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Gravity 3.

Published byDarlene Caldwell Modified over 6 years ago

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Presentation on theme: "Gravity 3."— Presentation transcript:

1 Gravity 3

2 Gravity Corrections/Anomalies
Gravity survey flow chart: 1. Measurements of the gravity (absolute or relative)  2. Calculation of the theoretical gravity (reference formula)  3. Gravity corrections 4. Gravity anomalies 5. Interpretation of the results

3 Theoretical Gravity Gravity is a function of:
Latitute of observation () Elevation of the station (R – the difference for R) Mass distribution in the subsurface (M)

4 Theoretical Gravity For a Reference Oblate Spheroid:
– latitude of observation (sometime you can see  instead of )

5 Free Air Gravity Anomaly/Correction
Accounts for the elevation For g  980,625 MGal, and R  6,367 km = 6,367,000 m Average value for the change in gravity with elevation

6 Free Air Gravity Anomaly/Correction
FAC – Free Air Correction (mGal); h – elevation above sea level (m) gfa = g – gt + FAC

7 Free Air Gravity Anomaly/Correction
Example of free air gravity anomaly across areas of mass excess and mass deficiency

8 Bouguer Gravity Anomaly/Correction
Accounts for the gravitational attraction of the mass above sea level datum Attraction of a infinite slab with thickness h = elevation of the station: BC = 2Gh BC = h BC – Bouguer Correction (mGal); h – elevation above sea level (m)  - density (g/cm3)

9 Bouguer Gravity Anomaly/Correction
For land gB = gfa – BC in BC must be assumed (reduction density) For a typical  = 2.67 g/cm3 (density of granite): BC = x 2.67 x h = = (0.112 mGal/m) x h gB = gfa – (0.112 mGal/m) x h

10 Bouguer Gravity Anomaly/Correction
For sea For a typical w = 1.03 g/cm3 (water) and c = 2.67 g/cm3 (crust): BCs = x (w - c) x hw = x (-1.64) x hw = (mGal/m) x hw gB = gfa – BCs gB = gfa – h h = 0  gB = gfa gB = gfa + ( mGal/m) x hw

11 Bouguer Gravity Anomaly/Correction
FAC vs. BC: BC < FAC (always for stations above sea level) Mass excesses result in “+” anomalies, and deficiencies in “-” anomalies for both Short-wavelength changes in FAC due to abrupt topographic changes are removed by BC.

12 Terrain Correction For rugged areas – additional correction
For low relief the BC is okay but for rugged terrain it is not gBc = gB + TC

13 Free Air and Bouguer Gravity Anomalies (summary)
3. Bouguer Gravity Anomaly gB = gfa – BC = gfa – h On land: gB = gfa – (0.112 mGal/m) h for  = +2.67 At sea: gB = gfa + ( mGal/m) h for  = In rugged terrain: gBc = gB + TC Theoretical Gravity Free Air Gravity Anomaly gfa = g – gt + (0.308 mGal/m) h Bs – Bouguer – simple; Bc – Bouguer – complete

14 Free Air and Bouguer Gravity Anomalies (summary)
3. Bouguer Gravity Anomaly gB = gfa – BC = gfa – h On land: gB = gfa – (0.112 mGal/m) h for  = +2.67 At sea: gB = gfa + ( mGal/m) h for  = In rugged terrain: gBc = gB + TC Theoretical Gravity Free Air Gravity Anomaly gfa = g – gt + (0.308 mGal/m) h Bs – Bouguer – simple; Bc – Bouguer – complete

15 Gravity Corrections/Anomalies
1. Measurements of the gravity (absolute or relative)  2. Calculation of the theoretical gravity (reference formula)  3. Gravity corrections  4. Gravity anomalies 5. Interpretation of the results

16 Gravity modelling - 2-D approach
Developed by Talwani et al. (1959): Gravity anomaly can be computed as a sum of contribution of individual bodies, each with given density and volume. The 2-D bodies are approximated , in cross-section as polygons.

17 Gravity anomaly of sphere
Analogy with the gravitational attraction of the Earth: g  g (change in gravity) M  m (change in mass relative to the surrounding material) R  r

18 Gravity anomaly of sphere
Total attraction at the observation point due to m

19 Gravity anomaly of sphere
- Total attraction (vector) Horizontal component of the total attraction (vector) Vertical component of the total attraction (vector) Horizontal component Vertical component Angle between a vertical component and g direction

20 Gravity anomaly of sphere
a gravimeter measures only this component R – radius of a sphere  - difference in density

21 Gravity anomaly of sphere

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