Presentation is loading. Please wait.

Presentation is loading. Please wait.

Continuous Time Monte Carlo and Driven Vortices in a Periodic Potential V. Gotcheva, Yanting Wang, Albert Wang and S. Teitel University of Rochester Lattice.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Continuous Time Monte Carlo and Driven Vortices in a Periodic Potential V. Gotcheva, Yanting Wang, Albert Wang and S. Teitel University of Rochester Lattice."— Presentation transcript:

1 Continuous Time Monte Carlo and Driven Vortices in a Periodic Potential V. Gotcheva, Yanting Wang, Albert Wang and S. Teitel University of Rochester Lattice gas dynamics for driven steady states. Particles can hop over energy barriers in a single bound! Can greatly speed up simulation time as compared to continuum molecular dynamics.

2 2D Lattice Coulomb gas integer charge on site i of a periodic square L x L grid f uniform background charge charge neutrality fixes N c particles logarithmic interactions periodic boundary conditions integer charges on a compensating uniform background

3 Continuous time Monte Carlo dynamics Uniform applied force F For a single particle move of displacement  r the energy difference for the move, including work done by F, is Define the rate to move a particle at site i a unit spacing in direction , Rates satisfy local detailed balance. Probability to make the above move is, Sample the distribution P i   to decide which move to make, and then update the simulation clock by

4 Periodic grid of lattice gas represents the minima of a periodic potential with energy barriers E b. Algorithm describes thermal activation over energy barriers when  U < E b. Use particle density f = 1/25 Compute structure function Real space correlation function F = 0 ground state charge configuration is a 5x5 square lattice real space k-space

5 F = 0.10 in x direction a)S(k) after 6000 passes b)S(k) after 10 7 passes c)S(k) after 6x10 7 passes d)C(r) corresponding to (c) Large drive Long time steady state is smectic with flow of particles in periodically spaced channels; channels are out of phase with each other. T = 0.004 L = 50

6 Low drive F = 0.04 in x direction T = 0.004 L = 75 Coexisting liquid and solid phases, as in a 1st order transition. liquid solid F

7 C(r) liquid C(r) solid Solid consists of particles moving in channels parallel to F. Channels are separated by 3 grid spacings. Particles within each channel are separated by 8 1/3 grid spacings on average. This is different than both the ground state or the high drive smectic! F The liquid has long ranged 6-fold orientational order! Local 6-fold clusters prefer to lock into the grid direction transverse to the driving force.

8 moving solid is transversely pinned

Download ppt "Continuous Time Monte Carlo and Driven Vortices in a Periodic Potential V. Gotcheva, Yanting Wang, Albert Wang and S. Teitel University of Rochester Lattice."

Similar presentations

PRAGMA – 9 V.S.S.Sastry School of Physics University of Hyderabad 22 nd October, 2005.

PRAGMA – 9 V.S.S.Sastry School of Physics University of Hyderabad 22 nd October, 2005.
Simulazione di Biomolecole: metodi e applicazioni giorgio colombo

Simulazione di Biomolecole: metodi e applicazioni giorgio colombo
Effective long-range interactions in driven systems David Mukamel.

Effective long-range interactions in driven systems David Mukamel.
Biological fluid mechanics at the micro‐ and nanoscale Lecture 7: Atomistic Modelling Classical Molecular Dynamics Simulations of Driven Systems Anne Tanguy.

Biological fluid mechanics at the micro‐ and nanoscale Lecture 7: Atomistic Modelling Classical Molecular Dynamics Simulations of Driven Systems Anne Tanguy.
Molecular Dynamics at Constant Temperature and Pressure Section 6.7 in M.M.

Molecular Dynamics at Constant Temperature and Pressure Section 6.7 in M.M.
The Wales Group in Context: Exploring Energy Landscapes Research Review by Ryan Babbush Applied Computation 298r February 8, 2013.

The Wales Group in Context: Exploring Energy Landscapes Research Review by Ryan Babbush Applied Computation 298r February 8, 2013.
Ajay Kumar Ghosh Jadavpur University Kolkata, India Vortex Line Ordering in the Driven 3-D Vortex Glass MesoSuperMag 2006 Stephen Teitel University of.

Ajay Kumar Ghosh Jadavpur University Kolkata, India Vortex Line Ordering in the Driven 3-D Vortex Glass MesoSuperMag 2006 Stephen Teitel University of.
Ajay Kumar Ghosh Jadavpur University Kolkata, India Vortex Line Ordering in the Driven 3-D Vortex Glass Vortex Wroc ł aw 2006 Stephen Teitel University.

Ajay Kumar Ghosh Jadavpur University Kolkata, India Vortex Line Ordering in the Driven 3-D Vortex Glass Vortex Wroc ł aw 2006 Stephen Teitel University.
Ajay Kumar Ghosh Jadavpur University Kolkata, India Vortex Line Ordering in the Driven 3-D Vortex Glass Vortex Wroc ł aw 2006 Stephen Teitel University.

Ajay Kumar Ghosh Jadavpur University Kolkata, India Vortex Line Ordering in the Driven 3-D Vortex Glass Vortex Wroc ł aw 2006 Stephen Teitel University.
Lecture 25 Practice problems Boltzmann Statistics, Maxwell speed distribution Fermi-Dirac distribution, Degenerate Fermi gas Bose-Einstein distribution,

Lecture 25 Practice problems Boltzmann Statistics, Maxwell speed distribution Fermi-Dirac distribution, Degenerate Fermi gas Bose-Einstein distribution,
Bose-Fermi solid and its quantum melting in a one-dimensional optical lattice Bin Wang 1, Daw-Wei Wang 2, and Sankar Das Sarma 1 1 CMTC, Department of.

Bose-Fermi solid and its quantum melting in a one-dimensional optical lattice Bin Wang 1, Daw-Wei Wang 2, and Sankar Das Sarma 1 1 CMTC, Department of.
Critical Scaling at the Jamming Transition Peter Olsson, Umeå University Stephen Teitel, University of Rochester Supported by: US Department of Energy.

Critical Scaling at the Jamming Transition Peter Olsson, Umeå University Stephen Teitel, University of Rochester Supported by: US Department of Energy.
Phase Diagram of a Point Disordered Model Type-II Superconductor Peter Olsson Stephen Teitel Umeå University University of Rochester IVW-10 Mumbai, India.

Phase Diagram of a Point Disordered Model Type-II Superconductor Peter Olsson Stephen Teitel Umeå University University of Rochester IVW-10 Mumbai, India.
Ajay Kumar Ghosh Jadavpur University Kolkata, India Vortex Line Ordering in the Driven 3-D Vortex Glass MesoSuperMag 2006 Stephen Teitel University of.

Ajay Kumar Ghosh Jadavpur University Kolkata, India Vortex Line Ordering in the Driven 3-D Vortex Glass MesoSuperMag 2006 Stephen Teitel University of.
Stochastic Roadmap Simulation: An Efficient Representation and Algorithm for Analyzing Molecular Motion Mehmet Serkan Apaydin, Douglas L. Brutlag, Carlos.

Stochastic Roadmap Simulation: An Efficient Representation and Algorithm for Analyzing Molecular Motion Mehmet Serkan Apaydin, Douglas L. Brutlag, Carlos.
Critical Scaling at the Jamming Transition Peter Olsson, Umeå University Stephen Teitel, University of Rochester Supported by: US Department of Energy.

Critical Scaling at the Jamming Transition Peter Olsson, Umeå University Stephen Teitel, University of Rochester Supported by: US Department of Energy.
Lecture 27 Overview Final: May 8, SEC hours (4-7 PM), 6 problems

Lecture 27 Overview Final: May 8, SEC hours (4-7 PM), 6 problems
Jamming Peter Olsson, Umeå University Stephen Teitel, University of Rochester Supported by: US Department of Energy Swedish High Performance Computing.

Jamming Peter Olsson, Umeå University Stephen Teitel, University of Rochester Supported by: US Department of Energy Swedish High Performance Computing.
Relating computational and physical complexity Computational complexity: How the number of computational steps needed to solve a problem scales with problem.

Relating computational and physical complexity Computational complexity: How the number of computational steps needed to solve a problem scales with problem.
Monte Carlo Methods: Basics

Monte Carlo Methods: Basics

Similar presentations

Ads by Google