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2. . Earth's architectural featuresFolds, Faults, Fractures, Joints, etc.Structural GeologyStudy of these features. 3. Why is it important?. . Oil / Gas DepositsPrecious
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3. 3 Oil / Gas Deposits
Precious & Other Metal Deposits
Hazards Analysis
Earthquakes, Dams, Nuclear Plants, etc.
4. 4 Change in a rock mass
Size
Shape
Orientation or
Position
5. 5 Anywhere tectonic forces act upon formations
e.g., Plate margins
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7. 7 Stress
Confining Pressure (stress uniform in all directions)
Differential Stress (nonuniform stress)
Compressional Stress
Tensional Stress
Shear Stress
8. 8 Undeformed rocks
9. 9 Horizontal compression
10. 10 Horizontal tension
11. 11 Shearing
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13. 13 Deformation caused by stress
- a strained body does not retain it’s original shape during/after deformation
14. 14 Deformation depends on
Temperature & Confining Pressure
Brittle & Ductile deformation
Brittle – the material breaks
Ductile – solid-state flow; change in size and shape without breakage
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16. 16 -Rock Type
Rock Salt, Gypsum, Shale – flow ductilely
Limestone, marble, schist - intermediate
Granite, basalt – strong and brittle
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18. 18 Mapping Geological Structures Formations
Strike and dip
Folds
Faults
19. 19 Formations Mappable rock unit
Has definite upper & lower contacts (boundaries with other units)
Obvious characteristics (i.e., rock type) which allows it to be traced from place to place
Is different from other rock units
Generally sedimentary rocks
Named for nearby location/feature & main rock (or “Formation” if no single rock type)
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21. 21 Strike
The compass direction of the line produced by the intersection of an inclined rock layer or fault, with a horizontal plane
In northern hemisphere, measured from north
Example: N75°E – the horizontal line is oriented 75º east of north
22. 22 Dip
The angle of inclination of the surface of a rock unit or fault measured from a horizontal plane
Dip direction – direction water would flow if you poured some on the surface
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24. 24 Wave-like undulations of strata
Most form from compressional stresses
Microscopic to Macroscopic in scale
25. 25 Limbs
The two sides of a fold
Axial Plane
- The surface that divides a fold as symmetrically as possible
Hinge
The line drawn along maximum curvature
Plunge
- angle the hinge makes with the horizontal
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27. 27 Anticlines & Synclines
Symmetrical & Antisymmetrical
Overturned
Recumbent (the axial plane is horizontal)
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29. 29 Monocline Rocks bent due to a fault in the underlying bedrock
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31. 31 Plunging folds
32. 32 Doubly-plunging folds
Domes
Large scale, circular or elongated upwarped folded sedimentary strata
Basins
Same, but downwarped
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36. 36 Faults are fractures in the crust along which appreciable displacement has taken place
Sudden movement along faults are the cause of most earthquakes
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38. 38 Brevard Fault Zone (Chattahoochee)
Towaliga Fault / Goat Rock Fault
Pine Mountain, Warm Springs
Cartersville Fault
Rome Fault
39. 39 Dip-slip Faults
Movement parallel to the dip of the fault surface
Strike-slip Faults
Movement parallel to the strike of the fault surface
40. 40 Hanging wall & footwall
41. 41 Normal Faults
Reverse Faults
Thrust Faults
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46. 46 Displacement is horizontal and parallel to the strike of the fault surface
Right-lateral strike slip fault
Left-lateral strike slip fault
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48. 48 Joints Fractures in rocks where no appreciable movement has occurred
May have two or three intersecting sets
Mineral deposits may be deposited within joints
Joints may affect construction projects (highways, dams)
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