that the viruses with poor water quality, high nutrients, red and green algae, toxic substances, etc. are responsible for natural substances demises, aquatic habitats death. In large, it affects the environment and human health.

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来源期刊
CiteScore
4.00
自引率
5.90%
发文量
122
审稿时长
>12 weeks
期刊介绍: The aim of this journal is to foster the growth of scientific research among Iranian scientists and to provide a medium which brings the fruits of their research to the attention of the world’s scientific community. The journal publishes original research findings – which may be theoretical, experimental or both - reviews, techniques, and comments spanning all subjects in the field of basic sciences, including Physics, Chemistry, Mathematics, Statistics, Biology and Earth Sciences
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