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outstanding problems in the physics of deformation of polymers

outstanding problems in the physics of deformation of polymers. Han E.H. Meijer and Leon E. Govaert. Dutch Polymer Institute (DPI) Materials Technology (MaTe) Eindhoven University of Technology (TU/e) APST ONE, Advances in Polymer Science and Technology

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outstanding problems in the physics of deformation of polymers

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  1. outstanding problems in the physics of deformation of polymers Han E.H. Meijer and Leon E. Govaert Dutch Polymer Institute (DPI) Materials Technology (MaTe) Eindhoven University of Technology (TU/e) APST ONE, Advances in Polymer Science and Technology July 8 – July 10, 2009, Johannes Kepler University Linz, Austria

  2. introduction • predicting performance of present models • outstanding problems: • first question: origin of deformation kinetics • second question: origin of ageing kinetics • third question: origin of strain hardening • summary

  3. localization of strain tough brittle • PC: necking • moderate localization • stable growth • PS: crazing • extreme localization • unstable growth

  4. a comment on (solid state) rheology rheology: branch of fluid mechanics call themselves non-Newtonian but are Newton’s successors that are mathematically well educated and only deal with transient homogeneous shear flows it took them 50 years to arrive at a constitutive equation that is also valid in transient homogeneous extensional flows solid state rheology: branch of solid mechanics Hooke’s successors that necessarily have to deal only with transient inhomogeneous extensional flows

  5. rejuvenation polystyrene PS

  6. ageing mechanically rejuvenated moderate ageing severe ageing unstable localisation homogeneous deformation stable localisation brittle ductile ductile

  7. ageing

  8. from compression to tension compression entanglement network intermolecular total ageing = + Mn

  9. from compression to tension compression entanglement network intermolecular total ageing = + Mn tension increasing entanglement density

  10. introduction • predicting performance of present models • outstanding problems: • first question: origin of deformation kinetics • second question: origin of ageing kinetics • third question: origin of strain hardening • summary

  11. from compression to tension compression

  12. from compression to tension compression tension

  13. from compression to tension compression fit tension prediction

  14. indentation and scratching mesh

  15. indentation and scratching indentor type round a c a Berkovich b b flat punch c

  16. indentation and scratching flat-ended cone angle: 60o diameter: 10.0 µm post-mortem visco-elastic visco-plastic

  17. indentation and scratching line: experiment symbol: prediction flat-ended cone angle: 60o diameter: 10.0 µm post-mortem visco-elastic visco-plastic

  18. indentation and scratching results are quantitative lines: experiments symbols: predictions ageing deformation rate ageing kinetics deformation kinetics

  19. indentation and scratching strategy hybrid experimental/numerical method Fn v Ff polymer Ff experiments Fadh= Ff- Fdef ? simulations Fdef T,v,scale effects

  20. indentation and scratching results: experimental: influence sliding velocity

  21. indentation and scratching results: numerical: deformation only Fn=300mN v =0.1µm/s r =50 µm visco-elastic visco-plastic

  22. indentation and scratching results: experimental versus numerical deformation only Fadh Fdef Ff = Fdef + Fadh

  23. indentation and scratching results: numerical: influence interaction between indenter and polymer what about adhesion? most basic dry-friction model: Leonardo da Vinci (1452) Amonton (1699) - Coulomb (1781) stick: slip :

  24. indentation and scratching results: numerical: influence interaction between indenter and polymer

  25. indentation and scratching results: numerical: influence interaction between indenter and polymer Fn vx Ff A2 polymer Fsim A1 Ff = Fsim = Fdef Fadh = 0

  26. indentation and scratching results: numerical: influence interaction between indenter and polymer Fn vx Ff A2 polymer Fsim A1 Ff = Fsim = Fdef + Fadh Fadh Fdef

  27. indentation and scratching results: numerical: influence interaction between indenter and polymer Fn vx Ff A2 polymer Fsim A1 Ff = Fsim = Fdef + Fadh Fadh Fdef

  28. indentation and scratching results: numerical: influence interaction between indenter and polymer

  29. indentation and scratching results: experimental versus numerical validation using different tip Fn=150mN v =0.1µm/s r =10µm visco-elastic visco-plastic

  30. indentation and scratching results: experimental versus numerical validation using different tip

  31. indentation and scratching results: experimental versus numerical wear

  32. introduction • predicting performance of present models • outstanding problems: • first question: origin of deformation kinetics • second question: origin of ageing kinetics • third question: origin of strain hardening • summary

  33. introduction • predicting performance of present models • outstanding problems: • first question: origin of deformation kinetics • second question: origin of ageing kinetics • third question: origin of strain hardening • summary

  34. deformation kinetics rate dependence of PC

  35. deformation kinetics rate dependence of PC

  36. constant stress .  deformation kinetics constant strain rate response rate-dependent yield failure under constant strain rate and constant stress experiment governed by same kinetics

  37. deformation kinetics time-dependent accumulation of plastic strain: plastic flow

  38. deformation kinetics influence of thermal history on intrinsic behavior influence of thermal history on rate dependence

  39. deformation kinetics and time to failure PC influence of thermal history on intrinsic behavior influence of thermal history on time-to-failure

  40. deformation kinetics and time to failure strain rate dependence of yield stress stress dependence of time-to-failure

  41. deformation kinetics and time to failure question 1: how does molecular architecture determine deformation kinetics

  42. deformation kinetics and time to failure question 1: how does molecular architecture determine deformation kinetics and thus the long term behaviour asreflected in the time-to-failure

  43. introduction • predicting performance of present models • outstanding problems: • first question: origin of deformation kinetics • second question: origin of ageing kinetics • third question: origin of strain hardening • summary

  44. ageing and ageing kinetics ageing ageing influence of thermal history on intrinsic behaviour influence of thermal history on rate dependence

  45. ageing and ageing kinetics PS PS: brittle fracture within hours PC: necking returns within months

  46. ageing and ageing kinetics ageing accelerated by temperature Arrhenius temperature dependence; ΔH 205 kJ/mol

  47. ageing and ageing kinetics ageing accelerated by stress

  48. ageing and ageing kinetics rate dependence of yield stress aged loading curve changes in thermal history captured by a single state parameter: Sa behaviour independent of molecular weight distribution

  49. ageing and ageing kinetics yield stress increases with time

  50. ageing kinetics: two domains temperature history received during processing temperature history received during product life • ~seconds • high temperatures • fast evolution • ~years • low temperatures • slow evolution evolution of yield stress in both domains governed by the same kinetics

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