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Localized Patterns (2404.14987v2)

Published 23 Apr 2024 in nlin.PS, math.AP, and math.DS

Abstract: Localized patterns are coherent structures embedded in a quiescent state and occur in both discrete and continuous media across a wide range of applications. While it is well-understood how domain covering patterns (for example stripes and hexagons) emerge from a pattern-forming/Turing instability, analyzing the emergence of their localized counterparts remains a significant challenge. There has been considerable progress in studying localized patterns over the past few decades, often by employing innovative mathematical tools and techniques. In particular, the study of localized pattern formation has benefited greatly from numerical techniques; the continuing advancement in computational power has helped to both identify new types patterns and further our understanding of their behavior. We review recent advances regarding the complex behavior of localized patterns and the mathematical tools that have been developed to understand them, covering various topics from spatial dynamics, exponential asymptotics, and numerical methods. We observe that the mathematical understanding of localized patterns decreases as the spatial dimension increases, thus providing significant open problems that will form the basis for future investigations.

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References (266)
  1. B. Akers and P. A. Milewski. Dynamics of three-dimensional gravity-capillary solitary waves in deep water. SIAM Journal on Applied Mathematics, 70(7):2390–2408, 2010.
  2. Spikes and localised patterns for a novel Schnakenberg model in the semi-strong interaction regime. European Journal of Applied Mathematics, Jan. 2022.
  3. F. Al Saadi and P. Parra-Rivas. Transitions between dissipative localized structures in the simplified Gilad–Meron model for dryland plant ecology. Chaos: An Interdisciplinary Journal of Nonlinear Science, 33(3):033129, 03 2023.
  4. J. Allen. The early history of solitons (solitary waves). Physica Scripta, 57(3):436, 1998.
  5. Localized patterns in periodically forced systems. SIAM Journal on Applied Dynamical Systems, 13(3):1311–1327, 2014.
  6. Localized patterns in periodically forced systems: II. Patterns with nonzero wavenumber. SIAM Journal on Applied Dynamical Systems, 17(2):1478–1502, 2018.
  7. S.-i. Amari. Dynamics of pattern formation in lateral-inhibition type neural fields. Biological Cybernetics, 27(2):77–87, 1977.
  8. Isolas versus snaking of localized rolls. Journal of Dynamics and Differential Equations, 31(3):1199–1222, 2019.
  9. Crystallization kinetics and self-induced pinning in cellular patterns. Physical Review E, 62:R5–R8, Jul 2000.
  10. Formation of periodic and localized patterns in an oscillating granular layer. Physica A: Statistical Mechanics and its Applications, 249(1):103–110, 1998.
  11. H. Arbell and J. Fineberg. Temporally harmonic oscillons in newtonian fluids. Physical Review Letters, 85(4):756, 2000.
  12. Pushed-to-pulled front transitions: Continuation, speed scalings, and hidden monotonicty. Journal of Nonlinear Science, 33(6):102, 2023.
  13. Streamwise-localized solutions at the onset of turbulence in pipe flow. Physical Review Letters, 110:224502, May 2013.
  14. Spot dynamics in a reaction-diffusion model of plant root hair initiation. SIAM Journal on Applied Mathematics, 78(1):291–319, 2018.
  15. Bump attractors and waves in networks of leaky integrate-and-fire neurons. SIAM Review, 65(1):147–182, 2023.
  16. To snake or not to snake in the planar Swift-Hohenberg equation. SIAM Journal on Applied Dynamical Systems, 9(3):704–733, 2010.
  17. D. Avitabile and H. Schmidt. Snakes and ladders in an inhomogeneous neural field model. Physica D: Nonlinear Phenomena, 294:24–36, 2015.
  18. D. Avitabile and K. C. Wedgwood. Macroscopic coherent structures in a stochastic neural network: from interface dynamics to coarse-grained bifurcation analysis. Journal of Mathematical Biology, 75(4):885–928, 2017.
  19. Generalized and multi-oscillation solitons in the nonlinear Schrödinger equation with quartic dispersion. Chaos: An Interdisciplinary Journal of Nonlinear Science, 33(7):073154, 07 2023.
  20. Two-and three-dimensional oscillons in nonlinear Faraday resonance. Physical Review letters, 89(10):104101, 2002.
  21. Ring solitons and soliton sacks in imbalanced fermionic systems. Physical Review Research, 2:043282, Nov 2020.
  22. Pulse solutions for an extended klausmeier model with spatially varying coefficients. SIAM Journal on Applied Dynamical Systems, 19(1):1–57, 2020.
  23. Convectons in a rotating fluid layer. Journal of Fluid Mechanics, 717:417–448, 2013.
  24. Homoclinic snaking of localized states in doubly diffusive convection. Physics of Fluids, 23(9):094102, 09 2011.
  25. Convectons and secondary snaking in three-dimensional natural doubly diffusive convection. Physics of Fluids, 25(2):024105, 02 2013.
  26. Three-dimensional doubly diffusive convectons: instability and transition to complex dynamics. Journal of Fluid Mechanics, 840:74–105, 2018.
  27. Localized rotating convection with no-slip boundary conditions. Physics of Fluids, 25(12):124105, 12 2013.
  28. Nonsnaking doubly diffusive convectons and the twist instability. Physics of Fluids, 25(11):114102, 11 2013.
  29. Near-onset dynamics in natural doubly diffusive convection. Journal of Fluid Mechanics, 934:A42, 2022.
  30. Snakes, ladders, and isolas of localized patterns. SIAM Journal on Mathematical Analysis, 41(3):936–972, 2009.
  31. Localized patterns in a generalized Swift–Hohenberg equation with a quartic marginal stability curve. IMA Journal of Applied Mathematics, 86(5):944–983, 08 2021.
  32. A. Bergeon and E. Knobloch. Spatially localized states in natural doubly diffusive convection. Physics of Fluids, 20(3):034102, 03 2008.
  33. Patterns in thin vibrated granular layers: Interfaces, hexagons, and superoscillons. Physical Review E, 61(5):5600, 2000.
  34. S. Blanchflower. Magnetohydrodynamic convectons. Physics Letters A, 261(1-2):74–81, 1999.
  35. S. Blanchflower and N. Weiss. Three-dimensional magnetohydrodynamic convectons. Physics Letters A, 294(5):297–303, 2002.
  36. Microscopic patterns in the 2D phase-field-crystal model. Nonlinearity, 35(3):1500, feb 2022.
  37. Local theory of the slanted homoclinic snaking bifurcation diagram. Physical Review E, 78:036214, Sep 2008.
  38. Solitary localized structures in a liquid crystal light-valve experiment. New Journal of Physics, 11(9):093037, sep 2009.
  39. Bistability between different localized structures in nonlinear optics. Physical review letters, 93(25):253901, 2004.
  40. Cavity light bullets: Three-dimensional localized structures in a nonlinear optical resonator. Physical Review Letters, 93:203901, Nov 2004.
  41. J. Bramburger and M. Holzer. Pattern formation in random networks using graphons. SIAM Journal on Mathematical Analysis, 55(3):2150–2185, 2023.
  42. J. J. Bramburger. Isolas of multi-pulse solutions to lattice dynamical systems. Proceedings of the Royal Society of Edinburgh. Section A. Mathematics, 151(3):916–952, 2021.
  43. Localized radial roll patterns in higher space dimensions. SIAM Journal on Applied Dynamical Systems, 18(3):1420–1453, 2019.
  44. J. J. Bramburger and B. Sandstede. Localized patterns in planar bistable weakly coupled lattice systems. Nonlinearity, 33(7):3500, 2020.
  45. J. J. Bramburger and B. Sandstede. Spatially localized structures in lattice dynamical systems. Journal of Nonlinear Science, 30(2):603–644, 2020.
  46. E. Brand and J. Gibson. A doubly localized equilibrium solution of plane Couette flow. Journal of Fluid Mechanics, 750:R3, 2014.
  47. Asymptotics of cellular buckling close to the Maxwell load. The Royal Society of London. Proceedings. Series A. Mathematical, Physical and Engineering Sciences, 457(2016):2935–2964, 2001.
  48. C. J. Budd and R. Kuske. Localized periodic patterns for the non-symmetric generalized Swift-Hohenberg equation. Physica D. Nonlinear Phenomena, 208(1-2):73–95, 2005.
  49. Existence and conditional energetic stability of three-dimensional fully localised solitary gravity-capillary water waves. Journal of Differential Equations, 254(3):1006–1096, 2013.
  50. A variational reduction and the existence of a fully localised solitary wave for the three-dimensional water-wave problem with weak surface tension. Archive for Rational Mechanics and Analysis, 228(3):773–820, Jun 2018.
  51. Fully localised three-dimensional gravity-capillary solitary waves on water of infinite depth. Journal of Mathematical Fluid Mechanics, 24(2):55, 2022.
  52. Heteroclinic orbits for a system of amplitude equations for orthogonal domain walls. Journal of Differential Equations, 355:193–218, 2023.
  53. J. Burke and J. H. Dawes. Localized states in an extended Swift–Hohenberg equation. SIAM Journal on Applied Dynamical Systems, 11(1):261–284, 2012.
  54. J. Burke and E. Knobloch. Localized states in the generalized Swift-Hohenberg equation. Physical Review E, 73(5):056211, 2006.
  55. J. Burke and E. Knobloch. Homoclinic snaking: structure and stability. Chaos: An Interdisciplinary Journal of Nonlinear Science, 17(3), 2007.
  56. J. Burke and E. Knobloch. Multipulse states in the Swift–Hohenberg equation. In Conference Publications, volume 2009, pages 109–117. AIMS Proceedings, 2009.
  57. Classification of spatially localized oscillations in periodically forced dissipative systems. SIAM Journal on Applied Dynamical Systems, 7(3):651–711, 2008.
  58. Large amplitude radially symmetric spots and gaps in a dryland ecosystem model. Journal of Nonlinear Science, 33(6):107, 2023.
  59. Stationary non-radial localized patterns in the planar Swift–Hohenberg PDE: constructive proofs of existence. Submitted 2024, 2024.
  60. Noise can induce explosions for dissipative solitons. Phys. Rev. E, 85:015205, Jan 2012.
  61. Simultaneous influence of additive and multiplicative noise on stationary dissipative solitons. Phys. Rev. E, 100:012214, Jul 2019.
  62. A. Champneys and F. Al Saadi. Unified framework for localized patterns in reaction-diffusion systems; the Gray-Scott and Gierer-Meinhardt cases. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 379(2213), Nov. 2021.
  63. Localized patterns and semi-strong interaction, a unifying framework for reaction-diffusion systems. IMA Journal of Applied Mathematics, 86(5):1031–1065, Oct. 2021.
  64. Dissecting the snake: Transition from localized patterns to spike solutions. Physica D: Nonlinear Phenomena, 419, May 2021.
  65. S. J. Chapman and G. Kozyreff. Exponential asymptotics of localised patterns and snaking bifurcation diagrams. Physica D. Nonlinear Phenomena, 238(3):319–354, 2009.
  66. W. Chen and M. J. Ward. The stability and dynamics of localized spot patterns in the two-dimensional gray–scott model. SIAM Journal on Applied Dynamical Systems, 10(2):582–666, 2011.
  67. Multistable solitons in higher-dimensional cubic–quintic nonlinear Schrödinger lattices. Physica D: Nonlinear Phenomena, 238(2):126–136, 2009.
  68. Traveling waves in lattice dynamical systems. Journal of Differential Equations, 149(2):248–291, 1998.
  69. Dynamics of lattice differential equations. International Journal of Bifurcation and Chaos, 6(09):1605–1621, 1996.
  70. Waves and bumps in neuronal networks with axo-dendritic synaptic interactions. Physica D: Nonlinear Phenomena, 178(3):219–241, 2003.
  71. P. Coullet and K. Emilsson. Strong resonances of spatially distributed oscillators: a laboratory to study patterns and defects. Physica D: Nonlinear Phenomena, 61(1-4):119–131, 1992.
  72. R. P. Coyle. Localised states in the Zhang-Vinals equations. PhD thesis, University of Leeds, 2023.
  73. Pattern formation outside of equilibrium. Reviews of Modern Physics, 65(3):851, 1993.
  74. J. Dawes. The emergence of a coherent structure for coherent structures: localized states in nonlinear systems. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 368(1924):3519–3534, 2010.
  75. J. Dawes and J. Williams. Localised pattern formation in a model for dryland vegetation. Journal of Mathematical Biology, 73:63–90, 2016.
  76. J. H. Dawes and S. Lilley. Localized states in a model of pattern formation in a vertically vibrated layer. SIAM Journal on Applied Dynamical Systems, 9(1):238–260, 2010.
  77. J. H. P. Dawes. Localized convection cells in the presence of a vertical magnetic field. Journal of Fluid Mechanics, 570:385–406, 2007.
  78. J. H. P. Dawes. Localized pattern formation with a large-scale mode: slanted snaking. SIAM Journal on Applied Dynamical Systems, 7(1):186–206, 2008.
  79. J. H. P. Dawes. After 1952: the later development of Alan Turing’s ideas on the mathematics of pattern formation. Historia Mathematica, 43(1):49–64, 2016.
  80. Orientation-dependent pinning and homoclinic snaking on a planar lattice. SIAM Journal on Applied Dynamical Systems, 14(1):481–521, 2015.
  81. Noisy localized structures induced by large noise. Phys. Rev. E, 91:020901, Feb 2015.
  82. R. L. Devaney. Homoclinic orbits in Hamiltonian systems. Journal of Differential Equations, 21(2):431–438, 1976.
  83. F. Dias and G. Iooss. Chapter 10 - water-waves as a spatial dynamical system. In S. Friedlander and D. Serre, editors, Handbook of Mathematical Fluid Dynamics, volume 2 of Handbook of Mathematical Fluid Dynamics, pages 443–499. North-Holland, 2003.
  84. AUTO-07P: Continuation and bifurcation software for ordinary differential equations, 2007.
  85. A. Doelman and T. J. Kaper. Semistrong pulse interactions in a class of coupled reaction-diffusion equations. SIAM Journal on Applied Dynamical Systems, 2(1):53–96, 2003.
  86. Pattern formation in the one-dimensional Gray-Scott model. Nonlinearity, 10(2):523–563, 1997.
  87. Pulse dynamics in reaction-diffusion equations with strong spatially localized impurities. Philosophical Transactions of the Royal Society A. Mathematical, Physical and Engineering Sciences, 376(2117):20170183, 20, 2018.
  88. A geometric approach to stationary defect solutions in one space dimension. SIAM Journal on Applied Dynamical Systems, 15(2):655–712, 2016.
  89. A. Doelman and F. Veerman. An explicit theory for pulses in two component, singularly perturbed, reaction-diffusion equations. Journal of Dynamics and Differential Equations, 27(3-4):555–595, 2015.
  90. M. Ehrnström and M. D. Groves. Small-amplitude fully localised solitary waves for the full-dispersion Kadomtsev–Petviashvili equation. Nonlinearity, 31(12):5351, oct 2018.
  91. Normal form reduction for time-periodically driven differential equations. Physics Letters A, 120(9):459–463, 1987.
  92. D. Escaff and O. Descalzi. Shape and size effects in localized hexagon patterns. International Journal of Bifurcation and Chaos, 19(08):2727–2743, 2009.
  93. Localized states in an unbounded neural field equation with smooth firing rate function: a multi-parameter analysis. Journal of Mathematical Biology, 66(6):1303–1338, May 2013.
  94. Localized radial bumps of a neural field equation on the Euclidean plane and the Poincaré disc. Nonlinearity, 26(2):437, jan 2013.
  95. On homoclinic snaking in optical systems. Chaos: An Interdisciplinary Journal of Nonlinear Science, 17(3), 2007.
  96. Spatial heterogeneity localizes turing patterns in reaction-cross-diffusion systems. Discrete and Continuous Dynamical Systems - B, 28(12):6092–6125, 2023.
  97. J. P. Gaivao and V. Gelfreich. Splitting of separatrices for the Hamiltonian–Hopf bifurcation with the Swift-Hohenberg equation as an example. Nonlinearity, 24(3):677, 2011.
  98. Time-periodic forcing of spatially localized structures. In M. Tlidi and M. G. Clerc, editors, Nonlinear Dynamics: Materials, Theory and Experiments, pages 303–316, Cham, 2016. Springer International Publishing.
  99. Localized states in periodically forced systems. Physical Review Letters, 114:034102, Jan 2015.
  100. Spatially localized structures in the Gray–Scott model. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 376:20170375, 2018.
  101. Global solutions for 3D quadratic Schrödinger equations. International Mathematics Research Notices, 2009(3):414–432, 2009.
  102. Adopting a spatially explicit perspective to study the mysterious fairy circles of Namibia. Ecography, 38(1):1–11, 2015.
  103. Discovery of fairy circles in Australia supports self-organization theory. Proceedings of the National Academy of Sciences, 113(13):3551–3556, 2016.
  104. R. Goh and A. Scheel. Growing patterns. Nonlinearity, 36(10):R1, 2023.
  105. M. Groves. Steady water waves. Journal of Nonlinear Mathematical Physics, 11:435–460, 2004.
  106. Fully localised solitary-wave solutions of the three-dimensional gravity–capillary water-wave problem. Archive for Rational Mechanics and Analysis, 188(1):1–91, 2008.
  107. Linear and nonlinear front instabilities in bistable systems. Physica D: Nonlinear Phenomena, 217(2):186–192, 2006.
  108. M. Haragus and G. Iooss. Domain walls for the Bénard–Rayleigh convection problem with “rigid–free”boundary conditions. Journal of Dynamics and Differential Equations, 34(4):3217–3236, 2022.
  109. M. Haragus and A. Scheel. Interfaces between rolls in the Swift-Hohenberg equation. International Journal of Dynamical Systems and Differential Equations, 1(2):89–97, 2007.
  110. M. Haragus and A. Scheel. Grain boundaries in the Swift-Hohenberg equation. European Journal of Applied Mathematics, 23(6):737–759, 2012.
  111. J. Härterich. Cascades of reversible homoclinic orbits to a saddle-focus equilibrium. Physica D: Nonlinear Phenomena, 112(1-2):187–200, 1998.
  112. Traveling Water Waves - The Ebb and Flow of Two Centuries. Quarterly of Applied Mathematics, 80(2):317–401, 2022.
  113. Transient localized patterns in noise-driven reaction-diffusion systems. Phys. Rev. Lett., 104:158301, Apr 2010.
  114. Pattern formation in quantum ferrofluids: From supersolids to superglasses. Physical Review Research, 3:033125, Aug 2021.
  115. Approximate localised dihedral patterns near a Turing instability. Nonlinearity, 36(5):2567, 2023.
  116. Dihedral rings of patterns emerging from a Turing bifurcation. Nonlinearity, 37(3):035015, feb 2024.
  117. Localised radial patterns on the free surface of a ferrofluid. Journal of Nonlinear Science, 31(5):1–99, 2021.
  118. A. Hoffman and J. Mallet-Paret. Universality of crystallographic pinning. Journal of Dynamics and Differential Equations, 22(2):79–119, 2010.
  119. Localized states in passive and active phase-field-crystal models. IMA Journal of Applied Mathematics, 86(5):896–923, 07 2021.
  120. Localized plumes in three-dimensional compressible magnetoconvection. Monthly Notices of the Royal Astronomical Society, 412(1):555–560, 03 2011.
  121. R. B. Hoyle. Pattern formation: an introduction to methods. Cambridge University Press, 2006.
  122. Cellular buckling in long structures. Nonlinear Dynamics, 21(1):3–29, 2000.
  123. Propagation failure in the discrete Nagumo equation. Proceedings of the American Mathematical Society, 139(10):3537–3551, 2011.
  124. A. T. Il’ichev. Solitary waves in media with dispersion and dissipation (a review). Fluid Dynamics, 35(2):157–176, Mar 2000.
  125. G. Iooss. Existence of quasipatterns in the superposition of two hexagonal patterns. Nonlinearity, 32(9):3163, 2019.
  126. G. Iooss and A. Mielke. Bifurcating time-periodic solutions of Navier–Stokes equations in infinite cylinders. Journal of Nonlinear Science, 1(1):107–146, 1991.
  127. G. Iooss and M.-C. Pérouème. Perturbed homoclinic solutions in reversible 1:1:111:11 : 1 resonance vector fields. Journal of Differential Equations, 102(1):62–88, 1993.
  128. Localized spot patterns on the sphere for reaction-diffusion systems: Theory and open problems. In J. Bélair, I. A. Frigaard, H. Kunze, R. Makarov, R. Melnik, and R. J. Spiteri, editors, Mathematical and Computational Approaches in Advancing Modern Science and Engineering, pages 641–651, Cham, 2016. Springer International Publishing.
  129. G. Jaramillo and A. Scheel. Deformation of striped patterns by inhomogeneities. Mathematical Methods in the Applied Sciences, 38(1):51–65, 2015.
  130. The effect of impurities on striped phases. Proceedings of the Royal Society of Edinburgh. Section A. Mathematics, 149(1):131–168, 2019.
  131. The existence of localized vegetation patterns in a systematically reduced model for dryland vegetation. Physica D: Nonlinear Phenomena, 412:132637, 2020.
  132. Saddle transport and chaos in the double pendulum. Nonlinear Dynamics, 111(8):7199–7233, 2023.
  133. Spatial localization in heterogeneous systems. Physical Review E, 89:012903, Jan 2014.
  134. K. Kirchgässner. Wave-solutions of reversible systems and applications. Journal of Differential Equations, 45(1):113–127, 1982.
  135. Y. S. Kivshar and B. Luther-Davies. Dark optical solitons: physics and applications. Physics Reports, 298(2):81–197, 1998.
  136. Ostwald ripening in dryland vegetation. Communications on Pure and Applied Analysis, 11(1):261–273, 2012.
  137. E. Knobloch. Spatially localized structures in dissipative systems: open problems. Nonlinearity, 21(4):T45, 2008.
  138. E. Knobloch. Spatial localization in dissipative systems. Annual Review of Condensed Matter Physics, 6(1):325–359, 2015.
  139. E. Knobloch. Localized structures and front propagation in systems with a conservation law. IMA Journal of Applied Mathematics, 81(3):457–487, 2016.
  140. Defectlike structures and localized patterns in the cubic-quintic-septic Swift-Hohenberg equation. Physical Review E, 100(1), jul 2019.
  141. Isolas of 2-pulse solutions in homoclinic snaking scenarios. Journal of Dynamics and Differential Equations, 23(1):93–114, 2011.
  142. Non-reversible perturbations of homoclinic snaking scenarios. Nonlinearity, 25(12):3469, 2012.
  143. J. Knobloch and T. Wagenknecht. Homoclinic snaking near a heteroclinic cycle in reversible systems. Physica D: Nonlinear Phenomena, 206(1):82–93, 2005.
  144. S. Koga and Y. Kuramoto. Localized Patterns in Reaction-Diffusion Systems. Progress of Theoretical Physics, 63(1):106–121, 01 1980.
  145. T. Kolokolnikov and M. Ward. A ring of spikes in a schnakenberg model. Physica D: Nonlinear Phenomena, 441:133521, 2022.
  146. Zigzag and breakup instabilities of stripes and rings in the two-dimensional gray–scott model. Studies in Applied Mathematics, 116(1):35–95, 2006.
  147. G. Kozyreff and S. J. Chapman. Asymptotics of large bound states of localized structures. Physical Review Letters, 97:044502, Jul 2006.
  148. G. Kozyreff and S. J. Chapman. Analytical results for front pinning between an hexagonal pattern and a uniform state in pattern-formation systems. Physical Review Letters, 111:054501, Aug 2013.
  149. R. Kusdiantara and H. Susanto. Homoclinic snaking in the discrete Swift-Hohenberg equation. Physical Review E, 96(6):062214, 2017.
  150. R. Kusdiantara and H. Susanto. Snakes in square, honeycomb and triangular lattices. Nonlinearity, 32(12):5170, 2019.
  151. PDE methods for nonlocal models. SIAM Journal on Applied Dynamical Systems, 2(3):487–516, 2003.
  152. Oscillons and propagating solitary waves in a vertically vibrated colloidal suspension. Physical Review Letters, 83:3190–3193, Oct 1999.
  153. D. Lloyd and B. Sandstede. Localized radial solutions of the Swift-Hohenberg equation. Nonlinearity, 22(2):485, 2009.
  154. D. J. Lloyd. Hexagon invasion fronts outside the homoclinic snaking region in the planar Swift-Hohenberg equation. SIAM Journal on Applied Dynamical Systems, 20(2):671–700, 2021.
  155. Localized hexagon patterns of the planar Swift-Hohenberg equation. SIAM Journal on Applied Dynamical Systems, 7(3):1049–1100, 2008.
  156. D. J. B. Lloyd. Invasion fronts outside the homoclinic snaking region in the planar Swift-Hohenberg equation. SIAM Journal on Applied Dynamical Systems, 18(4):1892–1933, 2019.
  157. Homoclinic snaking near the surface instability of a polarisable fluid. Journal of Fluid Mechanics, 783:283–305, 2015.
  158. D. J. B. Lloyd and H. O’Farrell. On localised hotspots of an urban crime model. Physica D: Nonlinear Phenomena, 253:23–39, 2013.
  159. D. J. B. Lloyd and A. Scheel. Continuation and bifurcation of grain boundaries in the Swift-Hohenberg equation. SIAM Journal on Applied Dynamical Systems, 16(1):252–293, 2017.
  160. Magnetohydrodynamic convectons. Journal of Fluid Mechanics, 687:595–605, 2011.
  161. Three-dimensional spatially localized binary-fluid convection in a porous medium. Journal of Fluid Mechanics, 730:R2, 2013.
  162. Complex convective structures in three-dimensional binary fluid convection in a porous medium. Fluid Dynamics Research, 49(6):061402, nov 2017.
  163. G. J. Lord and V. Thümmler. Computing stochastic traveling waves. SIAM Journal on Scientific Computing, 34(1):B24–B43, 2012.
  164. Y.-P. Ma and E. Knobloch. Two-dimensional localized structures in harmonically forced oscillatory systems. Physica D: Nonlinear Phenomena, 337:1–17, 2016.
  165. E. Makrides and B. Sandstede. Predicting the bifurcation structure of localized snaking patterns. Physica D: Nonlinear Phenomena, 268:59–78, 2014.
  166. E. Makrides and B. Sandstede. Existence and stability of spatially localized patterns. Journal of Differential Equations, 266(2-3):1073–1120, 2019.
  167. B. A. Malomed. Past and present trends in the development of the pattern-formation theory: Domain walls and quasicrystals. Physics, 3(4):1015–1045, 2021.
  168. Domain boundaries in convection patterns. Physical Review A, 42:7244–7263, Dec 1990.
  169. Pattern formation with a conservation law. Nonlinearity, 13(4):1293, jul 2000.
  170. S. McCalla and B. Sandstede. Snaking of radial solutions of the multi-dimensional Swift-Hohenberg equation: a numerical study. Physica D: Nonlinear Phenomena, 239(16):1581–1592, 2010.
  171. S. G. McCalla and B. Sandstede. Spots in the Swift-Hohenberg equation. SIAM Journal on Applied Dynamical Systems, 12(2):831–877, 2013.
  172. N. McCullen and T. Wagenknecht. Pattern formation on networks: from localised activity to Turing patterns. Scientific reports, 6(1):1–8, 2016.
  173. K. McQuighan and B. Sandstede. Oscillons in the planar Ginzburg–Landau equation with 2:1 forcing. Nonlinearity, 27(12):3073, 2014.
  174. Computationally determined existence and stability of transverse structures. II. Multipeaked cavity solitons. Physical Review E, 66(4):046606, 2002.
  175. Optical self-organization and cavity solitons in optically pumped semiconductor microresonators. Physical Review A, 74(2):023818, 2006.
  176. Convectons in periodic and bounded domains. Fluid Dynamics Research, 42(2):025505, dec 2009.
  177. Convectons, anticonvectons and multiconvectons in binary fluid convection. Journal of Fluid Mechanics, 667:586–606, 2011.
  178. Travelling convectons in binary fluid convection. Journal of Fluid Mechanics, 722:240–266, 2013.
  179. Localized structures in dryland vegetation: Forms and functions. Chaos: An Interdisciplinary Journal of Nonlinear Science, 17(3):037109, 2007.
  180. J. W. Miles. Solitary waves. Annual Review of Fluid Mechanics, 12(1):11–43, 1980.
  181. J. W. Miles. Parametrically excited solitary waves. Journal of Fluid Mechanics, 148:451–460, 1984.
  182. D. Morgan and J. H. P. Dawes. The Swift-Hohenberg equation with a nonlocal nonlinearity. Physica D. Nonlinear Phenomena, 270:60–80, 2014.
  183. Existence, stability, and dynamics of ring and near-ring solutions to the saturated Gierer–Meinhardt model in the semistrong regime. SIAM Journal on Applied Dynamical Systems, 16(1):597–639, 2017.
  184. Complex localization mechanisms in networks of coupled oscillators: Two case studies. Chaos: An Interdisciplinary Journal of Nonlinear Science, 34(1), 2024.
  185. Two-dimensional localized states in an active phase-field-crystal model. Physical Review E, 103:032601, Mar 2021.
  186. Snaking bifurcations in a self-excited oscillator chain with cyclic symmetry. Communications in Nonlinear Science and Numerical Simulation, 44:108–119, 2017.
  187. Multiple spatially localized dynamical states in friction-excited oscillator chains. Journal of Sound and Vibration, 417:56–64, 2018.
  188. Three-dimensional waves beneath an ice sheet due to a steadily moving pressure. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 369:2973–2988, 2011.
  189. Nonlinear three-dimensional gravity–capillary solitary waves. Journal of Fluid Mechanics, 536:99–105, 2005.
  190. Nonlinear three-dimensional interfacial flows with a free surface. Journal of Fluid Mechanics, 591:481–494, 2007.
  191. Origin, bifurcation structure and stability of localized states in Kerr dispersive optical cavities. IMA Journal of Applied Mathematics, 86(5):856–895, 08 2021.
  192. Dark solitons in the lugiato-lefever equation with normal dispersion. Physical Review A, 93(6):063839, 2016.
  193. Dynamics of spatially localized states in transitional plane Couette flow. Journal of Fluid Mechanics, 867:414–437, 2019.
  194. Exponential dichotomies for solitary-wave solutions of semilinear elliptic equations on infinite cylinders. Journal of Differential Equations, 140(2):266–308, 1997.
  195. Resonant pattern formation in achemical system. Nature, 388(6643):655–657, 1997.
  196. Y. Pomeau. Front motion, metastability and subcritical bifurcations in hydrodynamics. Physica D: Nonlinear Phenomena, 23(1):3–11, 1986.
  197. Slanted snaking of localized Faraday waves. Physical Review Fluids, 2:064401, Jun 2017.
  198. Continuation of localized coherent structures in nonlocal neural field equations. SIAM Journal on Scientific Computing, 36(1):B70–B93, 2014.
  199. L. Rayleigh. On convection currents in a horizontal layer of fluid, when the higher temperature is on the under side. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 32(192):529–546, 1916.
  200. R. Richter. Mag(net)ic liquid mountains. Europhysics News, 42(3):17–19, 2011.
  201. R. Richter and I. V. Barashenkov. Two-dimensional solitons on the surface of magnetic fluids. Physical Review Letters, 94:184503, May 2005.
  202. The stability of localized spot patterns for the brusselator on the sphere. SIAM Journal on Applied Dynamical Systems, 13(1):564–627, 2014.
  203. A. M. Rucklidge and M. Silber. Design of parametrically forced patterns and quasipatterns. SIAM Journal on Applied Dynamical Systems, 8(1):298–347, 2009.
  204. H. Sakaguchi and H. R. Brand. Stable localized solutions of arbitrary length for the quintic Swift-Hohenberg equation. Physica D: Nonlinear Phenomena, 97(1-3):274–285, 1996.
  205. H. Sakaguchi and H. R. Brand. Stable localized squares in pattern-forming nonequilibrium systems. Europhysics Letters, 38(5):341, 1997.
  206. B. Sandstede and A. Scheel. Defects in oscillatory media: toward a classification. SIAM Journal on Applied Dynamical Systems, 3(1):1–68, 2004.
  207. B. Sandstede and Y. Xu. Snakes and isolas in non-reversible conservative systems. Dynamical Systems, 27(3):317–329, 2012.
  208. A. Scheel. Radially symmetric patterns of reaction-diffusion systems. Memoirs of the American Mathematical Society, 165(786):viii+86, 2003.
  209. H. Schmidt and D. Avitabile. Bumps and oscillons in networks of spiking neurons. Chaos: An Interdisciplinary Journal of Nonlinear Science, 30(3):033133, 2020.
  210. G. Schneider and H. Uecker. Nonlinear PDEs, volume 182. American Mathematical Soc., 2017.
  211. Snakes and ladders: Localized solutions of plane Couette flow. Physical Review Letters, 104:104501, Mar 2010.
  212. Localized edge states nucleate turbulence in extended plane Couette cells. Journal of Fluid Mechanics, 646:441–451, 2010.
  213. V. Solomatov. Localized subcritical convective cells in temperature-dependent viscosity fluids. Physics of the Earth and Planetary Interiors, 200-201:63–71, 2012.
  214. V. S. Solomatov and C. Jain. Stability range of localized subcritical Rayleigh–-Bénard convection in temperature-dependent viscosity fluids: Constraints from two-dimensional simulations. Physics of Fluids, 33(5):056603, 05 2021.
  215. M. G. I. Stewart and D. Schaeffer. Singularities and Group in Bifurcation Theory, Vol II. Springer-Verlag, New-York, 533pp, 2000.
  216. S. H. Strogatz. Nonlinear dynamics and chaos with student solutions manual: With applications to physics, biology, chemistry, and engineering. CRC press, 2018.
  217. Spatially localized quasicrystalline structures. New Journal of Physics, 20(12):122002, 2018.
  218. Snaking without subcriticality: grain boundaries as non-topological defects. IMA Journal of Applied Mathematics, 86(5):1164–1180, 2021.
  219. J. Swift and P. C. Hohenberg. Hydrodynamic fluctuations at the convective instability. Physical Review A, 15(1):319, 1977.
  220. C. Taylor and J. H. Dawes. Snaking and isolas of localised states in bistable discrete lattices. Physics Letters A, 375(1):14–22, 2010.
  221. G. I. Taylor. VIII. stability of a viscous liquid contained between two rotating cylinders. Philosophical Transactions of the Royal Society of London. Series A, Containing Papers of a Mathematical or Physical Character, 223(605-615):289–343, 1923.
  222. Localized states in the conserved Swift-Hohenberg equation with cubic nonlinearity. Physical Review E, 87:042915, Apr 2013.
  223. Snaking bifurcations of localized patterns on ring lattices. IMA Journal of Applied Mathematics, 86(5):1112–1140, 2021.
  224. Optical crystals and light-bullets in Kerr resonators. Chaos, Solitons & Fractals, 152:111364, 2021.
  225. Localized structures and localized patterns in optical bistability. Physical Review Letters, 73(5):640, 1994.
  226. Solitary flexural–gravity waves in three dimensions. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 376, 2018.
  227. Toward convectons in the supercritical regime: Homoclinic snaking in natural doubly diffusive convection. SIAM Journal on Applied Dynamical Systems, 22(3):1710–1742, 2023.
  228. A. M. Turing. The chemical basis of morphogenesis. Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences, 237(641):37–72, 1952.
  229. H. Uecker and D. Wetzel. Snaking branches of planar BCC fronts in the 3D Brusselator. Physica D: Nonlinear Phenomena, 406:132383, 2020.
  230. pde2path - a matlab package for continuation and bifurcation in 2D elliptic systems. Numerical Mathematics: Theory, Methods and Applications, 7(1):58–106, 2014.
  231. Localized excitations in a vertically vibrated granular layer. Nature, 382(6594):793–796, 1996.
  232. Rigorous computation of a radially symmetric localized solution in a Ginzburg-Landau problem. SIAM Journal on Applied Dynamical Systems, 14(1):423–447, 2015.
  233. Spatially complex localisation in twisted elastic rods constrained to a cylinder. International journal of solids and structures, 39(7):1863–1883, 2002.
  234. P. van Heijster and B. Sandstede. Bifurcations to travelling planar spots in a three-component fitzhugh–nagumo system. Physica D: Nonlinear Phenomena, 275:19–34, 2014.
  235. Traveling wave solutions for systems of ODEs on a two-dimensional spatial lattice. SIAM Journal on Applied Mathematics, 59(2):455–493, 1998.
  236. Stationary and oscillatory localized patterns, and subcritical bifurcations. Physical Review letters, 92(12):128301, 2004.
  237. Localized patterns in reaction-diffusion systems. Chaos: An Interdisciplinary Journal of Nonlinear Science, 17(3):037110, 2007.
  238. Oscillatory clusters in the periodically illuminated, spatially extended Belousov–Zhabotinsky reaction. Physical Review Letters, 86(3):552, 2001.
  239. J. Vanden-Broeck. Solitary waves in water: numerical methods and results. In Solitary Waves in Fluids, Advances in fluid mechanics, pages 55–84. WIT Press, 2007.
  240. A. Vanderbauwhede. Centre manifolds, normal forms and elementary bifurcations. In U. Kirchgraber and H. O. Walther, editors, Dynamics Reported: A Series in Dynamical Systems and Their Applications, pages 89–169. Vieweg+Teubner Verlag, Wiesbaden, 1989.
  241. R. Veltz. BifurcationKit. jl. PhD thesis, Inria Sophia-Antipolis, 2020.
  242. S. C. Venkataramani and E. Ott. Pattern selection in extended periodically forced systems: A continuum coupled map approach. Physical Review E, 63(4):046202, 2001.
  243. E. Villar-Sepúlveda and A. R. Champneys. General conditions for Turing and wave instabilities in reaction -diffusion systems. Journal of Mathematical Biology, 86(3):39, 2023.
  244. Two-dimensional clusters of solitary structures in driven optical cavities. Physical Review E, 65:046606, Mar 2002.
  245. Diversity of vegetation patterns and desertification. Physical Review Letters, 87:198101, 2001.
  246. Solitary wave interaction phenomena in a strut buckling model incorporating restabilisation. Physica D: Nonlinear Phenomena, 163(1-2):26–48, 2002.
  247. VisualPDE: rapid interactive simulations of partial differential equations. Bulletin of Mathematical Biology, 85(11):113, 2023.
  248. Z. Wang and P. A. Milewski. Dynamics of gravity–capillary solitary waves in deep water. Journal of Fluid Mechanics, 708:480–501, 2012.
  249. M. J. Ward. Spots, traps, and patches: asymptotic analysis of localized solutions to some linear and nonlinear diffusive systems. Nonlinearity, 31(8):R189, jun 2018.
  250. M. J. Ward and J. Wei. The existence and stability of asymmetric spike patterns for the Schnakenberg model. Studies in Applied Mathematics, 109(3):229–264, 2002.
  251. Time-periodic traveling solutions of localized convection cells in binary fluid mixture. Theoretical and Applied Mechanics Japan, 59:211–219, 2011.
  252. Spontaneous formation of travelling localized structures and their asymptotic behaviour in binary fluid convection. Journal of Fluid Mechanics, 712:219–243, 2012.
  253. A skeleton of collision dynamics: Hierarchical network structure among even-symmetric steady pulses in binary fluid convection. SIAM Journal on Applied Dynamical Systems, 15(2):789–806, 2016.
  254. J. Wei and M. Winter. On the two-dimensional Gierer–Meinhardt system with strong coupling. SIAM Journal on Mathematical Analysis, 30(6):1241–1263, 1999.
  255. J. Wei and M. Winter. Asymmetric spotty patterns for the Gray-–Scott model in R2superscript𝑅2R^{2}italic_R start_POSTSUPERSCRIPT 2 end_POSTSUPERSCRIPT. Studies in Applied Mathematics, 110(1):63–102, 2003.
  256. Modelling the emergence of cities and urban patterning using coupled integro-differential equations. Journal of The Royal Society Interface, 19(190):20220176, 2022.
  257. A mathematical theory of the functional dynamics of cortical and thalamic nervous tissue. Kybernetik, 13(2):55–80, 1973.
  258. T. Wong and M. J. Ward. Weakly nonlinear analysis of peanut-shaped deformations for localized spots of singularly perturbed reaction-diffusion systems. SIAM Journal on Applied Dynamical Systems, 19(3):2030–2058, 2020.
  259. T. Wong and M. J. Ward. Spot patterns in the 2-d schnakenberg model with localized heterogeneities. Studies in Applied Mathematics, 146(4):779–833, 2021.
  260. T. Wong and M. J. Ward. Dynamics of patchy vegetation patterns in the two-dimensional generalized klausmeier model. Discrete and Continuous Dynamical Systems - S, 15(9):2747–2793, 2022.
  261. P. Woods and A. Champneys. Heteroclinic tangles and homoclinic snaking in the unfolding of a degenerate reversible Hamiltonian–Hopf bifurcation. Physica D: Nonlinear Phenomena, 129(3-4):147–170, 1999.
  262. Oscillon dynamics and rogue wave generation in Faraday surface ripples. Physical Review Letters, 109(11):114502, 2012.
  263. A. Yulin and A. Champneys. Snake-to-isola transition and moving solitons via symmetry-breaking in discrete optical cavities. Discrete and Continuous Dynamical Systems - Series S, 4:1341–1357, 2011.
  264. Gradual regime shifts in fairy circles. Proceedings of the National Academy of Sciences, 112(40):12327–12331, 2015.
  265. Fairy circles reveal the resilience of self-organized salt marshes. Science Advances, 7(6):eabe1100, 2021.
  266. Britte reaction of a high-temperature ion melt. Europhysics Letters, 38(4):285, 1997.
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