Geodesic
The role of Allee effect in cannibalistic species: An action plan to sustain the declining cod population
Parimita Roy1 ; Sanjoli Jain1 ; Mohamed Maama2
1 Department of Mathematics, Thapar Institute of Engineering and Technology, Patiala, Punjab
2 Applied Mathematics and Computational Sciences, King Abdullah University of Science and Technology, Thuwal 23955-6900, Kingdom of Saudi Arabia
Mathematical modelling of natural phenomena, Tome 19 (2024), article no. 15.

Voir la notice de l'article provenant de la source EDP Sciences

Atlantic cod collapsed in the late 20th century after being harvested heavily for 50 years. This paper aims to design conservation guidelines for the cod population, which is diminishing due to predation by grey seals and cannibalism. For this purpose, we first designed a continuous time ecological model (with and without the Allee effect) using a system of differential equations consisting of juvenile Atlantic cod, adult Atlantic cod, and grey seals. The developed model has set forth global existence, non-negativity, and long-term behavior. Subsequently, to handle the extinction problem cost-effectively, Pontryagin’s principle is employed to construct the optimal control, which is then numerically solved using an iterative forward–backward method. We numerically explored the impact of the Allee effect on cod survival within the original model and its two extended versions (i) stochastic and (ii) reaction–diffusion, to thoroughly understand the possible consequences wherein a population has cannibalistic tendencies. The numerical comparison between the non-Allee and Allee models (Ordinary, Stochastic, Reaction–Diffusion) reveals that the Allee effect may significantly promote recovery and benefit the cannibalistic population. We adopted a partial rank correlation coefficient (PRCC) to conduct a global sensitivity analysis to estimate the most sensitive parameters responsible for cod prevalence.
DOI : 10.1051/mmnp/2024007

Parimita Roy 1 ; Sanjoli Jain 1 ; Mohamed Maama 2

1 Department of Mathematics, Thapar Institute of Engineering and Technology, Patiala, Punjab
2 Applied Mathematics and Computational Sciences, King Abdullah University of Science and Technology, Thuwal 23955-6900, Kingdom of Saudi Arabia 
@article{MMNP_2024_19_a8,
     author = {Parimita Roy and Sanjoli Jain and Mohamed Maama},
     title = {The role of {Allee} effect in cannibalistic species: {An} action plan to sustain the declining cod population},
     journal = {Mathematical modelling of natural phenomena},
     eid = {15},
     publisher = {mathdoc},
     volume = {19},
     year = {2024},
     doi = {10.1051/mmnp/2024007},
     language = {en},
     url = {http://geodesic.mathdoc.fr/articles/10.1051/mmnp/2024007/}
}
TY  - JOUR
AU  - Parimita Roy
AU  - Sanjoli Jain
AU  - Mohamed Maama
TI  - The role of Allee effect in cannibalistic species: An action plan to sustain the declining cod population
JO  - Mathematical modelling of natural phenomena
PY  - 2024
VL  - 19
PB  - mathdoc
UR  - http://geodesic.mathdoc.fr/articles/10.1051/mmnp/2024007/
DO  - 10.1051/mmnp/2024007
LA  - en
ID  - MMNP_2024_19_a8
ER  - 
%0 Journal Article
%A Parimita Roy
%A Sanjoli Jain
%A Mohamed Maama
%T The role of Allee effect in cannibalistic species: An action plan to sustain the declining cod population
%J Mathematical modelling of natural phenomena
%D 2024
%V 19
%I mathdoc
%U http://geodesic.mathdoc.fr/articles/10.1051/mmnp/2024007/
%R 10.1051/mmnp/2024007
%G en
%F MMNP_2024_19_a8
Parimita Roy; Sanjoli Jain; Mohamed Maama. The role of Allee effect in cannibalistic species: An action plan to sustain the declining cod population. Mathematical modelling of natural phenomena, Tome 19 (2024), article  no. 15. doi : 10.1051/mmnp/2024007. http://geodesic.mathdoc.fr/articles/10.1051/mmnp/2024007/

[1] R.D. Neuenhoff, D.P. Swain, S.P. Cox, M.K. Mcallister, A.W. Trites, C.J. Walters, M.O. Hammill Continued decline of a collapsed population of atlantic cod (gadus morhua) due to predation-driven allee effects Can. J. Fisher. Aquat. Sci. 2019 168 184

[2] L. Akveld, The Cod: AC Jensen. Crowell, New York, NY (1972) 182 pp., US 7.95 (1974).

[3] S.M. Garcia, C. Newton et al., Current Situation, Trends and Prospects in World Capture Fisheries. FAO, Fisheries Department (1995).

[4] M. Kurlansky and R.M. Davidson, Cod: A Biography of the Fish that Changed the World. Phoenix Books (2006).

[5] C.C. on the Status of Endangered Wildlife in Canada), Cosewic Assessment and Status Report on Atlantic Cod (Gadus morhua) in Canada (2010).

[6] K.F. Drinkwater The response of Atlantic cod (Gadus morhua) to future climate change ICES J. Mar. Sci. 2005 1327 1337

[7] P.A. Shelton, A.F. Sinclair, G.A. Chouinard, R. Mohn, D.E. Duplisea Fishing under low productivity conditions is further delaying recovery of northwest Atlantic cod (Gadus morhua) Can. J. Fisher. Aquat. Sci. 2006 235 238

[8] J.A. Brown, G. Minkoff, V. Puvanendran Larviculture of Atlantic cod (Gadus morhua): progress, protocols and problems Aquaculture 2003 357 372

[9] G. Rosenlund, Ó. Halldórsson Cod juvenile production: research and commercial developments Aquaculture 2007 188 194

[10] L.R. Fox Cannibalism in natural populations Annu. Rev. Ecol. Syst. 1975 87 106

[11] B. Bogstad, G.R. Lilly, S. Mehl, O.K. Palsson and G. Stefánsson, Cannibalism and year-class strength in Atlantic cod (Gadus morhua L.) in arcto-boreal ecosystems (Barents sea, Iceland, and Eastern Newfoundland). (1994).

[12] A. Folkvord Growth, survival and cannibalism of cod juveniles (Gadus morhua): effects of feed type, starvation and fish size Aquaculture 1991 41 59

[13] G. Blom, A. Folkvord A snapshot of cannibalism in 0-group Atlantic cod (Gadus morhua) in a marine pond J. Appl. Ichthyol. 1997 177 181

[14] A. Folkvord, H. Otterå Effects of initial size distribution, day length, and feeding frequency on growth, survival, and cannibalism in juvenile Atlantic cod (Gadus morhua L.) Aquaculture 1993 243 260

[15] D. Austin, W. Bowen, J. Mcmillan Intraspecific variation in movement patterns: modeling individual behaviour in a large marine predator Oikos 2004 15 30

[16] W. Bowen, J. Lawson, B. Beck Seasonal and geographic variation in the species composition and size of prey consumed by grey seals (Halichoerus grypus) on the Scotian shelf Can. J. Fisher. Aquat. Sci. 1993 1768 1778

[17] R. Mohn, W. Bowen Grey seal predation on the eastern Scotian shelf: modelling the impact on Atlantic cod Can. J. Fisher. Aquat. Sci. 1996 2722 2738

[18] W.D. Bowen, J. Mcmillan, R. Mohn Sustained exponential population growth of grey seals at sable island, Nova Scotia ICES J. Mar. Sci. 2003 1265 1274

[19] P. Stephens, W. Sutherland and R. Freckleton, What is the Anee effect? Oikos 50 (199) 87.

[20] S.D. Gregory, C.J. Bradshaw, B.W. Brook, F. Courchamp Limited evidence for the demographic Allee effect from numerous species across taxa Ecology 2010 2151 2161

[21] A.M. Kramer, L. Berec, J.M. Drake Allee effects in ecology and evolution J. Anim. Ecol. 2018 7 10

[22] P.A. Stephens, W.J. Sutherland Consequences of the Allee effect for behaviour, ecology and conservation Trends Ecol. Evol. 1999 401 405

[23] A. Veprauskas, J.M. Cushing A juvenile–adult population model: climate change, cannibalism, reproductive synchrony, and strong Allee effects J. Biol. Dyn. 2017 1 24

[24] M.K. Trzcinski, R. Mohn, W.D. Bowen Continued decline of an Atlantic cod population: how important is gray seal predation? Ecol. Applic. 2006 2276 2292

[25] D.M. Keith, J.A. Hutchings Population dynamics of marine fishes at low abundance Can. J. Fisher. Aquat. Sci. 2012 1150 1163

[26] K.A. Vert-Pre, R.O. Amoroso, O.P. Jensen, R. Hilborn Frequency and intensity of productivity regime shifts in marine fish stocks Proc. Natl. Acad. Sci. U.S.A. 2013 1779 1784

[27] G. Chouinard, D. Swain, M. Hammill, G. Poirier Covariation between grey seal (Halichoerus grypus) abundance and natural mortality of cod (Gadus morhua) in the southern gulf of St. Lawrence Can. J. Fisher. Aquat. Sci. 2005 1991 2000

[28] C.S. Holling Some characteristics of simple types of predation and parasitism Can. Entomologist 1959 385 398

[29] A.M. Fisher, S.J. Cornell, G.I. Holwell, T.A. Price Mate-finding Allee effects can be exacerbated or relieved by sexual cannibalism J. Anim. Ecol. 2020 1581 1592

[30] V. Puvanendran, B.J. Laurel, J.A. Brown Cannibalism of Atlantic cod Gadus morhua larvae and juveniles on first-week larvae Aquat. Biol. 2008 113 118

[31] M.R. Rodriguez, N. Smith, T. Phan, J. Woodbury, Y. Kang Interactions between leaf-cutter ants and fungus garden: effects of division of labor, age polyethism, and egg cannibalism Math. Model. Natural Phenomena 2018 30

[32] M.S. Shabbir, Q. Din, K. Ahmad, A. Tassaddiq, A.H. Soori, M.A. Khan Stability, bifurcation, and chaos control of a novel discrete-time model involving Allee effect and cannibalism Adv. Diff. Equ. 2020 1 28

[33] M.S. Shabbir, Q. Din, R. Alabdan, A. Tassaddiq, K. Ahmad Dynamical complexity in a class of novel discretetime predator-prey interaction with cannibalism IEEE Access 2020 100226 100240

[34] P.R. Chowdhury, S. Petrovskii, M. Banerjee Oscillations and pattern formation in a slow–fast prey–predator system Bull. Math. Biol. 2021 1 41

[35] A. Tassaddiq, M.S. Shabbir, Q. Din, K. Ahmad, S. Kazi A ratio-dependent nonlinear predator-prey model with certain dynamical results IEEE Access 2020 195074 195088

[36] W. Alharbi, S. Petrovskii The impact of fragmented habitat’s size and shape on populations with allee effect Math. Model. Natural Phenomena 2016 5 15

[37] M.A. Lewis, P. Kareiva Allee dynamics and the spread of invading organisms Theor. Popul. Biol. 1993 141 158

[38] G. Craciun, F. Nazarov, C. Pantea Persistence and permanence of mass-action and power-law dynamical systems SIAM J. Appl. Math. 2013 305 329

[39] H.L. Smith and H.R. Thieme, Dynamical Systems and Population Persistence, Vol. 118. American Mathematical Society (2011).

[40] P. Roy, S. Jain, M. Maama Assessing the viability of tri-trophic food chain model in designing a conservation plan: the case of dwindling quokka population Ecol. Complex. 2020 100811

[41] M. Garrione, C. Rebelo Persistence in seasonally varying predator-prey systems via the basic reproduction number Nonlinear Anal. Real World Applic. 2016 73 98

[42] P. Rebelo, S. Rosa, C.M. Silva Modelling optimal pest control of non-autonomous predator-prey interaction Math. Model. Natural Phenomena 2022 28

[43] W.H. Fleming and R.W. Rishel, Deterministic and Stochastic Optimal Control, Vol. 1. Springer Science Business Media (2012).

[44] L.S. Pontryagin, Mathematical Theory of Optimal Processes. Routledge (2018).

[45] C. Freitas, E.M. Olsen, E. Moland, L. Ciannelli, H. Knutsen Behavioral responses of Atlantic cod to sea temperature changes Ecol. Evol. 2015 2070 2083

[46] X. Mao, Stochastic Differential Equations and Applications. Elsevier (2007).

[47] N. Dalal, D. Greenhalgh, X. Mao A stochastic model for internal HIV dynamics J. Math. Anal. Applic. 2008 1084 1101

[48] P.C. Fife, Mathematical Aspects of Reacting and Diffusing Systems, Vol. 28. Springer Science Business Media (2013).

[49] W. Chen, M. Wang Qualitative analysis of predator–prey models with Beddington-Deangelis functional response and diffusion Math. Comput. Model. 2005 31 44

[50] G.A. Chouinard, L.G. Currie and G.A. Poirier, Assessment of Cod in the Southern Gulf of St. Lawrence, February 2000. Fisheries Oceans, Science, Canadian Stock Assessment Secretariat (2000).

[51] R.M. Cook, V. Trijoulet The effects of grey seal predation and commercial fishing on the recovery of a depleted cod stock Can. J. Fisher. Aquat. Sci. 2016 1319 1329

[52] M. Crick and M. Hill, The role of sensitivity analysis in assessing uncertainty, in Uncertainty Analysis for Performance Assessments of Radioactive Waste Disposal Systems (1987).

[53] R.L. Iman, J.C. Helton An investigation of uncertainty and sensitivity analysis techniques for computer models Risk Anal. 1988 71 90

[54] R.L. Iman, J.C. Helton The repeatability of uncertainty and sensitivity analyses for complex probabilistic risk assessments Risk Anal. 1991 591 606

[55] D.J. Downing, R. Gardner, F. Hoffman An examination of response-surface methodologies for uncertainty analysis in assessment models Technometrics 1985 151 163

[56] J.R. Butler, S.J. Middlemas, I.M. Graham, R.N. Harris Perceptions and costs of seal impacts on Atlantic salmon fisheries in the moray firth, Scotland: implications for the adaptive co-management of seal-fishery conflict Mar. Policy 2011 317 323

[57] K. Kauhala, M. Kurkilahti Delayed effects of prey fish quality and winter temperature during the birth year on adult size and reproductive rate of Baltic grey seals Mammal Res. 2020 117 126

[58] R.J. Lilley, R.K. Unsworth Atlantic cod (Gadus morhua) benefits from the availability of seagrass (Zostera marina) nursery habitat Global Ecol. Conserv. 2014 367 377

[59] D.J. Higham An algorithmic introduction to numerical simulation of stochastic differential equations SIAM Rev. 2001 525 546

[60] R. Arditi, L.R. Ginzburg Coupling in predator–prey dynamics: ratio-dependence J. Theor. Biol. 1989 311 326

[61] M. Bandyopadhyay, C. Chakrabarti Deterministic and stochastic analysis of a nonlinear prey-predator system J. Biol. Syst. 2003 161 172

[62] M. Bandyopadhyay, J. Chattopadhyay Ratio-dependent predator–prey model: effect of environmental fluctuation and stability Nonlinearity 2005 913

[63] T. Perälä, J.A. Hutchings, A. Kuparinen Allee effects and the allee-effect zone in northwest Atlantic cod Biol. Lett. 2022 20210439

[64] J. Beirão, M. Boulais, V. Gallego, J.K. O’Brien, S. Peixoto, T.R. Robeck, E. Cabrita Sperm handling in aquatic animals for artificial reproduction Theriogenology 2019 161 178

[65] K.E.T. Busch, I.-B. Falk-Petersen, S. Peruzzi, N.A. Rist, K. Hamre Natural zooplankton as larval feed in intensive rearing systems for juvenile production of Atlantic cod (Gadus morhua L.) Aquacult. Res. 2010 1727 1740

[66] O.B. Samuelsen, A.H. Nerland, T. Jørgensen, M.B. Schrøder, T. Svåsand, Ø. Bergh Viral and bacterial diseases of Atlantic cod Gadus morhua, their prophylaxis and treatment: a review Dis. Aquat. Organ. 2006 239 254

Cité par Sources :