Boundary Conflicts and Cluster Coarsening: Waves of Life and Death in the Cyclic Competition of Four Species

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1 Boundary Conflicts and Cluster Coarsening: Waves of Life and Death in the Cyclic Competition of Four Species Ahmed Roman, Michel Pleimling Virginia Tech, Blacksburg Friday, October 21 Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 1 / 10

2 Motivation Examples 3 Lizard populations competing cyclically Roman A., Pleimling M. (Virginia Tech, Blacksburg) Condensed Matter Physics Group Friday, October 21 2 / 10

3 Motivation Examples 3 Lizard populations competing cyclically 5 grass populations competing in a complicated manner Roman A., Pleimling M. (Virginia Tech, Blacksburg) Condensed Matter Physics Group Friday, October 21 2 / 10

4 Motivation Examples 3 Lizard populations competing cyclically 5 grass populations competing in a complicated manner 4 species cyclically competing model is a stepping stone in understanding complex food chains of 4 species. Roman A., Pleimling M. (Virginia Tech, Blacksburg) Condensed Matter Physics Group Friday, October 21 2 / 10

5 Motivation Examples 3 Lizard populations competing cyclically 5 grass populations competing in a complicated manner 4 species cyclically competing model is a stepping stone in understanding complex food chains of 4 species. Roman A., Pleimling M. (Virginia Tech, Blacksburg) Condensed Matter Physics Group Friday, October 21 2 / 10

6 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

7 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Randomly choose a position (i, j) on the lattice Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

8 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Randomly choose a position (i, j) on the lattice Randomly choose one of the following (i, j + 1), (i, j 1), (i + 1, j), (i 1, j) Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

9 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Randomly choose a position (i, j) on the lattice Randomly choose one of the following (i, j + 1), (i, j 1), (i + 1, j), (i 1, j) Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

10 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Randomly choose a position (i, j) on the lattice Randomly choose one of the following (i, j + 1), (i, j 1), (i + 1, j), (i 1, j) A + B k A A + A else A + B 1 k A B + A Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

11 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Randomly choose a position (i, j) on the lattice Randomly choose one of the following (i, j + 1), (i, j 1), (i + 1, j), (i 1, j) A + B k A A + A else A + B 1 k A B + A B + C k B B + B else B + C 1 k B C + B Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

12 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Randomly choose a position (i, j) on the lattice Randomly choose one of the following (i, j + 1), (i, j 1), (i + 1, j), (i 1, j) A + B k A A + A else A + B 1 k A B + A B + C k B B + B else B + C 1 k B C + B C + D k C C + C else C + D 1 k C D + C Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

13 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Randomly choose a position (i, j) on the lattice Randomly choose one of the following (i, j + 1), (i, j 1), (i + 1, j), (i 1, j) A + B k A A + A else A + B 1 k A B + A B + C k B B + B else B + C 1 k B C + B C + D k C C + C else C + D 1 k C D + C D + A k D D + D else D + A 1 k D A + D Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

14 Model Definition On a two dimensional square lattice with periodic boundary conditions and an occupation number of 1 per lattice site we randomly distribute the four species A, B, C and D which compete in the following manner: Randomly choose a position (i, j) on the lattice Randomly choose one of the following (i, j + 1), (i, j 1), (i + 1, j), (i 1, j) A + B k A A + A else A + B 1 k A B + A B + C k B B + B else B + C 1 k B C + B C + D k C C + C else C + D 1 k C D + C D + A k D D + D else D + A 1 k D A + D A + C µ AC C + A and B + D µ BD D + B Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 3 / 10

15 Model Cont d Figure: Periodic Boundary Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 4 / 10

16 Model Cont d Figure: Periodic Boundary Definition A Monte-Carlo time step is L 2 reactions where L is the length of the square lattice. Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 4 / 10

17 Model Cont d Figure: Periodic Boundary Definition A Monte-Carlo time step is L 2 reactions where L is the length of the square lattice. Definition The sum of the populations of the species is invariant and is equal to L 2 since the occupation number is 1 element per lattice site. Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 4 / 10

18 Three Species and Pattern Formation Figure: Pattern Formation in 3 Species Model [E. Frey Group] Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 5 / 10

19 Four Species and Cluster Coarsening Remark Alliance Formation (A, C) vs. (B, D) Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 6 / 10

20 Four Species and Cluster Coarsening Remark Alliance Formation (A, C) vs. (B, D) Algebraic Cluster Growth t 1/z where z (.44,.47) Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 6 / 10

21 Four Species and Cluster Coarsening Remark Alliance Formation (A, C) vs. (B, D) Algebraic Cluster Growth t 1/z where z (.44,.47) Finite-Size effects are observed when t 1/z L 2 Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 6 / 10

22 Four Species and Cluster Coarsening Remark Alliance Formation (A, C) vs. (B, D) Algebraic Cluster Growth t 1/z where z (.44,.47) Finite-Size effects are observed when t 1/z L 2 Wave Fronts and Spirals Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 6 / 10

23 Four Species and Cluster Coarsening Remark Alliance Formation (A, C) vs. (B, D) Algebraic Cluster Growth t 1/z where z (.44,.47) Finite-Size effects are observed when t 1/z L 2 Wave Fronts and Spirals Figure: t 100 Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 6 / 10

47) Finite-Size effects are observed when t 1/z L 2 Wave Fronts and Spirals Figure:

24 Four Species and Cluster Coarsening Remark Alliance Formation (A, C) vs. (B, D) Algebraic Cluster Growth t 1/z where z (.44,.47) Finite-Size effects are observed when t 1/z L 2 Wave Fronts and Spirals Figure: t 100 Figure: t 500 Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 6 / 10

25 Space Time Correlation function Definition λ A t (i, j) = { 1 if (i,j) contains A at time t 1 Otherwise. γ A t (i, j, r) = 1 4 λa t (i, j)[λ A t (i + r, j) + λ A t (i r, j) + λ A t (i, j + r) + λ A t (i, j r)] we similarly define γ ξ t (i, j, r) and λ ξ t (i, j) where ξ = B, C or D. Then the space-time correlation function is defined as C t (r) = L 4 L r=1 i=1 j=1 L [γt A (i, j, r) + γt B (i, j, r) + γt C (i, j, r) + γt D (i, j, r)] Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 7 / 10

26 Correlation Function and Geometry Measurement We plot 1 r C 0(0) = constant where r R chosen appropriately as well as C t (r) as function of time, then we plot the intersection of the two traces as a function of time yielding the length scale L t 1/z as a function of time. Problem Are there better geometries to observe the length scale? Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 8 / 10

27 Correlation Function and Geometry Measurement We plot 1 r C 0(0) = constant where r R chosen appropriately as well as C t (r) as function of time, then we plot the intersection of the two traces as a function of time yielding the length scale L t 1/z as a function of time. Problem Are there better geometries to observe the length scale? Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 8 / 10

well as C t (r) as function of time, then we plot the

yielding the length scale L t 1/z as a function of time.

28 Correlation Function and Geometry Measurement We plot 1 r C 0(0) = constant where r R chosen appropriately as well as C t (r) as function of time, then we plot the intersection of the two traces as a function of time yielding the length scale L t 1/z as a function of time. Problem Are there better geometries to observe the length scale? Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 8 / 10

29 Future Work Problem Study the square width of the interface as a function of time. (Work In Progress.) Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 9 / 10

30 Future Work Problem Study the square width of the interface as a function of time. (Work In Progress.) Can we observe patterns in the behavior on the boundary of clusters as a function of thickness? Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 9 / 10

31 Future Work Problem Study the square width of the interface as a function of time. (Work In Progress.) Can we observe patterns in the behavior on the boundary of clusters as a function of thickness? How can we study the physics of the various waves in this system? Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 9 / 10

32 Future Work Problem Study the square width of the interface as a function of time. (Work In Progress.) Can we observe patterns in the behavior on the boundary of clusters as a function of thickness? How can we study the physics of the various waves in this system? Can we observe periodic oscillations in the population sizes as a function of time for the symmetric reaction rates like those observed in the zero dimensional model? Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 9 / 10

33 Future Work Problem Study the square width of the interface as a function of time. (Work In Progress.) Can we observe patterns in the behavior on the boundary of clusters as a function of thickness? How can we study the physics of the various waves in this system? Can we observe periodic oscillations in the population sizes as a function of time for the symmetric reaction rates like those observed in the zero dimensional model? Which confined geometry provides the largest time regime where the dynamical exponent can be observed free of early time effects or finite-size effects? (Work In Progress.) Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October 21 9 / 10

34 Questions Questions Do you have a question? Ask Away... Roman A., Pleimling M. (Virginia Tech, Blacksburg)Condensed Matter Physics Group Friday, October / 10

Spiral Waves Emergence in a Cyclic Predator-Prey Model

Spiral Waves Emergence in a Cyclic Predator-Prey Model Luo-Luo Jiang 1,Wen-XuWang 2,XinHuang 3, and Bing-Hong Wang 1 1 Department of Modern Physics, University of Science and Technology of China, Hefei