Impact of peer pressure on cooperation evolution in the networked prisoner’s dilemma game with migration mechanisms

doi:10.1088/1674-1056/ade425

Abstract In social and ecological systems, individual migration behavior and peer pressure are crucial factors influencing decision-making and cooperative behavior. However, how migration regulates the evolution of cooperation and the specific role of peer pressure in this process remain to be further investigated. To address this, this study develops a model that incorporates migration mechanisms and peer pressure within the framework of the networked prisoner’s dilemma game. Specifically, we modify the population structure and introduce a migration strategy based on payoff maximization, enabling individuals to dynamically adjust their positions according to the local environment. The model also considers the impact of peer pressure on individual decision-making and introduces heterogeneity in individuals’ sensitivity to pressure, thereby systematically examining the role of both factors in the evolution of cooperative behavior. Based on this framework, we further compare our model with a scenario in which no migration mechanism is present to evaluate its impact on cooperative dynamics. The results reveal that the migration mechanism significantly promotes the evolution of cooperative behavior. Under this mechanism, higher individual sensitivity leads to an increased level of cooperation, and stronger peer pressure intensity more effectively enhances the promotion of cooperation. Additionally, the influence of population structure on cooperation frequency cannot be overlooked. An increase in vacant nodes provides cooperators with greater buffering space and more migration opportunities, making cooperative behavior more stable and facilitating its propagation within the system. These findings suggest that appropriately regulating individual mobility and reinforcing peer pressure constraints can enhance the stability and propagation of cooperative behavior, providing significant theoretical support for social governance, organizational management, and group collaboration.

Keywords: prisoner’s dilemma peer pressure migration mechanism cooperation two-dimensional grid network

Received: 22 February 2025
Revised: 18 April 2025
Accepted manuscript online: 13 June 2025

PACS:	02.50.Le	(Decision theory and game theory)
	87.23.Ge	(Dynamics of social systems)
	07.05.Tp	(Computer modeling and simulation)
	89.75.Fb	(Structures and organization in complex systems)

Fund: This work was supported in part by the National Natural Science Foundation of China (Grant No. 72031009) and Major Project of the National Social Science Foundation of China (Grant No. 20&ZD058).

Corresponding Authors: Yanan Li
E-mail: lynlynlyn0312@126.com

Cite this article:

Xianjia Wang(王先甲), Yanan Li(李亚楠), and Zhipeng Yang(杨志鹏) Impact of peer pressure on cooperation evolution in the networked prisoner’s dilemma game with migration mechanisms 2025 Chin. Phys. B 34 110201

[1] Axelrod R and Hamilton W D 1981 Science 211 1390
[2] Samuni L, Preis A, Mundry R, Deschner T, Crockford C and Wittig R M 2017 Proc. Natl. Acad. Sci. USA 114 268
[3] Wenseleers T, Hart A G and Ratnieks F L 2004 The American Naturalist 164 E154
[4] Paul D B 1988 Journal of the History of Biology 21 411
[5] Colman A M 1995 Game Theory and Its Applications in the Social and Biological Sciences (Publisher: Routledge)
[6] Dawes R M and Messick D M 2000 International Journal of Psychology 35 111
[7] Melbinger A, Cremer J and Frey E 2015 Journal of the Royal Society Interface 12 20150171
[8] Brock W A and Durlauf S N 2001 The Review of Economic Studies 68 235
[9] Da Z and Huang X 2020 Management Science 66 1847
[10] Hofbauer J and Sigmund K 1998 Evolutionary games and population dynamics (Cambridge University Press)
[11] Nowak M A 2006 Evolutionary dynamics: exploring the equations of life (Harvard University Press)
[12] Sigmund K 2010 The Calculus of Selfishness (Princeton University Press)
[13] Chen Z, Geng Y, Chen X and Fu F 2024 New J. Phys. 26 073047
[14] Cliff D 2025 Chaos, Solitons & Fractals 190 115702
[15] Chen Y, Qin S M, Yu L and Zhang S 2008 Phys. Rev. E 77 032103
[16] Hu Y, Wang Z and Li X 2020 Journal of Cleaner Production 265 121703
[17] Cassar A 2007 Games and Economic Behavior 58 209
[18] Barabási A L and Bonabeau E 2003 Scientific American 288 50
[19] Shan S N, Zhang Z C,Wang C J and Han G Q 2024 RAIRO-Operations Research 58 2797
[20] Lind P G, Gallas J A and Herrmann H J 2004 Phys. Rev. E 70 056207
[21] Shen C, Chu C, Shi L, Perc M and Wang Z 2018 Royal Society Open Science 5 180199
[22] Szabó G and Hauert C 2002 Phys. Rev. E 66 062903
[23] Li J, Zhang J and Liu Q 2024 Chin. Phys. B 33 030202
[24] Hauert C and Doebeli M 2004 Nature 428 643
[25] Liu X S, Wu Z X and Guan J Y 2018 Chin. Phys. B 27 120203
[26] Gu C, Wang X, Ding R, Zhao J and Liu Y 2022 Chaos, Solitons & Fractals 164 112658
[27] Wang X and Wang T 2023 Chin. Phys. B 32 100202
[28] Santos F C, Santos M D and Pacheco J M 2008 Nature 454 213
[29] Sun X P, Bi Y Z, Kang H W, Shen Y and Chen Q Y 2024 Chin. Phys. B 33 090204
[30] Nowak M A 2006 Science 314 1560
[31] Számadó S, Balliet D, Giardini F, Power E A and Takács K 2021 Philosophical Transactions of the Royal Society B 376 (1838) 20200286
[32] Pei H, Yan G and Wang H 2021 Chin. Phys. B 30 050203
[33] Hu Q, Zhou M, Jiang Y and Liu X 2024 Applied Mathematics and Computation 482 128977
[34] Liu C, Shi J, Li T and Liu J 2019 Applied Mathematics and Computation 342 247
[35] Battigalli P and Generoso N 2024 Games and Economic Behavior 145 356
[36] Hansen K A, Ibsen-Jensen R and Neyman A 2021 Games and Economic Behavior 128 213
[37] Huang L, Zhang L, Huang C and HanW2025 Chaos, Solitons & Fractals 191 115835
[38] Song Q, Cao Z, Tao R, Jiang W, Liu C and Liu J 2020 Applied Mathematics and Computation 368 124798
[39] Jiang L L, Wang W X, Lai Y C and Wang B H 2010 Phys. Rev. E 81 036108
[40] Cheng H, Dai Q, Li H, Zhu Y, Zhang M and Yang J 2011 New J. Phys. 13 043032
[41] Xiao Z, Chen X and Szolnoki A 2020 New J. Phys. 22 023012
[42] Rand D G, Dreber A, Ellingsen T, Fudenberg D and Nowak M A 2009 Science 325 1272
[43] Mittone L and Ploner M 2011 Experimental Economics 14 203
[44] Van Vugt M 2009 Current Directions in Psychological Science 18 169
[45] Fan R, Wang Y, Chen F, Du K and Wang Y 2022 Journal of Cleaner Production 364 132711
[46] Wang J, Yu F, He J, Chen W, Xu W, Dai W and Ming Y 2023 Chaos, Solitons & Fractals 168 113187
[47] Chang Q and Zhang Y 2021 Euro. Phys. J. B 94 100
[48] Yang H X, Wu Z X, Rong Z and Lai Y C 2015 Phys. Rev. E 91 022121
[49] Gao L, Pan Q and He M 2023 Chaos, Solitons & Fractals 174 113860
[50] Zhang Y, Zeng Z, Pi B and Feng M 2023 Applied Mathematics and Computation 457 128168
[51] Feng M, Li X, Zhao D and Xia C 2023 Chaos, Solitons & Fractals 175 114042
[52] Shu F, Liu X and Li M 2018 Phys. Lett. A 382 1317

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Impact of peer pressure on cooperation evolution in the networked prisoner’s dilemma game with migration mechanisms

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