Abstract
There are a number of situations in which rescaled interacting particle systems have been shown to converge to a reaction diffusion equation (RDE) with a bistable reaction term, see e.g., Cox et al. (Astérisque 349:1–127, 2013), Durrett (Ann Appl Prob 19:477–496, 2009, Electron J Probab 19:1–64, 2014), Durrett and Neuhauser (Ann Probab 22:289–333, 1994). These RDEs have traveling wave solutions. When the speed of the wave is nonzero, block constructions have been used to prove the existence or nonexistence of nontrivial stationary distributions. Here, we follow the approach in a paper by Etheridge et al. (Electron J Probab 22:1–40, 2017) to show that in a wide variety of examples when the RDE limit has a bistable reaction term and traveling waves have speed 0, one can run time faster and further rescale space to obtain convergence to motion by mean curvature. This opens up the possibility of proving that the sexual reproduction model with fast stirring has a discontinuous phase transition, and that in Region 2 of the phase diagram for the nonlinear voter model studied by Molofsky et al. (Theoret Pop Biol 55(1999):270–282, 1999) there were two nontrivial stationary distributions.
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References
Bonaventure, L.: Interface dynamics in an interacting particle system. Nonlinear Anal. 25, 799–819 (1995)
Chen, X.: Generation and propogation of interfaces for reaction–diffusion equations. J. Differ. Equ. 96, 116–141 (1992)
Cox, J.T., Durrett, R., Perkins, E.: Voter model perturbations and reaction diffusion equations. Astérisque 349, 1–127 (2013)
De Masi, A., Orlandi, E., Presutti, E., Trioli, L.: Glauber evolution with Kac potentials: I. Mesoscopic, macroscopic limits, and interface dynamics. Nonlinearity 7, 633–696 (1994)
De Masi, A., Orlandi, E., Presutti, E., Trioli, L.: Glauber evolution with Kac potentials: II. Fluctuations. Nonlinearity 9, 27–51 (1996)
De Masi, A., Orlandi, E., Presutti, E., Trioli, L.: Glauber evolution with Kac potentials: III. Spinoidal decomposition. Nonlinearity 9, 27–51 (1996)
Durrett, R.: Coexistence in stochastic spatial models. (Wald lecture paper). Ann. Appl. Probab. 19, 477–496 (2009)
Durrett, R.: Spatial evolutionary games with small selection coefficients. Electron. J. Probab. 19, 1–64 (2014)
Durrett, R., Neuhauser, C.: Particle systems and reaction–diffusion equations. Ann. Probab. 22, 289–333 (1994)
Etheridge, A., Freeman, N., Penington, S.: Branching Brownian motion, mean curvature flow and the motion of hybrid zones. Electron. J. Probab. 22, 1–40 (2017)
Evans, L.C., Soner, H.M., Souganidis, P.E.: Phase transitions and generalized motion by mean curvature. Commun. Pure. Appl. Math. 45, 1097–1123 (1992)
Evans, L.C., Spruck, J.: Motion of level sets by mean curvature I. Preprint (1992)
Fife, P.C., McLeod, J.B.: The approach of solutions of nonlinear diffusion equations to travelling front solutions. Arch. Ration. Mech. Anal. 65, 335–361 (1977)
Fife, P.C., McLeod, J.B.: A phase plane discussion of convergence to traveling fronts for nonlinear diffusion. Arch. Ration. Mech. Anal. 75, 281–314 (1981)
Funaki, T., Spohn, H.: Motion by mean curvature from the Ginzburg-Landau \(\nabla \phi \) interface model. Commun. Math. Phys. 185, 1–36 (1995)
Funaki, T., Tsunoda, K.: Motion by mean curvature from Glauber–Kawasaki dynamics. J. Stat. Phys. 177, 183–208 (2019)
Kallenberg, O.: Foundations of Modern Probability, vol. 2. Springer, New York (1997)
Katsoulakiis, M.A., Souganidis, P.E.: Generalized motion by mean curvature as a macroscopic limit of stochastic Ising models with long range interactions and Glauber dyanmics. Commun. Math. Phys. 169, 61–97 (1995)
Liggett, T.M.: Interacting Particle Systems. Springer, New York (1985)
Molofsky, J., Durrett, R., Dushoff, J., Griffeath, D., Levin, S.: Local frequency dependence and global coexistence. Theoret. Pop. Biol. 55(1999), 270–282 (1999)
Neuhauser, C., Pacala, S.: An explicitly spatial version of the Lotka–Volterra model with interspecific competition. Ann. Appl. Probab. 9, 1226–1259 (1999)
Sowers, R.B.: Hydrodynamic limits and geometric measure theory: mean curvature limits from threshold voter models. J. Funct. Anal. 169, 121–155 (1999)
Yiup, N.K.: Stochastic motion by mean curvature. Arch. Ration. Mech. Anal. 144, 313–355 (1998)
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Huang, X., Durrett, R. Motion by mean curvature in interacting particle systems. Probab. Theory Relat. Fields 181, 489–532 (2021). https://doi.org/10.1007/s00440-021-01082-0
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DOI: https://doi.org/10.1007/s00440-021-01082-0