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Geology 5660/6660 Applied Geophysics 5 Feb 2016

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1 Geology 5660/6660 Applied Geophysics 5 Feb 2016
Last time: Refraction Plus-Minus; Reflection: • Plus-Minus Method for arbitrarily changing h:  where m– is slope of a plot of t1i–t2i vs xi for SP1, 2 and geophones i • Seismic Reflection Travel-Times have eqns of a hyperbola. For single layer over halfspace, has intercept 2h1/V1 and slope of the asymptote is 1/V1! • Defined Normal Move-Out (NMO) as the reflection travel-times at distance x minus t at x = 0: For Mon 08 Feb: Burger (§ ) © A.R. Lowry 2016

2 Distance water shale gas sand shale Two-Way Travel Time

3 Shifting the seismic reflection amplitude to where it would be
(in two-way travel-time) for zero-offset produces an image… Note that this approach is VERY different from the model of velocity structure we generate from the refraction method!

4 Reflection from a second layer interface over half-space:
x/2 V1 h1 V2 h2 Can derive using Snell’s law but easier to consider that: For x = 0,  intercept of hyperbola For x  , asymptotic to the layer 2 refraction

5 Equation for the hyperbola then is
After some algebra we have And you might see where this could start to get complicated for 3, 4, … layers This is part of why industry seismic reflection processing historically did not go after full seismic velocity analysis but instead took shortcuts to imaging of structures…

6 A Dipping Reflector: V1 h1 Geometrically, this is equivalent to rotating the axis of the reflector by the dip angle . This rotates the hyperbola on the travel-time curve by  = tan-1(–2h1sin) and has equation

7 Example: V1 = 1500, h = 45 m,  = 8° Helpful Hint: Reflect does not model dipping layers, but the Table 4-6 Excel spreadsheet does!

8 Getting velocity structure: The x2 – t2 method
If we have travel-times from a reflection, can plot t2 vs x2 to get parameters of thickness & velocity from slope and intercept of the resulting line fit! Recall that the goal of geophysics is to invert for parameters (in this case, velocity and thickness) Given travel-times from a reflection, can plot t2 vs x2 to get parameters of thickness & velocity from slope and intercept of the resulting line fit. For the single layer case:

9 So for slope m, intercept t02 of a line fit:
x2

10 Note x2 – t2 method is also useful for dipping layers!
q down-dip limb mean slope t t2 up-dip limb x x2

11 Note this is the approach taken to
inverting data in Reflect!

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