Faults fold and deformation
Hanging wall or headwall moves down in relationship to the foot wall in a normal fault.
Normal Fault
Result from compressional forces where rocks are pushed upward.
Reverse Fault
Factor of how rock material behaves
Temperature and Confining pressure
Folds can:
Occur together
Plunging folds dip between
10° to 80°
Complex fold situations
upright meaning that their axial planes are vertical and both sides dip at the same angle.
Strike and dip
used to describe the orientation of rock layers
Factors influencing mass wasting
vegetation cover
What factors influence mass wasting part 3
water content
Compressive
Creates folds, reverse & thrust faults
Tensional
Creates normal faults
Shear
Creates strike-slip faults and oblique
Most famous Strike-Slip fault
The San Andreas
what factors influence mass wasting part 2
Weathering and climate
Folded rock layers
When compressed, rock layers deform into folds because the rocks have entered plastic strain or deformation.
Recumbent Folds
When deformation is so extreme that axial planes of folds have become horizontal, this creates a special overturned fold called a recumbent fold.
all faults caused by
compression
mass wasting more common in
loose or poorly consolidated material than in bedrock because it breaks apart more easily
ConfiningPressure
lower confining pressure allows materials to be brittle and fracture sooner.
in humid areas, weathering is deeper and produces tens of meters of unconsolidated material which leads to increased
mass wasting
faults
a fracture along which rocks on opposite sides of the fracture have moved parallel with the fracture surface
How do we figure out Strike
a long line oriented parallel to the compass direction of the rock layer
How do we figure out Dip
a short tick mark is placed in the center of the line on the side to which the inclined layer
oldest in the middle
anticline
water content in mass wasting
may increase the weight of a slope to induce failure reduces the amount of friction between particles clay particle are platy and slide easily past one another
Geologic Structure Joints:
often associated with folding events.
Dynamic Forces
plate boundaries cause fracturing, folding, metamorphism, and igneous activity.
All rock layers dip towards the axis in
plunging synclines
Plunging fold
refers to how a fold looks when they appear to dive or underneath adjacent rocks.
Monocline
represents a simple bend or flexure in otherwise horizontal or uniformly dipping rock layers.
Syncline
represents an downward arched fold with the youngest rock layers in its core.
Anticline
represents an upward fold with the oldest rock layers in its core.
Faults Cause:
rock layers to break, bend, fold, etc.
What can extreme stress and pressure cause
rocks to shear along a plane of weakness creating a fault.
Fracture:
Irreversible strain causing rock to break or faults to form.
How rock folds are formed
1. type of stress applied to rock 2. temperature of rock 3. pressure under which the rock is deformed 4. type of rock being deformed
Vertical folds dip between
81° to 90°
Youngest rockas at the folds center
Basin
are inclined meaning they have different angles on either side of the fold.
Complex folds
Why are joints different:
Do not have any significant offset or rock layers either vertically or horizontally
Oldest rocks at the folds center
Dome
Unlike an anticline, all the folded rock layers dip outward from a central point as opposed from a line in an anticline
Domes
Parallel lines are NOT
Faults
On a large scale these features are known as rift valleys.
Graben Fault
Produced when tensional stresses result in the subsidence of a block of rock
Graben Fault
What is the new fault
Graben Fault
Grand monocline
Grand canyon
Produced by the development of two reverse faults causing a major block of rock to be pushed upward.
Horst Fault
new fault
Horst Fault
More ways that deformation causes rocks to change their shape
Joints, folds, domes, basins
What are the three groups of folds
Monocline, Anticline, Syncline
Result of tensional forces (pulling apart of rocks).
Normal Fault
The hanging wall or head wall moves down in relation to the foot wall
Normal Fault
Major Groups of faults
Normal ► Reverse ► Thrust ► Strike-Slip► Oblique-Slip
Both walls move outward and pull apart.
Oblique-slip fault
Caused by a combination of shearing and tension of compressional forces.
Oblique-slip fault
Combination of upward and downward movement of the headwall and footwall.
Oblique-slip fault
Vertical movement roughly matches horizontal movement along fault plane.
Oblique-slip fault
All rock layers dip away from the fold axis in
Plunging anticlines
Headwall moves up in relationship to the footwall in a reverse fault due to compression.
Reverse Fault
The headwall has moved upward in relation to the foot wall.
Reverse Fault
Geologic Structures Domes:
Rock layers dip away from the center with the rocks getting older from the outside in
Geologic structures:Basins
Rock layers dip towards the center with the youngest rocks at the fold's center.
Ductile Deformation
Strain is irreversible causing folds to form.
Fault blocks move side ways from one another instead of up or down.
Strike-Slip faults
All movement is in the direction of the fault plane's strike.
Strike-slip faults
Caused by right lateral or left lateral depending on the apparent direction of offset.
Strike-slip faults
Formed by shearing forces.
Strike-slip faults
Relative motion of fault is along a horizontal plane not a vertical plane.
Strike-slip faults
Complex Folds:
Symmetrical, Asymmetrical, isoclinal, overturned, recumbent, chevron
Looks like the head wall thrusts over the foot wall.
Thrust fault
less than or equal to 45 degrees.
Thrust fault
Why do geologist measure the orientation of rock layers
To describe the type of folding that has occurred
What is a rock deformation?
defined as a change in the shape or volume of rocks and is caused by: Dynamic Forces
Geologic Structures Joints:
distinctively different from faults
When a rock is subjected to increasing stress:
either deforms or breaks
Geologic Structures Joints:
fractures with no displacement of rock.
Geologic Structure Joints:
generally planar fracture formed in a rock as a result of stress applied to the rock.
Headwall
is above the fault plane.
Headwall moving upward
is always compression
Footwall moving upward
is always tension
Orientation of rock layers: Dip
is the angle between a horizontal plane & the inclined plane and is measured perpendicular to the direction of strike
Dip
is the angle that the bed makes with horizontal, measured in the vertical plane, in the direction perpendicular to the strike.
Orientation of rock layers: strike
is the compass direction of any horizontal line formed on the rock plane
Stress
is the force applied to a body of rock or crust.
Strike
is the orientation of the line of intersection between the horizontal plane and the rock bed.
Strain
is the resulting deformation that occurs to the rock.
Footwall
lies below the fault plane.
Overturned folds
limbs dip in the same direction, That means one side has been rotated 90 degrees from its original position and it is now upside-down.
Fold center
syncline
Forms a downward bending arch
syncline
youngest layer is in the core of the fold
syncline
Temperature
temperatures stretch the bonds of mineral molecules causing them to be more ductile.
Normal Faults Caused by
tension
Differenital Stress
tension, compression, Shearing
How are faults formed
tensional or compressive or shearing stress.
What does Strike measure
the "direction" of the rock in relationship to north
mass wasting
the downslope movement of material under the direct influence of gravity varies by geologic factors
Factors influencing mass wasting
the steepest angle that a slop can maintain without failure is the angle of repose
What does Dip measure
the steepness or angle of the rock layer .
