1 / 20

Development of quantitative coarse-grained simulation models for polymers

Development of quantitative coarse-grained simulation models for polymers. Shekhar Garde & Sanat Kumar Rensselaer Polytechnic Institute grant number #0313101. Graduate students: Harshit Patel & Sandeep Jain Collaborator: Hank Ashbaugh, LANL/Tulane

anastacia-manella
Download Presentation

Development of quantitative coarse-grained simulation models for polymers

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Development of quantitative coarse-grained simulation models for polymers Shekhar Garde & Sanat Kumar Rensselaer Polytechnic Institute grant number #0313101 Graduate students: Harshit Patel & Sandeep Jain Collaborator: Hank Ashbaugh, LANL/Tulane Education/Outreach: New Visions, MoleculariumTM

  2. Motivation atactic -polypropylene polyethylene lamellar hexagonal bicontinuous Applications • Polymer blend phase behavior - Miscibility/immisciblity of polyolefins • Self-assembly of block copolymers to form novel micro-structured materials

  3. Hierarchy of Length and Time Scales molecular scale polymer coil polymer melt/continuum > 100 Å O(1sec) persistance length ~10Å ~ 100 Å 10-8 to 10 -4 sec bond length ~1Å 10 -15 to 10-12 sec

  4. Coarse-graining Examples: Lattice models or bead-spring chains, dissipative particle dynamics methods Basic idea: Integrate over (unimportant) degrees of freedom How do we coarse-grain atomically detailed systems without a significant loss of chemical information? Do coarse-grained systems provide correct description of structure, thermodynamics, and dynamics of a given atomic system?

  5. Coarse-graining of Polymer Simulations Goal: To develop coarse-grained descriptions to access longer length and timescales How do we derive physically consistent particle-particle interaction potentials? Coarse-grained description (t) Coarse-grained description (t + dt) Future work One CG particle describes n carbons of the detailed polymer Basic idea Atomistic system ( t ) Atomistic system ( t + dt )

  6. Coarse-graining method • Perform molecularly detailed simulations of polymers • Define coarse-grained beads by grouping backbone monomers • Calculate structural correlations between coarse-grained beads • Determine effective bead-bead interactions that reproduce coarse-grained correlations using Inverse Monte Carlo -- uniqueness?

  7. Detailed molecular dynamics simulations • Classical molecular dynamics • n-alkanes - C16 to C96 (M. Mondello et al. JCP 1998) • 50 to 100 chains • T = 403K P = 1 atm • time = 5 to 10 ns

  8. Coarse-graining intermolecular correlations 8mer-bead 1mer-bead 16mer-bead structural details are lost with increasing the level (n) of coarse-graining process

  9. Coarse Graining Intramolecular Correlations 13-intra 12-intra 14-intra

  10. Inverse Monte Carlo simulation choose a trial potential, e.g., j(r) = 0 update trial potential jnew(r) = jold(r) +fln[g(r)/gtarget(r)] run Monte Carlo simulation with trial potential done g(r) = gtarget(r) ? No Yes

  11. Coarse Grained Potential inter-bead interaction intra-bead interaction Etotal = Einter + Eintra = Spairsjinter(r) + S12pairsj12intra(r) + S13pairsj13intra(r) + S14pairsj14intra(r) + ...

  12. Inter-bead Interactions before IMC after IMC inter-bead radial distribution function effective interaction potential

  13. Intra-bead Interactions 14-intra-bead interactions 13-intra-bead interactions 12-intra-bead “bonded” interactions j14(r) j13(r) j12(r) potential (kT) r (Å) r (Å) r (Å)

  14. Oligomer conformation distribution radius of gyration distribution for C96 P(Rg) Rg(Å) CG method reproduces conformational statistics of molecular oligomers

  15. Radius of Gyration and Effect of Temperature T KEPIC Kexpt 403K 0.45 0.45 2Rg 2Rg 503K 0.40 0.42 CG excellent agreement with experiment

  16. Polymer Conformation Distribution radius of gyration distribution (403K) C96 C1000 C8000 ideal P(Rg*) Rg* = Rg / < Rg2 >1/2 polymer conformational space efficiently explored

  17. Buckyball Polymer Nanocomposites bead-ball distribution bead-ball interaction g(r) j (kT) r (Å) r (Å)

  18. Conclusions • CG method maps molecular scale correlations to coarse-grained potentials • Coarse grained potential simpler than molecular potential and can be extended to polymer simulations while preserving molecular identity • Not limited to polymeric species (e.g., buckyballs/ nanocomposites) • Path Forward - Polyolefin blends - Block copolymer assembly - Dynamics?

  19. Water molecule Hydra: H atom Biological world Mr. Carbone

  20. Thank you!

More Related