ISSN 0869-6632 (Print)
ISSN 2542-1905 (Online)

For citation:

Fakhretdinov M. I., Ekomasov E. G. Localized solutions of the φ4 equation in a model with three identical point impurities. Izvestiya VUZ. Applied Nonlinear Dynamics, 2026, vol. 34, iss. 3, pp. 481-492. DOI: 10.18500/0869-6632-003213, EDN: VJZWZL

This is an open access article distributed under the terms of Creative Commons Attribution 4.0 International License (CC-BY 4.0).
Full text PDF(Ru):
PDF icon and_2026-3_fakhretdinov-ekomasov_481-492.pdf
(downloads: 31)
Language: 
Russian
Heading: 
Nonlinear Waves. Solitons. Autowaves. Self-Organization.
Article type: 
Article
UDC: 
530.182.1
DOI: 
10.18500/0869-6632-003213
EDN: 
VJZWZL

Localized solutions of the φ4 equation in a model with three identical point impurities

Autors: 
Fakhretdinov Marat Irekovich, Ufa University of Science and Technology
Ekomasov Evgenii Grigorievich, Ufa University of Science and Technology
Abstract: 

Purpose. In this paper, we investigate collective dynamic effects in a non-integrable φ4 model with three identical point-like attractive impurities. We study the excitation process and subsequent evolution of longlived localized oscillations (impurity modes) initiated by the passage of a kink through the impurity system.

Methods. The study is conducted using a combined approach that integrates analytical methods with direct numerical simulation. Within the analytical framework, based on the method of collective variables for small oscillation amplitudes, a system of coupled linear differential equations is derived to describe the dynamics of three oscillators.

Results. The solution of this system allowed for the determination of the collective excitation spectrum, consisting of three distinct normal mode frequencies. The dependence of these frequencies on the distance between the impurities is analyzed, demonstrating their splitting at small distances and asymptotic convergence to the single-impurity frequency as the distance increases. Numerical solution of the original nonlinear partial differential equation confirmed the existence of three modes and allowed for a detailed study of their dynamics. It has been established that, depending on the initial kink velocity and the distance between the impurities, various types of oscillations can be excited: the first mode (in-phase oscillations), the second mode (oscillations of the outer waves in anti-phase with a stationary central one), and the third mode, characterized by the anti-phase motion of the central impurity relative to the outer ones. It was found that the second and third modes exhibit a thresholdlike localization: they contribute to the dynamics only upon reaching a critical distance, when their frequency drops below √2. A comparison of analytical and numerical results showed good quantitative agreement for large distances and a systematic discrepancy for small ones, attributed to the nonlinearity of the potential.

Conclusion. The results of the work demonstrate that the introduction of a third impurity leads to a qualitative increase in the complexity of the system dynamics, which opens up possibilities for controlling nonlinear waves in media with multiple impurities.

Key words: 
kink
breather
φ4 equation
impurity modes
numerical simulation
Acknowledgments: 
The authors express gratitude for the financial support rendered to the work on this paper by the State Assignment (Order №075-03-2024-123/1 dated February 15, 2024, topic №324-21).
Reference: 
  1. A Dynamical Perspective on the arphi^4 Model: Past, Present and Future. Kevrekidis P, Cuevas-Maraver J, editors. Cham: Springer; 2019. 311 p. DOI: 10.1007/978-3-030-11839-6.
  2. Gani VA, Kudryavtsev AE, Lizunova MA. Kink interactions in the (1+1)-dimensional arphi^6 model. Phys. Rev. D. 2014;89(12):125009. DOI: 10.1103/PhysRevD.89.125009.
  3. Marjaneh AM, Saadatmand D, Zhou K, Dmitriev SV, Zomorrodian ME. High energy density in the collision of n kinks in the arphi^4 model. Commun. Nonlinear Sci. Numer. Simul. 2017;49:30–38. DOI: 10.1016/j.cnsns.2017.01.022.
  4. Yan H, Zhong Y, Liu YX, Maeda KI. Kink–antikink collision in a Lorentz-violating arphi^4 model. Phys. Lett. B. 2020;807:135542. DOI: 10.1016/j.physletb.2020.135542.
  5. Yamaletdinov RD, Slipko VA, Pershin YV. Kinks and antikinks of buckled graphene: a testing ground for the arphi^4 field model. Phys. Rev. B. 2017;96(9):094306. DOI: 10.1103/PhysRevB.96.094306.
  6. Yamaletdinov RD, Romanczukiewicz T, Pershin YV. Manipulating graphene kinks through positive and negative radiation pressure effects. Carbon. 2019;141:253–257. DOI: 10.1016/j.carbon.2018.09.032.
  7. The sine-Gordon Model and its Applications: From Pendula and Josephson Junctions to Gravity and High-Energy Physics. Cuevas-Maraver J, Kevrekidis P, Williams F, editors. Cham: Springer; 2014. 263 p. DOI: 10.1007/978-3-319-06722-3.
  8. Getmanov BS. Soliton bound states in the arphi^4 in two-dimensions field theory. JETP Lett. 1976;24:291–295.
  9. Saadatmand D, Dmitriev SV, Borisov DI, Kevrekidis PG, Fatykhov MA, Javidan K. Effect of the arphi^4 kink's internal mode at scattering on a mathcalPT-symmetric defect. JETP Lett. 2015;101:497–502. DOI: 10.1134/S0021364015070140.
  10. Saadatmand D, Javidan K. Collective-coordinate analysis of inhomogeneous nonlinearlinebreak Klein–Gordon field theory. Braz. J. Phys. 2013;43:48–56. DOI: 10.1007/s13538-012-0113-y.
  11. Marjaneh A, Simas F, Bazeia D. Collisions of kinks in deformed arphi^4 and arphi^6 models. Chaos, Solitons and Fractals. 2022;164:112723. DOI: 10.1016/j.chaos.2022.112723.
  12. Zhang F, Kivshar YS, Vazquez L. Resonant kink-impurity interactions in the arphi^4 model. Phys. Rev. A. 1992;46(8):5214–5220. DOI: 10.1103/PhysRevA.46.5214.
  13. Lizunova MA, Kager J, de Lange S, van Wezel J. Kinks and realistic impurity models in arphi^4-theory. Int. J. Mod. Phys. B. 2022;36(5):2250042. DOI: 10.1142/S0217979222500424.
  14. Lizunova M, Kager J, de Lange S, van Wezel J. Emergence of oscillons in kink–impurity interactions. J. Phys. A: Math. Theor. 2021;54(31):315701. DOI: 10.1088/1751-8121/ac0d36.
  15. Romanczukiewicz T, Shnir Y. Oscillons in the presence of external potential. J. High Energ. Phys. 2018;2018:101. DOI: 10.1007/JHEP01(2018)101.
  16. Fakhretdinov MI, Samsonov KYu, Dmitriev SV, Ekomasov EG. Attractive impurity as a generator of wobbling kinks and breathers in the arphi^4 model. Russ. J. Nonlinear Dyn. 2024;20(1):15–26. DOI: 10.20537/nd231206.
  17. Fakhretdinov MI, Samsonov KYu, Dmitriev SV, Ekomasov EG. Kink dynamics in the arphi^4 model with extended impurity. Russ. J. Nonlinear Dyn. 2023. Vol. 19;(3):303–320. DOI: 10.20537/nd230603.
  18. Dorey P, Romanczukiewicz T. Resonant kink–antikink scattering through quasinormal modes. Phys. Lett. B. 2018;779:117–123. DOI: 10.1016/j.physletb.2018.02.003.
  19. Ekomasov EG, Gumerov AM, Kudryavtsev RV, Dmitriev SV, Nazarov VN. Multisoliton dynamics in the sine-Gordon model with two point impurities. Braz. J. Phys. 2018;48(6):576–584. linebreak. DOI: 10.1007/s13538-018-0606-4.
  20. Samsonov KYu, Kabanov DK, Nazarov VN, Ekomasov EG. Localized nonlinear waves of the sine-Gordon equation in the model with three extended impurities. Comput. Res. Model. 2024;16(4):855–868. DOI: 10.20537/2076-7633-2024-16-4-855-868.
  21. Ekomasov EG, Samsonov KYu, Gumerov AM, Kudryavtsev RV. Nonlinear waves of the sine-Gordon equation in the model with three attracting impurities. Izvestiya VUZ. Applied Nonlinear Dynamics. 2022;30(6):749–765. DOI: 10.18500/0869-6632-003011.
  22. Ekomasov EG, Kudryavtsev RV, Samsonov KYu, Nazarov VN, Kabanov DK. Kink dynamics of the sine-Gordon equation in a model with three identical attracting or repulsive impurities. Izvestiya VUZ. Applied Nonlinear Dynamics. 2023;31(6):693–709. DOI: 10.18500/0869-6632-003069.
  23. Fakhretdinov MI, Ekomasov EG. Localized waves of the arphi^4 equation in models with two extended impurities. Comput. Res. Model. 2025;17(3):437–449. DOI: 10.20537/2076-7633-2025-17-3-437-449.
  24. Fakhretdinov MI, Kabanov DK, Ekomasov EG. Localized waves of the arphi^4 equation in the model with two-point impurities. Rus. J. Nonlin. Dyn. 2025;21(3):419–432. DOI: 10.20537/nd250703.
  25. Schiesser WE. The Numerical Method of Lines: Integration of Partial Differential Equations. San Diego: Academic Press; 2012. 326 p.
  26. Belova TI, Kudryavtsev AE. Solitons and their interactions in classical field theory. Phys. Usp. 1997;40:359–387. DOI: 10.1070/PU1997v040n04ABEH000227.
  27. Israeli M, Orszag SA. Approximation of radiation boundary conditions. Journal of Computational Physics. 1981;41(1):115–135. DOI: 10.1016/0021-9991(81)90082-6.
Received: 
20.11.2025
Accepted: 
10.02.2026
Available online: 
15.02.2026
Published: 
29.05.2026
  • 509 reads