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What’s seismology about?

What’s seismology about?. Seismology is the study of the generation, propagation and recording of elastic waves in the Earth (and other celestial bodies) and of the sources that produce them. Elastic Moduli. Young’s Modulus Poisson Ratio Bulk Modulus Shear Modulus Lamb’s constants Vp, Vs.

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What’s seismology about?

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  1. What’s seismology about? • Seismology is the study of the generation, propagation and recording of elastic waves in the Earth (and other celestial bodies) and of the sources that produce them.

  2. Elastic Moduli • Young’s Modulus • Poisson Ratio • Bulk Modulus • Shear Modulus • Lamb’s constants • Vp, Vs.

  3. Young’s modulus s = tensile stress = (F /A) e = tensional strain = (DL /L) … for uniaxial tension or compression s e E =

  4. Young’s modulus s = tensile stress = (F /A) e = tensional strain = (DL /L) … for uniaxial tension or compression s e E =

  5. Under a stress (sxx) along the x-axis, longitudinal strain = exx = and transverse strain = eyy = DL L DW W Then, Poisson’s ratio = - (eyy / exx)

  6. Bulk Modulus = (DP/Q) … where Q = dilatation = DV/V and P = pressure

  7. A L shear modulus shear stress = (DF /A) shear strain = (Dl /L) shear stress shear strain m =

  8. Elastic Moduli and Densities of Some Common Materials From Lay & Wallace (1995)

  9. From Lay & Wallace (1995)

  10. 2mn E l = k - = 3( 1 + n ) ( 1 - 2n ) K + ( )ml + 2m 4/3 V = a = = p r r m r V = b = s Where m,l are the Lamé coefficients and l is

  11. Body Waves compressions P-wave dilatations S-wave amplitude wavelength

  12. Body wave Amp ~ 1/x Surface wave Amp ~ x-1/2

  13. Late homework policy • Late homework will not be accepted one week after the deadline. • Late homework will be penalized: 90% (1 day late), 80% (2 day late), 60% (3 day late), 40 % (4 day late) and 20% (5-7 day late).

  14. Body Waves compressions P-wave dilatations S-wave amplitude wavelength

  15. Seismic Rays & Geometric Ray Theory • Rays are defined as the normal to the wave fronts and thus point in the direction of propagation. Connecting the these successive directions forms a ray paths. In the case of plane wave, rays are a family of straight lines; in the case of spherical wave, rays are spokes radiating out from the seismic source. They provide a convenient means of tracking an expanding wave front. • The seismic rays corresponding to P and S waves behave very much as light does in traveling through materials of varying indices of refraction. This leads to many parallels with optics: rays bend, focus, and defocus depending on the velocity distribution. Although geometric ray theory is an approximation, it, however, simplifies the analysis and yet gives the correct answer or a good approximation.

  16. Fermat’s Principle • Ray paths between two points are those for which travel time is an extremum, either a minimum or maximum, with respect to the nearby possible paths.

  17. Snell’s Law Snell’s Law and Fermat Principle Fermat Principle: T(x) is either minimum or maximum

  18. Reynolds (1997)

  19. Spherical Ray Parameter R sini = constant = p V

  20. What control reflection and transmission? • Continuity of stress • Continuity of displacement

  21. I = 1 I = 2 Reynolds (1997)

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