MATHEMATICAL MODELING OF PLANT, PATHOGEN AND HERBIVORE INTERACTION INCORPORATING ALLEE EFFECT AND HARVESTING

BARASA, ISAAC KHAEMBA

dc.contributor.author	BARASA, ISAAC KHAEMBA
dc.date.accessioned	2023-01-10T07:06:29Z
dc.date.available	2023-01-10T07:06:29Z
dc.date.issued	2022-12
dc.identifier.citation	[1] Abate T., Ebro A. and Nigatu L. Evaluation of rangeland in arid and semi-arid grazing land of south East Ethiopia.International Journal of Agricultural science, 2012; 2(7), pp 221-234. [2] Allee W. C. Animal Aggregations: Study in General Sociology. Univer sity of Chicago.Press Chicago, 1931. [3] Asfaw, M. D., Kassa, S. M. and Lungu, E. M. The plant-herbivore in teraction with Allee effect.BIUST Research and Innovation Symposium (RDAIS). Botswana International University of Science and Technol ogy Palapye, Botswana, 2017; June, 12-14. [4] Asfaw M. D., Kassa S. M. and Lungu E. M. Coexistence of thresh old in the dynamics of the plant-,L’Dherbivore interaction with Allee effect and harvest.International journal of Biomathematics, 2018; 11(4)1850057. [5] Asfaw M.D., Kassa S. M, Lungu E. M. Effects of temperature and rainfall in plant-herbivore interactions at different altitude. Ecological Modelling. 2019;460:50-59 [6] Audrey L., Ludovic M., Yves D., F´ed´eric G. Direct and apparent com pensation in plant-herbivore interactions.Ecological modeling, Elsevier, Special issue of the 4 th international symposium on Plant Growth Mod eling,Simulation, Visualization and Application, 2014. [7] Bandyopadhyay M. and Saha T. Plant-herbivore model.J. Appl. Math and Computing, 2005; 19(1-2), pp. 327-344. [8] Birkhoff G.,Rota G. C. Ordinary Differential Equation, Ginn and Co. Boston, 1982. [9] Buckley Y. M, Rees M., Sheppard A. W and Smith M.J. Stable coexis tence of an invasive plant and biocontrol agent: a paractrized coupled plant herbivore model.In journal of Applied Ecology, 2005;Vol.19, pp 70-79. [10] Cindy P. and David W. Differentiated plant-defense strategies: Herbivore community dynamical affects plant-herbivore interaction, 2022:13401 [11] Crawley M. S. The herbivore dynamics. In; Crawley M. S. ed. Plant Ecology.Second edition. Oxford; Blackwell scientific, 1997. [12] Courchamp F., Berec and Gascoigne S. Allee effect in Ecology Conser vation. Oxford University. Press, Oxford, 2008. [13] Dudareva N., Nerge F., Nagegowda DA, Orlova I. Plant volatile:recent advances and future perspectives, Crit Rev Plant, 2006; Sci 25, pp. 417-440. 46 [14] Goss E. M. and Bergelson J.Fitness consequences of interaction of arabidopsis thaliana with its natural bacterial pathogen pseudomonas viridiflava.Oecologia, 2007; 152(1), pp. 71-81. [15] Hauntly N. Herbivores and the dynamics of communities and ecosys tems.Annual Review of Ecology and systematic, 1991; vol.22, pp. 477- 503. [16] Jones C. G., Lawton J. H. and Shachak M.Organisms as Ecosystem engineers, 1994; Oikos 69, pp. 373-386. [17] Lucas J. A. Plant pathology and plant pathogens. John Wiley and sons, 2020. [18] Khan M.S., Samreen M. et.al. On the qualitative study of a two-trophic plant-herbivore model. J. Math. Bio. 2022 85(34) [19] Mark K. Element of Mathematical Ecology. Cambridge University Press, 2001. [20] Mauck K. E.,Smyers E. De Moraes C. M.; Mescher M. C. Virus infec tion influences host plant interaction with non-vector herbivores and predators function,journal of Ecol , 2015; Vol.29, pp. 662-673. [21] Merdan H.and Karaoglu E. Consequence of Allee effects on stability analysis of the population model,Hacettepe Journal of Mathematics and Statistics, 2012; Vol 4(5), pp. 7551-765. [22] Mith¨ofer A. and Boland W. Recognition of herbivory-associated molec ular patterns. journal of Plant Physiology, 2008; vol.146, pp. 825-831 [23] Mukherjee D. Plant responses to diseases and herbivores attack. A mathematical model.Commun.Math.Bid.Neurosci., 2018; vol.8. [24] Mukherjee D. Effect of constant immigratiom on Plant-pathogen herbivore interactions. Math and Computers simulation(MATCOM), Elsevier, 2019; Vol.160. pp 192-200. [25] Murray J. D. Mathematical Biology: An Introduction,Third Edition. Springer Verlag, Berlin. 2002 [26] Osborne P. L. Tropical ecosystem and ecological concepts. Cambridge University press, 2000. [27] Price P.W., Bouton C.E., Gross P., Mcpheron B.A, Thompson J. F., Weiss A. E. Interaction among three trophic levels: Influence of plants on interactions between insects herbivores and natural enemies, Annu. Rev. Ecol, 1980; pp.41-65. [28] Rees M. and Brown V. K. Invertebrate herbivore and Plant Competi tion.Journal of Ecology, 1992; vol.80, pp. 353-360. [29] Vijayalakshmi S., Gunasekaran M. Complex Dynamics behavior of Disease Spread in a Plant-Herbivore system with Allee effect IJSR, 2015;Vol 11(6), pp 74-83.	en_US
dc.identifier.uri	http://erepository.kafuco.ac.ke/123456789/149
dc.description.abstract	In ecology, interactions between various species that live in a similar habitat are common. In the plant-pathogen-herbivore interactions, plants are invaded by pathogens and herbivores while the herbivores are harvested by natural enemies such as predators and human. Harvesting the species may affect the population densities of the harvested species and keeping harvested species is critical in the ecosystem. On the other hand, the abundance of food does not guarantee exponential growth of species who reproduce sexually and species governed by carrying capacity. Therefore, the Allee effect may be crucial for sustaining such species. Recent plant-pathogen-herbivore models have not taken the Allee effect and species harvesting into account. The main objective of this study was to formulate and analyze a mathematical model of plant-pathogen-herbivore interactions incorporating Allee effect and harvesting. To illustrate the interaction of the species, the model was formulated using a system of ordinary differential equations. The local stability analysis was investigated and numerical simulations were performed using MATLAB software. The stability analysis showed that the ratio of intrinsic growth rate to the environmental carrying capacity of susceptible plants must be greater than certain threshold value to raise sufficient plant biomass to sustain other species. It also shows that the intrinsic growth rate of plants must be greater than the harvesting rate of plant population for plants to get established. Given this circumstance, all species coexists. Numerical simulations show that all species coexist when intrinsic growth rate of plants is greater than the harvesting rate and when conversion rate of what is eaten by herbivores to newborn ones is greater than that of their natural enemies. It also shows that in the absence of susceptible plants, herbivores migrates in search of food, while others deteriorate and die out. Furthermore, regardless of the availability of susceptible plants, the herbivores population goes to extinction if the herbivore population is less than the least number required to keep the herbivores existing in the ecosystem. In the interest of conservation of all species and the environment, policy developers will greatly benefit from understanding the solutions to address human activities for example, clearing land for farming, settlement, infrastructure construction, burning charcoal, and herbivore or their natural enemies hunting. In addition, monitor species closely, especially those that reproduce sexually by establishing and maintaining the least number required to keep the species existing.	en_US
dc.description.sponsorship	KAIMOSI FRIENDS UNIVERSITY	en_US
dc.language.iso	en	en_US
dc.title	MATHEMATICAL MODELING OF PLANT, PATHOGEN AND HERBIVORE INTERACTION INCORPORATING ALLEE EFFECT AND HARVESTING	en_US
dc.type	Thesis	en_US