Rare Events and Phase Transition in Reaction–Diffusion Systems

1. Rare Events and Phase Transition in Reaction–Diffusion Systems Alex Kamenev, in collaboration with Vlad Elgart, Virginia Tech. PRE 70, 041106 (2004); PRE 74, 041101 (2006); Ann Arbor, June, 2007

2. Binary annihilation Lotka-Volterra model Reaction–Diffusion Models Examples: • Dynamical rules • Discreteness

3. Outline: • Hamiltonian formulation • Rare events calculus • Phase transitions and their classification

4. Rate equation: • PDF: • Extinction time Example: Branching-Annihilation Reaction rules:

5. GF properties: • Generating Function (GF): • Multiply ME by and sum over : extinction probability Master Equation

6. Imaginary time “Schrodinger” equation: Hamiltonian is non-Hermitian Hamiltonian

7. Conservation of probability • If no particles are created from the vacuum Hamiltonian For arbitrary reaction:

8. (rare events !) • Assuming: Hamilton-Jacoby equation • Hamilton equations: • Boundary conditions: Semiclassical (WKB) treatment

9. Rate equation ! Branching-Annihilation Zero energy trajectories !

10. Extinction time

11. Equations of Motion: • Rate Equation: Diffusion “Quantum Mechanics”  “QFT “

12. R Lifetime: Refuge Instanton solution

13. Phase Transitions • Thermodynamic limit • Extinction time vs. diffusion time Hinrichsen 2000

14. Critical exponents Hinrichsen 2000

15. Critical Exponents (cont) • How to calculate critical exponents analytically? • What other reactions belong to the same universality class? • Are there other universality classes and how to classify them?

16. V(j) Ising universality class: j critical parameter • Critical dimension • Renormalization group, -expansion Equilibrium Models • Landau Free Energy: (Lagrangian field theory)

17. q V(j) 1 j p 1 1 critical parameter Reaction-diffusion models • Hamiltonian field theory:

18. Critical dimension Renormalization group, -expansion cf. in d=3 Directed Percolation • Reggeon field theory Janssen 1981, Grassberger 1982 What are other universality classes (if any)?

19. k Effective Hamiltonian: • Example: k = 2 Pair Contact Process with Diffusion (PCPD) k-particle processes • `Triangular’ topology is stable! All reactions start from at least k particles

20. Reactions with additional symmetries • Parity conservation: • Reversibility:

21. Example: First Order Transitions

22. Wake up ! • Hamiltonian formulation and and its semiclassical limit. • Rare events as trajectories in the phase space • Classification of the phase transitions according to the phase space topology