Rheology and wave propagation by J. M. Carcione (OGS)

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Presentation transcript:

Rheology and wave propagation by J. M. Carcione (OGS)

Page: 2

Page: 3

Page: 4 Poro-elasticity

Page: 5 Strain energy - Stress-strain relation

Page: 6 Jacketed test

Page: 7 Unjacketed test

Page: 8 Elastic moduli

Page: 9 Gassmann modulus

Page: 10 Gassmann modulus- variation of fluid content

Page: 11 Gassmann modulus - Examples

Page: 12 Gassmann modulus - Examples

Page: 13 Gassmann modulus - Examples

Page: 14 Gassmann modulus - Fluid substitution

Page: 15 Visco-elasticity

Page: 16 Burgers model

Page: 17 Burgers model - stress-strain relation

Page: 18 Burgers model - Creep function

Page: 19 Mechanical models Maxwell Kelvin-Voigt Zener

Page: 20 Zener model - Creep function

Page: 21 Zener model - Relaxation function

Page: 22 Zener model - velocity and attenuation

Page: 23 Maxwell model - creep and relaxation

Page: 24 Memory variable

Page: 25 Viscoelastic equations

Page: 26 Anisotropy

Page: 27 Stress-strain relation

Page: 28 Triclinic media (21)

Page: 29 Transversely-isotropic media (5)

Page: 30 Orthorhombic media (9)

Page: 31 Monoclinic media (12)

Page: 32 Anisotropy - eigenstrains - attenuation

Page: 33 Anisotropy - Kelvin-Christoffel matrix

Page: 34 Anisotropy - Slowness-Wavefronts

Page: 35 Anisotropy and attenuation

Page: 36 Relevant references

Page: 37