Chapter 10 Deformation Of Rocks PDF

Summary

This document describes the deformation of rocks, covering topics such as stress, strain, types of deformation (elastic, ductile, brittle), factors influencing deformation (depth, rock type, time), and mapping rock structures. The document also includes diagrams.

Full Transcript

Figure 10.1
Chapter 10
Deformation of Rocks

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 Chapter 10
Crustal Deformation
Topics covered -
Stress and strain
Mapping strike and dip
Folds
Faults
Joints

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 Why knowledge of folds and faults
is important.
orientation of folds and faults give
– geologic setting
– direction of forces that produces structures
economic importance
– oil and gas trapped by structures
– must find faults so do not build structures there
– ore deposits localized on faults
folds faults control
location of oil

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 Deformation of Rocks
Deformation results in folding, flowing, fracturing
Folds and faults are geologic structures in response to
tectonic forces or stress on the rock
Structural geology is the study of the deformation of rocks.

O

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 Stress and Strain
Stress (tectonic forces)- is the amount of
force acting on the rock
Strain (deformation) – is the shape or
volume changes caused by stress

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 Three Types of Differential Stress
Differential stress is force applied
unequally in different directions.
compressional stress – forces push compresses
together
– shorten the rock body reducing its
volume
tensional stress (extensional) – widens
forces pull apart
– elongate rock body
twist
shear stress – forces push toward
but parallel to one another

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 Three Types of Deformation
elastic deformation –a temporary change in shape in
response to stress. This is not permanent because the elastic
limit of the rock has not been exceeded so the rock rebounds
when the stress is released
ductile deformation - when the rock bends
or flows, changes shape without breaking.
This is permanent.

brittle deformation (brittle failure) –
when the rock fractures, breaking into
separate pieces. This is permanent

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 Factors that determine if ductile or brittle
deformation will occur (that is will the rock fold or fracture)
depth-
– brittle deformation occurs at shallower depths because the rock is
fractures
cooler and pressures are lower so the rock will break more easily.
– ductile deformation occurs at great depth where pressure and
folds temperature are higher, and the rock is more mailable.
rock type
– brittle behavior is favored in silicate rich rocks, such as granitic
and basaltic rocks, because they are composed of interconnected silicate
minerals which have strong internal bonds
– ductile behavior is favored in nonsilicate rich rocks or shale
because nonsilicate minerals have weaker bonds
because clays composing shale are weakly cemented
time – brittle deformation occurs when forces acts quickly over short time,
versus ductile deformation when forces acts slowly over long time
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 Mapping rock structure
s Locate outcrop - surface exposure of rock
– Identify the rock type
Measure strike and dip of folds, faults and rock layers
Plot all the strike, dip and rock type information on a
geologic map.

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 Strike
Line produced by the intersection of a
horizontal plane on the rock surface
– if roll ball down rock surface it is the line
perpendicular to the path the ball takes
report as an angle relative to north
– N60oE = strike is 60o east of north
N
N
W E
60o
strike S 16
809

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 Dip
angle of inclination of the rock surface from the
horizontal plane
– the path of a ball rolling down the rock face
dip is always perpendicular to the strike
report angle and direction of dip
dip of 30oE
Horizontal plane
30o
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Strike = N60oE
Dip = 30oE

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 Geologic map
plot strike and dip of each structure
color code rock formations
can use this map to infer the shape and orientation
of structure below the ground

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817

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 Parts of a Folded Rock
limb - the 2 sides of the fold

hinge line (axis) - a line
drawn along the points of
maximum curvature of each
layer

axial plane - imaginary
surface that divides the fold
as symmetrically as possible

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 Parts of a Folded Rock (continued)

Non-plunging
fold
plunge - the angle
of incline of the
axis

hogback - steeply
inclined angular Plunging fold
ridges
– formed when
folded strata are
resistant to hogback
weathering and
form outcrop
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 Fold types
anticline/syncline
monocline
dome/basin

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 Anticline and Syncline
anticline - arching of geologic
layers
– older rocks on the inside

syncline - trough, downfolded
layers
– older rocks on the outside

produced by compressional
forces
occur together in sets
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 Features of anticlines and
synclines
symmetrical when both limbs are at same angle
asymmetrical when the limbs are at different angle
plunging when the hinge line dips into the ground
– anticline outcrop points in the direction of plunge
– syncline outcrop points opposite of the plunge direction
these folds do not go on forever they dissipate at
their ends

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824

sumpetrical
syncline syncline

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 799
Compressional forces produce
anticlines and synclines

Where do we get compression? –
Subduction zones where plates are colliding 43
827

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Map View of
Plunging
Folds

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Before
erosion

After erosion
of to the
plane
shown
above
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 Axial Trace of a
Plunging
Anticline

Landers Oil Field which
occurs
on the crest of an anticline
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Kurt N. Coonstenius
 Monocline
A fold that has only one limb
produced by vertical displacement along a fault rather than
compression
Overlying folded strata are folded over a vertical fault in
the underlying basement rock

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 Dome and Basin
dome - circular upwarping, oldest strata inside
basin - circular downwarping, youngest strata inside

Dome Basin

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 Faults
Faults are fractures with appreciable
displacement

Three types of fault
– Dip-slip
normal fault
reverse fault
– Strike-slip fault
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 Dip-slip faults
(either a normal or a reverse fault)
Dip-slip faults have movement
parallel to the dip of the fault
surface, so they have vertical
displacement.
hanging wall - rock surface above
the fault
foot wall - rock surface below the
fault
fault scarp - line of the fault on the
surface, which is generally a long
low-lying cliff

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1964 Alaska earthquake

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 Reverse Fault
(A type of dip-slip fault)

Hanging wall moves up
relative to the footwall
– older strata ends up over
younger strata
produced by compressional
forces (pushing together)
– results in crustal shortening
can occur at subduction
zones (convergent
boundaries)
Ketobe Knob, Utah
https://structuralgeo.files.wordpress.com/2013/07/reverse-fault-zone-
ketobe-knob-utah.jpeg 62
 Normal fault
(a type of dip-slip fault)

In normal faults the
hanging wall moves down
relative to the footwall.
produced by tensional
forces (pulling apart)
– results in lengthening and
extension of the crust
can occur at spreading
centers

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 Fault scarp

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Normal fault
Normal dip-slip fault

Hanging wall
Foot wall

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 Features of normal faulted terrain
horst – uplifted block bounded by two normal faults
graben – down-dropped block bounded by two
normal faults

fault-block mountains are produced in normally
faulted terrain.
– Example - Basin and Range Province of the southwestern
United States 66
 Normal faulted terrain: Fault block mountains of
the Basin and Range Province of SW United States

Extensional
forces
lengthen the
crust

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 Strike-slip fault
not a dipslip fault no vert displacement
Fault movement is horizontal and parallel to strike
– No vertical displacement,
– fault gauge erodes to produce linear trough
transform fault are strike slip faults
– Example: San Francisco fault system (1906 earthquake)

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 Joints- are fractures with no appreciable
displacement
Examples of joints
columnar joints -
– shrinkage fractures in cooling
igneous rock creates elongate
pillar-like structures Devils Tower of Wyoming
((http://blogs.agu.org/mountainbeltway/2011/08/31/columns-form-
perpendicular-to-cooling-fronts/)

sheeting - from unloading of
overlying rock
– joints parallel to the ground
surface
– breaks rocks into “sheets”
– Creates exfoliation domes
brittle failure associated with
folding

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 Importance of joints
Enhanced chemical weathering
can influence direction of streams
hydrothermal solutions deposit ore minerals
risk to construction projects
– Teton Dam,Idaho, failure 1976
– seepage along joints

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Chemical weathering is enhanced along joints.

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