Energy-Driven Pattern Formation: Phase Separation in Diblock Copolymer Melts

1. Energy-Driven Pattern Formation: Phase Separation in DiblockCopolymerMelts David Bourne Joint work with Mark Peletier CASA Day, 11 April 2012

2. DiblockCopolymer Melts

3. DiblockCopolymer Melts Figure from Choksi, Peletier & Williams (2009)

4. Microphase Separation Figure from MIT OCW

5. Microphase Separation Figure from the Wiesner Group website, Cornell University

6. Previous work • CASA: • Mark Peletier • Marco Veneroni • Yves van Gennip • Matthias Röger Others: Alberti, Cicalese, Choksi, Niethammer, Otto, Spadaro, Williams, …..

7. Model B A A A

8. Model B A A A Small volume fraction case: LARGE

9. Model B A A A Small volume fraction limit:

10. Model: Energy

11. Model: Energy B A A A

12. Model: Energy B A A A

13. Model: Energy

14. Model: Energy B A A A

15. Zero volume fraction limit • Complicated, nonlocal energy

16. Zero volume fraction limit • Complicated, nonlocalenergy • Weareinterested in thecaselarge, i.e., wherethevolumefractionofissmall

17. Zero volume fraction limit • Complicated, nonlocalenergy • Weareinterested in thecaselarge, i.e., wherethevolumefractionofissmall • So wesimplifytheenergybytaking

18. - Convergence Minimisers:

19. - Limit Theorem: The -limit ofthefunctionalsis where

20. Ingredients of the Proof • 2nd Concentrated Compactness Lemma of P.-L. Lions • IsoperimetricInequality • Metrizationoftheweakconvergenceofmeasuresbythe Wasserstein metric

21. Study of the Limit Energy • Limit ourattentionto, squaredomain

22. Study of the Limit Energy • Limit ourattentionto, squaredomain • After rescaling so that is the unit square we get • where

23. Study of the Limit Energy • Limit ourattentionto, squaredomain • After rescaling so that is the unit square we get • where • The parameter determinesfor the minimiserand the minimisingpattern

25. When • For , “”

26. When • For , “” • Forfixedfinite , theminimisingpatternis a • centroidalVoronoitessellation

27. When • For , “” • Forfixedfinite , theminimisingpatternis a • centroidalVoronoitessellation • i.e., thepointsareatthecentresofmassoftheVoronoicellsthattheygenerate, andtheweightsaretheareasoftheVoronoicells, where

28. Centroidal Voronoi Tessellations

29. When is in between: Numerical optimisation

30. When is in between: Numerical optimisation • To evaluate have tosolvean-dimensionallinearprogrammingproblem

31. When is in between: Numerical optimisation • To evaluate have tosolvean-dimensionallinearprogrammingproblem • Discretiseusing Gauss quadrature points andweightstoevaluateto at least 6 d.p.

32. When is in between: Numerical optimisation • To evaluate have tosolvean-dimensionallinearprogrammingproblem • Discretiseusing Gauss quadrature points andweightstoevaluateto at least 6 d.p. • Minimise in MATLAB usingfminconforfixed, thenfindoptimalM

33. When is in between: Numerical optimisation • To evaluate have tosolvean-dimensionallinearprogrammingproblem • Discretiseusing Gauss quadrature points andweightstoevaluateto at least 6 d.p. • Minimise in MATLAB usingfminconforfixed, thenfindoptimalM • Good news: CVT is a verygoodinitialguess. Easy tocomputeusingLloyd’salgorithm

34. When is in between: Numerical optimisation • To evaluate have tosolvean-dimensionallinearprogrammingproblem • Discretiseusing Gauss quadrature points andweightstoevaluateto at least 6 d.p. • Minimise in MATLAB usingfminconforfixed, thenfindoptimalM • Good news: CVT is a verygoodinitialguess. Easy tocomputeusingLloyd’salgorithm • Bad news: CVT is a verygoodinitialguess. Needtoworkto high accuracytoseethat the minimiserisn’t a CVT

35. Numerical Results

36. Numerical Results

37. Numerical Results

38. Future Directions • Comparisonwithexperiments

39. Future Directions • Comparisonwithexperiments • Numericalexploration of the bifurcation diagram

40. Future Directions • Comparisonwithexperiments • Numericalexploration of the bifurcation diagram • Whatcan we prove about the limit pattern?