Reaction-diffusion equations represent many important and critical applications in engineering and science. Numerical techniques play an important role for solving such equations accurately and efficiently. This paper presents a brief review of meshless methods for solving general diffusion equations, including reaction-diffusion systems.

Diffusion; reaction-diffusion system; engineering and science; numerical modelling; meshless methods

Abd-Elhameed, W.M. and Youssri, Y.H. (2018), “Fifth-kind orthonormal Chebyshev polynomial solutions for fractional differential equations”, Comp. Appl. Math. Vol. 37, pp. 2897–2921.

Ahmad, I., Siraj-ul-Islam and Khaliq, A.Q.M. (2017), “Local RBF method for multi-dimensional partial differential equations”, Comput. Math. Appl. Vol. 74, pp. 292–324.

Arora, R., Singh, S. and Singh, S. (2020), “Numerical solution of second-order two-dimensional hyperbolic equation by bi-cubic B-spline collocation method”, Math. Sci. Vol. 14, pp. 201–213.

Atluri, S.N. and Shen, S.P. (2002), “The Meshless local Petrov-Galerkin (MLPG) method: a simple & less-costly alternative to the finite element and boundary element methods”, CMES, Vol. 3, No. 1, pp. 11-51.

Atluri, S.N. and Zhu, T. (1998), “A new meshless local Petrov–Galerkin (MLPG) approach in computational mechanics”, Computational Mechanics, Vol. 22, pp. 117–27.

Bag, S., Trivedi, A. and De, A. (2009), “Development of a finite element based heat transfer model for conduction mode laser spot welding process using an adaptive volumetric heat source”, International Journal of Thermal Sciences, Vol. 48, pp. 1923–31.

Barrio, R.A. 2008, 'Turing Systems: A General Model for Complex Patterns in Nature', in I. Licata & A. Sakaji (eds), Physics of Emergence and Organization, World Scientific, Singapore, pp. 267-296.

Batra, R.C. and Zhang, G.M. (2008), “SSPH basis functions for meshless method, and comparison of solutions with strong and weak formulations”, Comput. Mech. Vol. 41, pp. 527–545.

Bellomo, N., Bellouquid, A. and Herreroc, M.A. (2007), “From microscopic to macroscopic description of multicellular systems and biological growing tissues”, Comput. Math. Appl. Vol. 53, pp. 647–663.

Belytschko, T., Lu, Y.Y. and Gu, L. (1994), “Element-free Galerkin method”, International Journal for Numerical Methods in Engineering, Vol. 37, pp. 229–56.

Boffi, D., Brezzi F. and Fortin, M. (2013), “Mixed Finite Element Methods and Applications”, Springer-Verlag Berlin Heidelberg.

Chen, C.S., Jankowska, M.A. and Karageorghis, A. (2021), “RBF–DQ algorithms for elliptic problems in axisymmetric domains”, Numer. Algor., in press.

Chen, L. and Liew, K.M. (2011), “A local Petrov-Galerkin approach with moving Kriging interpolation for solving transient heat conduction problems,” Computational Mechanics, Vol. 47, pp. 455–67.

Cheng, R.J., Zhang, L.W. and Liew, K.M. (2014), “Modeling of biological population problems using the element-free kp-Ritz method”, Appl. Math. Comput. Vol. 227, pp. 274–290.

Dai, B., Zheng, B., Liang, Q. and Wang, L. (2013), “Numerical solution of transient heat conduction problems using improved meshless local Petrov-Galerkin method”, Applied Mathematics and Computation, Vol. 219, pp. 10044–52.

Divo, E.A., Kassab, A.J. and Pepper, D.W. (2014), “An introduction to finite element, boundary element, and meshless methods with applications to heat transfer and fluid flow”, American Society of Mechanical Engineers, USA.

Efendiev, Y., Pun, S.M. and Vabishchevich, P. N. (2021), “Temporal splitting algorithms for non-stationary multiscale problems”, J. Comput. Phys. Vol. 439, 110375.

Fofonjka, A. and Milinkovitch, M.C. (2021), “Reaction-diffusion in a growing 3D domain of skin scales generates a discrete cellular automaton”, Nat. Commun. Vol. 12, pp. 1-13.

Gafiychuk, V., Datsko, B. and Meleshko, V. (2008), “Mathematical modeling of time fractional reaction–diffusion systems”, J. Comput. Appl. Math. Vol. 220, pp. 215–225.

Gao, X.W. (2006), “A meshless BEM for isotropic heat conduction problems with heat generation and spatially varying conductivity”, International Journal for Numerical Methods in Engineering, Vol. 66, pp. 1411–31.

Garrappa, R. and Popolizio, M. (2021), “A computationally efficient strategy for time-fractional diffusion-reaction equations”, Comput. Math. Appl., in press.

Gerace, S., Erhart, K., Kassab, A. and Divo, E. (2014), “A model-integrated localized collocation meshless method for large scale three-dimensional heat transfer problems”, Eng. Anal. Bound. Elem. Vol. 45, pp. 2–19.

Gingold, R.A. and Monaghan, J.J. (1977), “Smoothed particle hydrodynamics: theory and application to non-spherical stars”, Monthly Notices of the Royal Astronomical Society, Vol. 181, pp. 375–89.

Giunta, G., Seyed-Allaei, H. and Gerland, U. (2020), “Cross-diffusion induced patterns for a single-step enzymatic reaction”, Commun. Phys. Vol. 3, pp. 1-9.

Grzybowski, B.A., Bishop, K.J. M., Campbell, C.J., Fialkowski, M. and Smoukov, S.K. (2005), “Micro- and nanotechnology via reaction–diffusion”, Soft Matter Vol. 1, pp. 114–128.

Guin, L.N., Haque, M. and Mandal, P.K. (2012), “The spatial patterns through diffusion-driven instability in a predator-prey model”, Appl. Math. Model. Vol. 36, pp. 1825-1841.

Gui-Quan, S., Zhen, J., Quan-Xing, L. and Li, L. (2008), “Pattern formation induced by cross-difiusion in a predator-prey system”, Chinese Physics B Vol. 17(11), pp. 3936-3941.

Heydari, M.H., Avazzadeh, Z. and Atangana, A. (2021), “Orthonormal shifted discrete Legendre polynomials for solving a coupled system of nonlinear variable-order time fractional reaction-advection-diffusion equations”, Appl. Numer. Math. Vol. 161, pp. 425-436.

Iqbal, N. and Wu, R. (2019), “Turing patterns induced by cross-diffusion in a 2D domain with strong Allee effect”, C. R. Acad. Sci. Paris, Ser. I 357, pp. 863–877.

Ivorra, B., Gomez, S., Glowinski, R. and Ramos, A.M. (2017), “Nonlinear advection–diffusion–reaction phenomena involved in the evolution and pumping of oil in open sea: modeling, numerical simulation and validation considering the Prestige and Oleg Naydenov oil spill cases”, J. Sci. Comput. Vol. 70, pp. 1078–1104.

Kansa, E.J. (1990), “Multiquadric—a scattered data approximation scheme with applications to computational fluid dynamics II”, Computers and Mathematics with Applications, Vol. 19 Nos 8/9, pp. 147–61.

Karasözen, B., Mülayim, G., Uzunca, M. and Yıldız, S. (2021), “Reduced order modelling of nonlinear cross-diffusion systems”, Appl. Math. Comput. Vol. 401, 126058.

Khosravifard, A., Hematiyan, M.R. and Marin, L. (2011), “Nonlinear transient heat conduction analysis of functionally graded materials in the presence of heat sources using an improved meshless radial point interpolation method”, Applied Mathematical Modelling, Vol. 35, pp. 4157–74.

Lam, K.Y., Li, H., Yew, Y.K. and Ng, T.Y. (2006), “Development of the meshless Hermite–Cloud method for structural mechanics applications”, International Journal of Mechanical Sciences, Vol. 48, No. 4, pp. 440-50.

Le, P.B.H., Mai-Duy, N. Tran-Cong, T. and Baker, G. (2010), “A Cartesian-grid collocation technique with integrated radial basis functions for mixed boundary value problems”, International Journal for Numerical Methods in Engineering, Vol. 82, pp. 435–63.

Li, G., Ge, J. and Jie, Y. (2003), “Free surface seepage analysis based on the element-free method”, Mechanics Research Communications, Vol. 30, pp. 9-19.

Li, Q.H., Chen, S.S. and Kou, G.X. (2011), “Transient heat conduction analysis using the MLPG method and modified precise time step integration method”, Journal of Computational Physics, Vol. 30, pp. 2736-50.

Li, Q.H., Chen, S.S. and Zeng, J.H. (2013), “A meshless model for transient heat conduction analyses of 3D axisymmetric functionally graded solids”, Chinese Physics B, Vol. 22, No. 12, pp. 120204-1-5.

Liu, G.R., Yu, G.T. and Dai, K.Y. (2004), “Assessment and applications of point interpolation methods for computational mechanics”, International Journal for Numerical Methods in Engineering, Vol. 59, No. 10, pp. 1373-97.

Liu, W.K., Jun, S. and Zhang, Y.F. (1995), “Reproducing kernel particle methods”, International Journal for Numerical Methods in Fluids, Vol. 20, pp. 1081–1106.

Liu, Y., Du, Y., Li, H., Li, J. and He, S. (2015), “A two-grid mixed finite element method for a nonlinear fourth-order reaction–diffusion problem with time-fractional derivative”, Comput. Math. with Appl. Vol. 70(10), 2474-2492.

Lo, W.C. and Mao, S. (2019), “A hybrid stochastic method with adaptive time step control for reaction–diffusion systems”, J. Comput. Phys. Vol. 379, pp. 392–402.

Lou, Y. and Martínez, S. (2009), “Evolution of cross-diffusion and self-diffusion”, J. Biol. Dyn. Vol. 3(4), pp. 410–429.

Lucchesi, M., Alzahrani, H.H., Safta, C. and Knio, O.M. (2019), “A hybrid, non-split, stiff/RKC, solver for advection–diffusion–reaction equations and its application to low-Mach number combustion”, Combust. Theor. Model. Vol. 23(5), pp. 935–955.

Lucy, L.B. (1977), “A numerical approach to the testing of the fission hypothesis”, Astronomical Journal, Vol. 82, pp. 1013–24.

Luo, Z., Gao, J. and Xie, Z. (2015), “Reduced-order finite difference extrapolation model based on proper orthogonal decomposition for two-dimensional shallow water equations including sediment concentration”, J. Math. Anal. Appl. Vol. 429, pp. 901–923.

Ma, M, Gao, M. and Carretero-Gonzales, R. (2019), “Pattern formation for a two-dimensional reaction-diffusion model with chemotaxis”, J. Math. Anal. Appl. Vol. 475, pp. 1883–1909.

Macías-Díaz, J.E. and Vargas-Rodríguez, H. (2021), “Analysis and simulation of numerical schemes for nonlinear hyperbolic predator–prey models with spatial diffusion”, J. Comput. Appl. Math., 113636.

Madzvamuse, A., Ndakwo, H.S. and Barreira, R. (2015), “Cross-diffusion-driven instability for reaction-diffusion systems: analysis and simulations”, J. Math. Biol. Vol. 70, pp. 709–743.

Malchow, A.K., Azhand, A., Knoll, P., Engel, H. and Steinbock, O. (2019), “From nonlinear reaction-diffusion processes to permanent microscale structures”, Chaos Vol. 29, 053129.

Matychack, Y.S., Pavlyna, V.S. and Fedirko, V.M. (1998), “Diffusion processes and mechanics of materials”, Materials Science, Vol. 34(3), pp. 304-314.

Mesmoudi, S., Askour, O. and Braikat, B. (2020), “Radial point interpolation method and high-order continuation for solving nonlinear transient heat conduction problems”, Comptes Rendus Mécanique Vol. 348(8-9), pp. 745-758.

Mohebbi, F. and Evans, B. (2020), “Simultaneous estimation of heat flux and heat transfer coefficient in irregular geometries made of functionally graded materials”, Int. J. Thermofluids Vol. 1-2, 100009.

Murray, J.D. (2003), “Mathematical Biology II: Spatial Models and Biomedical Applications”, Springer.

Nayroles, B., Touzot, G. and Villon, P. (1992), “Generalizing the finite element method: diffuse approximation and diffuse elements”, Computational Mechanics Vol. 10, pp. 307–18.

Neves, A.M.A., Ferreira, A.J.M., Carrera, E., Roque, C.M.C., Cinefra, M., Jorge, R.M.N. and Soares, C.M.M. (2011), “Bending of FGM plates by a sinusoidal plate formulation and collocation with radial basis functions”, Mechanics Research Communications, Vol. 38, pp. 368-71.

Ootao, Y. and Tanigawa, Y. (2005), “Three-dimensional solution for transient thermal stresses of functionally graded rectangular plate due to nonuniform heat supply”, International Journal of Mechanical Sciences, Vol. 47, No. 11, pp. 1769-88.

Pandey, P. and Gómez-Aguilar, J.F. (2021), “On solution of a class of nonlinear variable order fractional reaction–diffusion equation with Mittag–Leffler kernel”, Numer. Methods Partial Differ. Equ. Vol. 37(2), pp. 998-1011.

Quintela, P., Barral, P., Gómez, D., Pena, F.J., Rodríguez, J., Salgado, P. and Vázquez-Méndez,M.E. (eds) (2017) Progress in Industrial Mathematics at ECMI 2016. Switzerland: Springer International Publishing AG.

Rattanakul, C., Lenbury, Y. and Suksamran, J. (2019), “Analysis of advection-diffusion-reaction model for fish population movement with impulsive tagging: stability and traveling wave solution”, Adv. Differ. Equ., pp. 1–15.

Ren, H., Cheng, J. and Huang, A. (2012), “The complex variable interpolating moving least-squares method”, Applied Mathematics and Computation, Vol. 219, pp. 1724–36.

Roque, C.M.C., Cunha, D., Shu, C. and Ferreira, A.J.M. (2011), “A local radial basis functions—Finite differences technique for the analysis of composite plates”, Engineering Analysis with Boundary Elements, Vol. 35, pp. 363–74.

Rossinelli, D., Bayati, B. and Koumoutsakos, P. (2008), “Accelerated stochastic and hybrid methods for spatial simulations of reaction–diffusion systems”, Chem. Phys. Lett. Vol. 451, pp. 136–140.

Ruiz-Baier, R. and Tian, C. (2013), “Mathematical analysis and numerical simulation of pattern formation under cross-diffusion”, Nonlinear Anal. Real World Appl. Vol. 14(1), pp. 601-612.

Sarra, S.A. (2012), “A local radial basis function method for advection-diffusion-reaction equations on complexly shaped domains”, Appl. Math. Comput. Vol. 218, pp. 9853–9865.

Sebestyén, G.S., Faragó, I., Horváth, R., Kersner, R. and Klincsik, M. (2016), “Stability of patterns and of constant steady states for a cross-diffusion system”, J. Comput. Appl. Math. Vol. 293, pp. 208–216.

Settanni, G. and. Sgura, I. (2016), “Devising efficient numerical methods for oscillating patterns in reaction-diffusion systems”, J. Comput. Appl. Math. Vol. 292, pp. 674–693.

Sgura, I., Bozzini, B. and Lacitignola, D. (2012), “Numerical approximation of Turing patterns in electrodeposition by ADI methods”, J. Comput. Appl. Math. Vol. 236, pp. 4132-4147.

Shakeri, F. and Dehghan, M. (2011), “The finite volume spectral element method to solve Turing models in the biological pattern formation”, Comput. Math. with Appl. Vol. 62, pp. 4322–4336.

Shan, Y.Y., Shu, C. and Qin, N. (2009), “Multiquadric finite diference (MQ-FD) method and its application”, Advances in Applied Mathematics and Mechanics, Vol. 1, pp. 615–38.

Shevchenko, V.Y., Makogon, A.I. and Sychov, M.M. (2021), “Modeling of reaction-diffusion processes of synthesis of materials with regular (periodic) microstructure”, Open Ceramics Vol. 6, 100088.

Shirzadi, A., Sladek, V. and Sladek, J. (2013), “A local integral equation formulation to solve coupled nonlinear reaction–diffusion equations by using moving least square approximation”, Eng. Anal. Bound. Elem. Vol. 37, pp. 8–14.

Shirzadi, A., Sladek, V. and Sladek, J. (2013), “A Meshless Simulations for 2D Nonlinear Reaction-diffusion Brusselator System”, CMES, Vol. 95(4), pp. 259-282.

Shivanian, E. and Jafarabadi, A. (2020), “Turing models in the biological pattern formation through spectral meshless radial point interpolation approach”, Eng. Comput. Vol. 36, pp. 271–282.

Shu, C., Ding, H. and Yeo, K.S. (2003), “Local radial basis function-based differential quadrature method and its application to solve two dimensional incompressible Navier–Stokes equations”, Computer Methods in Applied Mechanics and Enginering, Vol. 192, pp. 941–54.

Singh, A., Singh, I.V. and Prakash, R. (2007), “Meshless element free Galerkin method for unsteady nonlinear heat transfer problems”, International Journal of Heat and Mass Transfer, Vol. 50, pp. 1212–19.

Singh, I.V. and Tanaka, M. (2006), “Heat transfer analysis of composite slabs using meshless element free Galerkin method”, Computational Mechanics, Vol. 38, pp. 521–32.

Sladek, J., Sladek, V., Tan, C.L. and Atluri, S.N. (2008), “Analysis of Transient Heat Conduction in 3D Anisotropic Functionally Graded Solids, by the MLPG Method”, CMES, Vol. 32, pp. 161-74.

Smith, C.A. and Yates, C.A. (2021), “Incorporating domain growth into hybrid methods for reaction–diffusion systems”, J. R. Soc. Interface. Vol. 18(177), 20201047.

Sokolov, A., Ali, R. and Turek, S. (2015), “An AFC-stabilized implicit finite element method for partial differential equations on evolving-in-time surfaces”, J. Comput. Appl. Math. Vol. 289, pp. 101–115.

Soleimani, S., Jalaal, M., Bararnia, H., Ghasemi, E., Ganji, D.D. and Mohammadi, F. (2010), “Local RBF-DQ method for two-dimensional transient heat conduction problem”, International Communications in Heat and Mass Transfer, Vol. 37, pp. 1411–18.

Tolstykh, A.I. and Shirobokov, D.A. (2003), “On using radial basis functions in a ‘‘finite difference mode’’ with applications to elasticity problems”, Computational Mechanics, Vol. 33, pp. 68–79.

Turing, A. (1952), “The chemical basis of morphogenesis”, Philosophical Transactions of the Royal Society B Vol. 237, pp. 37–72.

Vanag, V.K. and Epstein, I.R. (2009), “Cross-diffusion and pattern formation in reaction–diffusion systems”, Phys. Chem. Chem. Phys. Vol. 11, pp.897–912.

Wang, B.L. and Mai, Y.W. (2005), “Transient one-dimensional heat conduction problems solved by finite element”, International Journal of Mechanical Sciences, Vol. 47, No. 2, pp. 303-17.

Wang, H., Qin, Q.H. and Kang, Y.L. (2006), “A meshless model for transient heat conduction in functionally graded materials”, Computational Mechanics, Vol. 38, pp. 51–60.

Watson, D.W., Karageorghis, A. and Chen, C.S. (2020), “The radial basis function-differential quadrature method for elliptic problems in annular domains”, J. Comput. Appl. Math. Vol. 363, pp. 53–76.

Wen, Z. and Fu, S. (2009), “Global solutions to a class of multi-species reaction-diffusion systems with cross-diffusions arising in population dynamics”, J. Comput. Appl. Math. Vol. 230(1), pp. 34-43.

Wu, C.P., Chiu, K.H. and Wang, Y.M. (2008), “A meshfree DRK-based collocation method for the coupled analysis of functionally graded magneto-electro-elastic shells and plates”, CMES, Vol. 35, pp. 181–214.

Wu, X.H., Shen, S.P. and Tao, W.Q. (2007), “Meshless local Petrov-Galerkin collocation method for two-dimensional heat conduction problems”, CMES, Vol. 22, pp. 65-76.

Xie, Z. (2012), “Cross-diffusion induced Turing instability for a three species food chain model”, J. Math. Anal. Appl. Vol. 388, pp. 539–547.

Yang, X., Yuan, Z. and Zhou, T. (2013), “Turing pattern formation in a two-species negative feedback system with cross-diffusion”, Int. J. Bifurc. Chaos Appl. Sci. Eng. Vol. 23(9), pp. 1350162-1-1350162-13.

Zhang, X., Zhang, P. and Zhang, L. (2013), “An improved meshless method with almost interpolation property for isotropic heat conduction problems”, Engineering Analysis with Boundary Elements, Vol. 37, pp. 850–59.