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Lecture 1. How to model: physical grounds

Lecture 1. How to model: physical grounds. Outline Physical grounds: parameters and basic laws Physical grounds: rheology. Physical grounds: displacement, strain and stress tensors. ξ i= ξ i (x1,x2,x3,t) i=1,2,3. Strain. x3. t´. t. r´. ξ 1, ξ 2, ξ 3. r. x1,x2,x3. x2. x1.

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Lecture 1. How to model: physical grounds

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  1. Lecture 1. How to model: physical grounds Outline • Physical grounds: parameters and basic laws • Physical grounds: rheology

  2. Physical grounds: displacement, strain and stress tensors

  3. ξi= ξi (x1,x2,x3,t) i=1,2,3 Strain x3 t´ t r´ ξ1,ξ2,ξ3 r x1,x2,x3 x2 x1

  4. Lagrangian ξi= ξi (x1,x2,x3,t) i=1,2,3 Strain x3 t´ t r´ ξ1,ξ2,ξ3 r x1,x2,x3 x2 x1

  5. Lagrangian ξi= ξi (x1,x2,x3,t) i=1,2,3 Strain x3 t´ xi=xi (ξ1,ξ2,ξ3,t) i=1,2,3 t r´ ξ1,ξ2,ξ3 r x1,x2,x3 x2 x1

  6. Lagrangian ξi= ξi (x1,x2,x3,t) i=1,2,3 Strain x3 t´ u xi=xi (ξ1,ξ2,ξ3,t) i=1,2,3 t r´ ξ1,ξ2,ξ3 r x1,x2,x3 x2 x1 u=r´-r -displacement vector

  7. Lagrangian ξi= ξi (x1,x2,x3,t) i=1,2,3 Strain x3 t´ u xi=xi (ξ1,ξ2,ξ3,t) i=1,2,3 t r´ ξ1,ξ2,ξ3 r x1,x2,x3 ui= ξi -xi=ui (x1,x2,x3,t) i=1,2,3 x2 x1 u=r´-r -displacement vector

  8. Lagrangian ξi= ξi (x1,x2,x3,t) i=1,2,3 Strain x3 t´ u xi=xi (ξ1,ξ2,ξ3,t) i=1,2,3 t r´ ξ1,ξ2,ξ3 r x1,x2,x3 Eulerian ui= ξi -xi=ui (x1,x2,x3,t) i=1,2,3 x2 ui= ξi -xi=ui (ξ1,ξ2,ξ3,t) i=1,2,3 x1 u=r´-r -displacement vector

  9. Strain tensor 1 3 2

  10. Strain tensor 1 2 3

  11. Strain tensor

  12. Strain and strain rate tensors

  13. Geometric meaning of strain tensor Changing length Changing angle Changing volume

  14. Stress tensor is the icomponent of the force acting at the unit surface which is orthogonal to direction j

  15. Tensor invariants, deviators Stress deviator P is pressure Stress norm

  16. Principal stress axes

  17. Physical grounds: conservation laws

  18. Mass conservation equation Material flux Substantive time derivative

  19. Mass conservation equation

  20. Momentum conservation equation Substantive time derivative

  21. Energy conservation equation Shear heating Heat flux Substantive time derivative

  22. Physical grounds: constitutive laws

  23. Rheology – the relationship between stress and strain • Rheology for ideal bodies • Elastic • Viscous • Plastic

  24. An isotropic, homogeneous elastic material follows Hooke's Law Hooke's Law: s = Ee

  25. For an ideal Newtonian fluid:differential stress = viscosity x strain rateviscosity: measure of resistance to flow

  26. Ideal plastic behavior

  27. Constitutive laws Elastic strain rate Viscous flow strain rate Plastic flow strain rate

  28. Superposition of constitutive laws ;

  29. Full set of equations mass momentum energy

  30. How Does Rock Flow? • Brittle – Low T, low P • Ductile – as P, T increase

  31. Modes of deformation Brittle Brittle-ductile Ductile

  32. Deformation Mechanisms • Brittle • Cataclasis • Frictional grain-boundary sliding • Ductile • Diffusion creep • Power-law creep • Peierls creep

  33. Cataclasis • Fine-scale fracturing and movement along fractures. • Favoured by low-confining pressures

  34. Frictional grain-boundary sliding • Involves the sliding of grains past each other - enhanced by films on the grain boundaries.

  35. Diffusion Creep • Involves the transport of material from one site to another within a rock body • The material transfer may be intracrystalline, intercrystalline, or both. • Newtionian rheology:

  36. Dislocation Creep • Involves processes internal to grains and crystals of rocks. • In any crystalline lattice there are always single atoms (i.e. point defects) or rows of atoms (i.e. line defects or dislocations) missing. These defects can migrate or diffuse within the crystalline lattice. • Motion of these defects that allows a crystalline lattice to strain or change shape without brittle fracture. • Power-law rheology :

  37. Peierls Creep For high differential stresses (about 0.002 times Young’s modulus as a threshold), mixed dislocation glide and climb occurs. This mechanism has a finite yield stress (Peierls stress, ) at absolute zero temperature conditions.

  38. Three creep processes Diffusion creep Peierls Dislocation creep Dislocation Peierls creep Diffusion ( Kameyama et al. 1999)

  39. Full set of equations mass momentum energy

  40. Final effective viscosity

  41. Plastic strain if Drucker-Prager yield criterion if Von Mises yield criterion if softening

  42. Final effective viscosity if if

  43. Strength envelope Strength Strength 0 50 100 0 50 100 water crust Moho Crust Moho Depth (km) Mantle Mantle

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