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Brittle Deformation

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Title: Brittle Deformation


1
Brittle Deformation
2
Fracture
  • A planar or curviplanar discontinuity
  • Forms as a result of brittle rock failure
  • Under relatively low pressure and temperature
    conditions in the earth crust
  • Rock fractures range in size from
  • Microcracks Intragranular to intergranular
    (fraction of a mm)
  • Faults - Extend for hundreds of kilometers

3
Brittle Deformation
  • Permanent change in rocks by fracture or sliding
    on fractures
  • Fracture A discontinuity across which cohesion
    (Co) is lost
  • The term fracture includes three basic types of
    discontinuities
  • Extension fracture (type I)
  • Relative movement normal to fracture surface
  • Shear fracture (type II III)
  • Relative movement parallel to fracture surface
  • Oblique extension (hybrid) fracture
  • Relative movement is oblique to the fracture
    surface
  • Vein fracture filled by secondary minerals

4
Four categories of fracture observation
  • Distribution and geometry of fracture system
  • Surface features of fracture
  • Relative timing of fracture formation
  • Geometric relation of fracture to other structures

5
Fracture set and system
  • Fracture set a group of fractures with similar
    orientation and arrangement
  • Small extension fractures are referred to as
    joint
  • Systematic joints have roughly planar surfaces,
    parallel orientation and regular spacing (vs.
    non-systematic joints)
  • Fracture system two or more sets of fracture
    affecting the same volume of rock

6
Sheet (exfoliation) joints
  • Are parallel to topography
  • Can form in any rock, but common in plutonic
    rocks that are exposed

7
Columnar Joints
  • Extension fractures characteristic of tabular
    extrusive igneous rocks
  • i.e., form in lava flow, sill, dike
  • Other types of joint
  • Strike joint, dip joint, cross joint, oblique
    joints

8
Extension fractures associated with shear
fractures
  • Feather (pinnate) fractures form en-echelon to
    a main brittle shear fracture
  • Gash fracture are simiar to feather fractures,
    but filled with mineral, in ductile shear
    fractures
  • Are sigmoidal (S- or Z-shaped)

9
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10
What do we collect about fractures?
  • Orientation (rose diagram, stereonet)
  • Spacing
  • Length
  • Spatial pattern
  • Relation to lithology
  • Relation to layer (bed) thickness

11
Joints
  • Are a type of fracture which form due to tension
  • They form parallel to the minimum tensile stress
  • Perpendicular to maximum tensile stress
  • Shearing is zero along joints when they form
  • Also called cracks or tensile fractures
  • Joints form under
  • shallow depth, low confining pressure (Pc)
  • elastic regime
  • low temperature (T)
  • high pore fluid pressures (Pf)

12
Joints
  • Joints form perpendicular to the maximum
    principal tensile stress
  • i.e, along a principal plane of stress
  • Therefore joints dominantly show separation or
    opening of the walls of the fractures with no
    appreciable shear displacement parallel to the
    plane of the fracture
  • Joints form through the Mode I crack surface
    displacement
  • Joints are commonly characterized by two
    matching, rough, discontinuous, and curved
    surfaces, although they are approximated to be
    smooth, continuous, and planar

13
Tensile strength and jointing
14
Joint sets
15
Modes of crack surface displacement
  • Individual cracks, when loaded, propagate,
    infinitesimally, in three different modes
  • Mode I Tensile (Opening) Mode
  • Tensile cracks form normal to the ?3 (parallel
    to the ?1?2 plane)
  • Crack opens infinitesimally perpendicular to the
    crack plane
  • Crack grows in its own plane no bending/changing
    orientation
  • Mode II Sliding Mode
  • One block moves parallel to the crack normal to
    the fracture front
  • Mode III Tearing Mode
  • One block moves parallel to the crack parallel to
    the fracture front

16
Modes of crack surface displacement
17
Modes of fracture
18
Mode II and III
  • Both are shear mode
  • Do not grow in their own plane.
  • As they start growing, they immediately either
  • Curve
  • Become mode I cracks
  • Spawn new tensile, wing cracks
  • However, shear fractures and faults are not large
    mode II or mode III cracks

19
Joints
  • The planar approximation is justified given that
    scale of geometric irregularities (e.g. joint
    surface morphologies, curvature amplitude) is
    commonly very small compared to the size of the
    fracture surface
  • Termination of the two opposing surfaces at their
    distal edge or periphery (fracture front), i.e.,
    a finite extent of the two walls
  • Displacement is zero at the fracture fronts
  • Involve small relative displacement of the
    originally contiguous points compared to the
    in-plane dimensions of the fracture walls

20
En-echelon Tension Gashes
21
Vein
22
Antiaxial vs. syntaxial vein
23
Joint Spacing Bed Thickness
24
Fracture Terminations
25
Shear Fractures
  • Fractures along which there has been shearing or
    displacement
  • Shear fractures are small, with small
    displacement
  • They occur in intact rock during brittle
    deformation
  • If the amount of displacement is significant and
    measurable, the shear fracture is called fault

26
Faults and joints
27
Shear Fractures
  • Shear fractures, form at an angle to the maximum
    compressive stress and show offset because of the
    shear traction along the fractures
  • The hybrid shear fractures are discontinuities
    with a mixed mode of opening and shear and form
    oblique to the plane of the fracture as a result
    of both tensile normal stress and shear stress

28
Terminology
  • Fracture front The line separating the
    fractured region from the un-fractured part of
    the rock
  • Fracture trace Intersection of the fracture with
    any surface
  • Fracture tip The termination of the fracture
    along the trace of the fracture

29
Joint Surface Morphology
  • Surface morphology of joints show evidence for
    initiation, propagation, and arrest
  • Theoretically, mode I loading in an isotropic,
    homogeneous material should lead to a smooth
    propagation with a mirror smooth surface
  • Joints however are not smooth, because rocks are
    commonly neither homogeneous nor isotropic

30
Out-of-plane Propagation
  • The orientation of the maximum tensile stress in
    front of a single crack tip may not be parallel
    to the normal to the parent crack
  • Cracks propagate so that new portions of the
    crack remain normal to the local maximum tensile
    stress
  • This requires a crack to leave the plane of the
    parent crack in order to maintain its orientation
    relative to the local stress field
  • This out-of-plane propagation is so common in
    microscopic scale that leads to the formation of
    rough, non-smooth fractures surfaces

31
Crack Propagation Paths
  • Out of plane propagation is characterized by a
    combination of two end member crack propagation
    paths
  • Twist leads to segmentation of the crack into
    several smaller crack planes.
  • Represents a rotation of the local maximum
    tensile stress in the initial yz plane.
  • Rotation is about an axis in the crack plane
    to propagation direction
  • Tilt Causes the crack tip to rotate without
    segmentation.
  • Rotation is about an axis in the crack plane __
    propagation direction

32
Mesoscopic Joint Surface
  • Although microscopic out-of-plane propagation is
    common, joints appear smooth on the mesoscopic
    scale.
  • This is due to the homogeneous nature of the
    remote stress field
  • Even when the crack leaves its plane, the general
    propagation path remains normal to the remote
    maximum tensile stress
  • The microscopic out-of-plane propagation leads to
    the development of joint surface morphology

33
Plumose Surface Morphology
  • Helps to interpret rupture nucleation,
    propagation, and arrest
  • Develops largely due to local twists and tilts
    during propagation of a fracture which would
    otherwise be planar.
  • Barbs surface irregularities
  • In homogeneous rocks, barbs trace to the point of
    origin (an original crack)
  • In inhomogeneous rocks (sandstone, shale), barbs
    radiate from either a bedding plane or an
    inclusion in the bed (e.g., fossil, concretion,
    clast)
  • The point of origin may vary from bed to bed in
    shale or siltstone

34
Joint Initiation and Beds
  • If joints initiate from bedding plane, they often
    originate from irregularities such as ripples or
    sole marks
  • Joints in a bed often initiate from a common
    feature such as the upper bedding plane
  • Fossils and concretions often originate joints in
    adjacent beds

35
Rupture Propagation
  • The progress of rupture from the origin to the
    final arrest leads to the formation of some
    patterns that are printed on the surface of
    joints
  • Mirror zone
  • Area immediately adjacent to the point of origin.
  • Forms under small tip stress values, not big
    enough to beak the material at oblique angles
  • Mist zone
  • Forms when larger stresses break bonds at oblique
    angles to crack plane.
  • On the fine scale, this oblique cracking forms a
    non-smooth (misty) zone, separating the mirror
    from the hackle zone

36
Hackle zone
  • Forms when there are local components of twist
    during crack propagation.
  • Form when propagation occurs at a critical
    velocity when cracks branch or bifurcate
  • Hypothesis I High velocities shift the maximum
    local tension away from the existing crack plane
  • Hypothesis II High velocities form secondary
    cracks. The main crack then branches to follow
    the secondary cracks

37
Plumose Structures
  • Also called feathers, hackle plumes, striations,
    or barbs.
  • These record rupture motion
  • Consists of an axis from which barbs mark the
    direction of the rupture front as portions
    diverge away from the plume axis
  • Barbs become more pronounced toward the edge of
    the beds away from the axis
  • Barbs represent long, narrow planes oblique to
    the main fracture plane.
  • Barbs form similar to hackle marks due to twist

38
Plumose Structures
  • Plumose structures have different shapes
  • Axes can be straight to curved
  • Barbs vary from uniform to symmetrical to
    asymmetrical about the axis
  • These variations reflect the degree to which
    rupture velocity was uniform during propagation

39
Arrest of Rupture
  • Arrest lines show up as ridges or cusped waves
    normal or subnormal to the direction of
    propagation of cracks
  • At arrest lines a large component of tilt is
    involved in the out-of-plane crack propagation
  • Arrest lines may be the boundaries between areas
    with perceptible barbs and areas with no barbs.
  • Rock joints may show several arrest lines in a
    row or a single arrest line at the end of a long
    fracture
  • Several arrest lines represent intermediate
    slowing or stopping points for a rupture as it
    moves through the rock to form a joint
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