Fractures

FRACTURES OF GEOLOGICAL ORIGIN
Presented by
Arvind Shukla
M.Sc.(Applied Geology, 4th semester)
Department of Earth and Planetary Sciences
University of Allahabad, Allahabad, U.P.
Email:-arvindshukla.au@gmail.com

INTRODUCTION
In a rock fractures are the surfaces of weakness along which two
blocks have tendency to move or break.
Fractures are also defined as the separation of a body into pieces
due to stress, at temperatures below the melting point. (Haakon
Fossen, 2010).
Penetrative and pervasive on the scale of observation.
Developed mainly due to brittle failure in the rock.
Forms as a result of external (e.g. tectonic) or internal (thermal or
residual) stress.

IMPORTANCE OF FRACTURE
1. Conduits for the migration of fluids through solid rock.
2. Migration of groundwater, of hydrocarbons, and of
hydrothermal and metamorphic fluids.
3. To know the tectonic evolution of the Earth's crust and the
dynamic processes that drive that evolution.
4. Fractures often serve as the site of preferential weathering and
thereby control the form of much of the Earth's topography.
5. Major impotence in the integrity of nuclear waste disposal sites.

6. Affect the location of hydrothermal mineral deposits.
7. Provide a better understanding of the secondary mineral deposit
along the joint planes.
8.Because the cohesion of the rocks is lost across fracture
surfaces, they are planes of weakness in the rock. This inherent
weakness must be accounted for in the building of dams, bridge
abutments, tunnels, mines, and similar engineering projects.
9. To better understand where large earthquakes originate.

CLASSIFICATION OF FRACTURE
There are two types of fractures classified into 3 modes-
1). Extensional Fractures: Mode-I (Joints)
• Form when the adjacent blocks move away from each other in a
direction perpendicular to the fracture plane.
• Very often these fractures are cemented with minerals that precipitate
from the solution filling the rock’s pore space. Quartz in silica-rich
rocks and calcite in carbonate-rich rocks commonly seal the fractures.
2). Shear Fractures: Mode-II (Faults)
• Involve displacement of adjacent blocks parallel to the fracture plane
• Shear fractures exist at any scale from microns to hundreds of
kilometers, and are often seismogenic (i.e. they are associated with
earthquakes).

Fracture is a general term. It is mainly classified as Faults
and Joints.
FAULT
•A fault is a fracture across which two blocks have slipped; the
displacement of adjacent blocks is parallel to the fault plane.
•Faulting corresponds to the brittle failure of an undeformed rock
formation or, alternatively, involves frictional sliding on a pre-
existing fault plane.
•Faulting occurs when the maximum differential stress exceeds the
shear strength of an intact rock formation or the frictional strength of
a pre-existing fault.

FAULT TERMINOLOGY
Fault plane, Footwall, Hanging wall, heave, throw, fault scarp, hade, ……..

TYPES OF FAULT
1. Normal Fault
2. Reverse Fault
3. Strike Slip Fault
Normal Fault
Source:https://www.google.com/bibikchatterjee/faultbibekfinal

REVERSE FAULT
STRIKE SLIP FAULT

EVIDENCE OF FAULTING
The most important evidences of faulting are:-
A). Geological evidences:-
1. Repetition and omission of strata.
2. Offset of rock unit: - Displacement of rock bed, dyke, vein, etc.
Occurs on opposite site of a fault. Offset of quartz vein.
3. Stratigraphic sequence
B). Fault Plane Evidences:-
1.Feather joints
2.Slickensides-The movement of one block against another block
result polishing and grooving of fault surfaces. These grooved and
striations are called slickensides. Slickensides are useful to knowing
the direction of the last movement on a fault surface.

3). Fault Breccia and Gouge:-
Angular grains are embedded in a finely grounded rock are called
“faulted breccia, formed as a result of grinding and crushing movement
along a fault.
When the rock is broken into clay or silt size particles as a result of
slippage on the fault, it is referred to as fault gouge.
4).Mylonite:-Along some faults rocks
are sheared or drawn out by ductile
deformation along the fault. The
resulting rock is a fine grained show
evidence of shear, called
mylonite. Faults that show such ductile
shear are referred to as shear zones.

Mechanism of fault (Anderson’s theory): -

JOINT
 A joint is a type of fracture surface of geological origin along which no
appreciable displacement has taken place.
In joint movement of adjacent block are essentially perpendicular to the
fracture surface. Joint leads to the crustal extension.
Joint usually developed in shallow part of the earth’s crust and are mostly
associated with other deformed structure like fold and fault.
Joint filling (Secondary Deposit)-
•All materials occurring between the fracture walls are referred to as joint filling.
•The secondary deposit along joints are dilational, if the vein material occupies space
between the two original fracture surfaces, or non-dilational if the vein material
occupies space made available by replacement of the original rock outside the two
original fracture surface.

Joint related terminology
I. Joint Set:- A group of parallel (similar orientation ) or sub-parallel
joints.
II. Joint system:- A joint system is formed when multiple or
differentially oriented joints sets cross each other.
III. Master Joint:-A joint which extent over long distances.
Classification of joints-
1.Based on orientation of joint set-
i. Orthogonal joints
ii. Diagonal Joints
2.Based on nature of filling-
- Filled and unfilled
3.Based on angular relation of joint set-
i. Shear joint
ii. Extensional joint
iii. Oblique joint

Fractures

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