Kinetic Monte Carlo Triangular lattice. Diffusion Thermodynamic factor Self Diffusion Coefficient.

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Presentation transcript:

Kinetic Monte Carlo Triangular lattice

Diffusion Thermodynamic factor Self Diffusion Coefficient

Diffusion

Standard Monte Carlo to study diffusion Pick an atom at random

Standard Monte Carlo to study diffusion Pick an atom at random Pick a hop direction

Standard Monte Carlo to study diffusion Pick an atom at random Pick a hop direction Calculate

Standard Monte Carlo to study diffusion Pick an atom at random Pick a hop direction Calculate If ( > random number) do the hop

Kinetic Monte Carlo Consider all hops simultaneously A. B. Bortz, M. H. Kalos, J. L. Lebowitz, J. Comput Phys, 17, 10 (1975). F. M. Bulnes, V. D. Pereyra, J. L. Riccardo, Phys. Rev. E, 58, 86 (1998).

For each potential hop i, calculate the hop rate

For each potential hop i, calculate the hop rate Then randomly choose a hop k, with probability

For each potential hop i, calculate the hop rate Then randomly choose a hop k, with probability = random number

For each potential hop i, calculate the hop rate Then randomly choose a hop k, with probability = random number

Then randomly choose a hop k, with probability = random number

Time After hop k we need to update the time = random number

Two independent stochastic variables: the hop k and the waiting time

Kinetic Monte Carlo Hop every time Consider all possible hops simultaneously Pick hop according its relative probability Update the time such that on average equals the time that we would have waited in standard Monte Carlo A. B. Bortz, M. H. Kalos, J. L. Lebowitz, J. Comput Phys, 17, 10 (1975). F. M. Bulnes, V. D. Pereyra, J. L. Riccardo, Phys. Rev. E, 58, 86 (1998).

Triangular 2-d lattice, 2NN pair interactions

Activation barrier

Thermodynamics

Kinetics