Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Molecular Simulations Macroscopic EOS (vdW, PR) Little molecular detail Empirical parameters (  ) Seeking understanding of complex systems Surfactants.

Published byNorah Woods Modified over 8 years ago

Similar presentations

Presentation on theme: "1 Molecular Simulations Macroscopic EOS (vdW, PR) Little molecular detail Empirical parameters (  ) Seeking understanding of complex systems Surfactants."— Presentation transcript:

1 1 Molecular Simulations Macroscopic EOS (vdW, PR) Little molecular detail Empirical parameters (  ) Seeking understanding of complex systems Surfactants Cell membranes RNA, DNA

2 Maxwell-Boltzmann Velocity Distribution 2

3 Speed Distribution 3 Read more about manipulation of integral: http://galileo.phys.virginia.edu/classes/252/kinetic_theory.html Fraction of molecules in velocity increment

4 Speed Distribution 4

5 Cumulative Speed Distribution (CH3 at 300K) 5

6 6 Calculating Energy Total Energy U = E KE + E PE Kinetic Energy N m - # sites/molec ( e.g. 3) m i – mass site i; N - # molec Independent of state of aggregation!

7 7 E KE for center of mass Some E KE is directionless (rotational, vibrational) E PE – configurational energy 4 pairs u 0 r/r/ Pair Potential

8 8 Ergodic Theorem Sampling small system over time Molecular Dynamics (MD) Sampling many small systems at one time Monte Carlo (MC), Statistical Mechanics Both methods provide the same expectation values, same results.

9 9 System size 1 cm 3 water - 3.3 E22 molecules Usually use ~1000 atoms of diameter  Methane at liquid density (~5 neighbors < 2.5  ) Need 5000 pair steps per time step Time step usually 1-2 fs (10E-15s) Need O(1E9) eval per ns (1E-9)!  s (1E-6) simulations challenging!

10 10 Using finite size systems Periodic Boundary Conditions e.g. if x i,new < 0, x i,new = x i,new + L Minimum Image Convention Use image if closer than actual site Cutoff Distance Use max cutoff = L/2 to avoid actual and image PE.

11 11 0 0 1’ L L L 2L LL LL trial accepted 5’ 1 2 3 4 5 6 2L See http:// www.etomica.org/app/modules/sites/swmd/pbcCubic.html

12 12 Waldo’s Walk Home Introduction to periodic boundaries and biased sampling (L/2, -L/2) (L/2, L/2) (-L/2, -L/2) (-L/2, L/2) If 10% trained, don’t use this 0.1(360)=36 o (Biased sampliing forces most steps toward the correct direction, but does not prevent errors.) home waldoperiodic.m

13 13 Molecular Monte Carlo Steps If  E step < 0, accept If  E step > 0 If (0 ≤ rand ≤ 1) < exp(-  E step /kT), accept exp(-  Estep/kT)  Estep 0 0 1 accept reject Lots acceptedFew accepted

14 14 Molecular Dynamics Continuous MD Challenge – computer takes finite steps Position, velocity, acceleration out of synch Discontinuous MD (DMD) Hard spheres or step potential Velocities constant until PE changes u r/r/ Step potential

15 15 Mathematics of relative positions, velocities 2 1 r2r2 r1r1 r 12 = r 1 – r 2 v 12  r 12 v 12 1 2 b = magnitude, r 12 v 12 cos  Particles are approaching (dr 12 /dt < 0) when b ≡ r ijv ij < 0

16 16 Dot product b = r 12v 12 = [r 12x, r 12y, r 12z ] [v 12x, v 12y, v 12z ] = r 12x v 12 x+ r 12y v 12y + r 12z v 12z = |r 12 ||v 12 |cos  Note: in Matlab b = dot(r,v) where r,v are vectors. Also, r 12r 12 = r 12 2, v 1v 1 = v 1 2 Kinetic energy is m i (v iv i )/2 Relative position at any time until collision: r ij = r ij o + v ij o (t - t o ) Collision occurs when r 12r 12 =  2 s = -1 if discriminant < 0, miss rjorjo rjtrjt rjt+rjt+ riorio

17 17 Collision Mechanics r 12 c  y v2’v2’ x v 12 v1’v1’ 1 1 2   v1’v1’ v2’v2’ Momentum conserved Kinetic energy conserved Must evaluate r ij c and b c = r ij cv ij at collision Collision force acts in direction vector between point of contact and center of site, r 12 c /  for 1 and - r 12 c /  for 2.

18 18 Event Tracking Start particles with desired E KE Calculate next collision. Move all particles to time of next collision. Calculate new velocities for particles that collide. Loop.

19 19 DMD and square well (a)(a) (b)(b) (c)(c)(d)(d) Will accelerate when fall into well. Will bounce on cores. Approaching, but cores will miss. Will decelerate if escape well, or will bounce inside well. Departing. Will decelerate if escape well, or will bounce inside well. 10 different types of events (this is a subset)

20 20 Time and velocity changes d ij = distance of event s = +1 or -1 depending on event where b c = r ij cv ij b = r ijv ij s = +1 or -1 depending on event

21 21 Bonded Sites bond pseudobond (1) Sites can not escape from wells. (2) Bond distances < site diameters.

22 Flow sheet 22

23 23 Applications of DMD Protein Fibril formation (Hall) Square-well attractive forces promote helix fibril formation. Vapor Pressure prediction (Elliott) DMD provides the reference state from which a perturbation is applied.

Download ppt "1 Molecular Simulations Macroscopic EOS (vdW, PR) Little molecular detail Empirical parameters (  ) Seeking understanding of complex systems Surfactants."

Similar presentations

Time averages and ensemble averages

Time averages and ensemble averages
How to setup the initial conditions for a Molecular Dynamic Simulation

How to setup the initial conditions for a Molecular Dynamic Simulation
Lecture 13: Conformational Sampling: MC and MD Dr. Ronald M. Levy Contributions from Mike Andrec and Daniel Weinstock Statistical Thermodynamics.

Lecture 13: Conformational Sampling: MC and MD Dr. Ronald M. Levy Contributions from Mike Andrec and Daniel Weinstock Statistical Thermodynamics.
Measuring Fluid Velocity and Temperature in DSMC Alejandro L. Garcia Lawrence Berkeley National Lab. & San Jose State University Collaborators: J. Bell,

Measuring Fluid Velocity and Temperature in DSMC Alejandro L. Garcia Lawrence Berkeley National Lab. & San Jose State University Collaborators: J. Bell,
Lecture 4 – Kinetic Theory of Ideal Gases

Lecture 4 – Kinetic Theory of Ideal Gases
Statistical Models of Solvation Eva Zurek Chemistry 699.08 Final Presentation.

Statistical Models of Solvation Eva Zurek Chemistry Final Presentation.
Problem Solving For Conservation of Momentum problems: 1.BEFORE and AFTER 2.Do X and Y Separately.

Problem Solving For Conservation of Momentum problems: 1.BEFORE and AFTER 2.Do X and Y Separately.
Physics 430: Lecture 10 Energy of Interaction Dale E. Gary NJIT Physics Department.

Physics 430: Lecture 10 Energy of Interaction Dale E. Gary NJIT Physics Department.
Particle-based fluid simulation for interactive applications

Particle-based fluid simulation for interactive applications
Physics 52 - Heat and Optics Dr. Joseph F. Becker Physics Department San Jose State University © 2005 J. F. Becker.

Physics 52 - Heat and Optics Dr. Joseph F. Becker Physics Department San Jose State University © 2005 J. F. Becker.
Fig. 16-12 A diatomic molecule. Almost all the mass of each atom is in its tiny nucleus. (a) The center of mass has 3 independent velocity components.

Fig A diatomic molecule. Almost all the mass of each atom is in its tiny nucleus. (a) The center of mass has 3 independent velocity components.
Department of Physics and Applied Physics 95.141, F2010, Lecture 20 Physics I 95.141 LECTURE 20 11/21/10.

Department of Physics and Applied Physics , F2010, Lecture 20 Physics I LECTURE 20 11/21/10.
Molecular Kinesis CM2004 States of Matter: Gases.

Molecular Kinesis CM2004 States of Matter: Gases.
4. Modeling 3D-periodic systems Cut-off radii, charges groups Ewald summation Growth units, bonds, attachment energy Predicting crystal structures.

4. Modeling 3D-periodic systems Cut-off radii, charges groups Ewald summation Growth units, bonds, attachment energy Predicting crystal structures.
1 CE 530 Molecular Simulation Lecture 2 David A. Kofke Department of Chemical Engineering SUNY Buffalo

1 CE 530 Molecular Simulation Lecture 2 David A. Kofke Department of Chemical Engineering SUNY Buffalo
Joo Chul Yoon with Prof. Scott T. Dunham Electrical Engineering University of Washington Molecular Dynamics Simulations.

Joo Chul Yoon with Prof. Scott T. Dunham Electrical Engineering University of Washington Molecular Dynamics Simulations.
Linear Momentum and Collisions

Linear Momentum and Collisions
Bioinf. Data Analysis & Tools Molecular Simulations & Sampling Techniques117 Jan 2006 Bioinformatics Data Analysis & Tools Molecular simulations & sampling.

Bioinf. Data Analysis & Tools Molecular Simulations & Sampling Techniques117 Jan 2006 Bioinformatics Data Analysis & Tools Molecular simulations & sampling.
ChE 551 Lecture 19 Transition State Theory Revisited 1.

ChE 551 Lecture 19 Transition State Theory Revisited 1.
Heat Engines Coal fired steam engines. Petrol engines Diesel engines Jet engines Power station turbines.

Heat Engines Coal fired steam engines. Petrol engines Diesel engines Jet engines Power station turbines.

Similar presentations

Ads by Google