Post on 20-Jan-2016
transcript
The deformation in the Plate Boundary zones
Shear Zone : San Andreas
-
Frédéric Flerit
The geometry of the Plates, and their position
Three kind of ocean plate boundary
Tectonics
The Pa-NA Boundary Zone
TOPOGRAPHYFault SYSTEM
Motion of
Pa/NA
The NAF offsets the geology features : 200km
100 km
The NAF Offsets mountain ranges
The NAF Offsets rivers : 100m – 1km
200 m200 m
200 m
200 m
… m
Long term deformation : lateral offsets at all scales
PA
NA
The plates are rigid and they are separated by plastic faults
Two historical major Earthquakes
1906 San Andreas 1857 Big bend
average slip of 6 m.
1906 San Andreas Eq 6m of lateral offset
The NAF Offset orange trees rows : 6 m
The profile of the co seismic displacement measured on the triangulation network of California
(Reid 1910)
100 km
SouthCalifornia
San Andreas Big Bend San Andreas south
Los AngelesLos Angeles
The velocity profile assoiated with the Plate motion
PA
NA
100 km
How to reconcile the Long term deformation with the deformation produced by an earthquake ?
The concept of Seismic Cycle
Two phases
1) interseismic loading
2) Coseismic relaxation
The seismic cycle
Consequence : The crust is elastic (load / relaxation)And the faults in the crust are plastic(permanent deformation)
The concept of Locking depth
Seismic
-
Brittle
(10-20 km)
Aseismic
-
Ductile
The velocity profile
Associated with the
Locking depth : d
Problems
Draw three profiles of the velocity vectors across SAF?
How can we invert the locking depth of the SAF (depth of the transition brittle-ductile) ?
Draw a profile of the velocity vectors parallel to the SAF.
Define the Azimut of the Pa/NA plate motion in Los Angeles Region, What is the Azimut of The SAF ?
What can you tell about the components of GPS velocity vectors perpendicular to the Pa/NA direction ?
Can you predict when and where the next one should occur
NB : the San Andreas Fault takes only 35 mm/yr
out of 50 mm/yr imposed by the plate motion
You will make the hypothese of the seismic cycle
Exercice on the Seismic risk on the San Andreas Fault
The shear strain rates
Dx
v1 v2
yy = Shear strain rates
= Dvy/Dx
= (V1 –V2)/Dx
The deformation in the direction perpendicular to V
y
Draw a profile of the Shear Strain rate and conclude?
x
. .
Question
Define the maximun strain on the SAF assuming that 200 years separate two successive earthquakes.
Geometric interpretation ofshear strain rate
=change in angle
Dx
V1 v2
yy = Shear strain rates = tan()
y
x
. . .
Geometric interpretation ofnormal strain
?
(shortening or lengthening)
Geometric interpretation of normal strain
=Change in length
Dx
l1
l2
yy = normal strain = Dly /Dy
y
x
xx yx
xy yy
The Matrix notation
( )
NOTE
yx = xy
xx yy
( )
The strain matrix is symetric
Deformation of the vector P ?
xx
yy Matrix:
P = Px
Py P
The matrix product allow to resolve the components of the strain For a given direction P
xx
xx
That is Deformation of the vector P :
pxx Px + Py
Px + yy Py
Px
Py.P =
Along x
Along y
Exercices :deform the above square and
circle using the following strainssupposed uniform
xx = 0.5
yy = 2
xy = 0.5
yx = 0.5
xx = -0.5 and yy = 0.5 and
xy = -0.5 and yx = -0.5
xy = 2 and yx = 2
Displacement -
Velocities
Strain
-
Strain rates
To measure the rigid motion of the plates or
of individual points we use the concepts of :
To measure the deformation of the crust or of the lithosphere
we use the concepts of :
The math object associated is a vector
The math object associated is a matrix
REMEMBER
SouthCalifornia
San Andreas Big Bend San Andreas South
Parallel and
tangeantcomponents
of the plate
motion resolved on the 1) SAFand on the2) Big bend
The perpendicular component is associated with the creation of topography with inverse faults
IN MAP view
Lateral motion :
Strike-Slip Fault
Perpendicular motion :
Inverse Fault
Perpendicular motion :
Normal Fault
V
n
Resoling the tangeant and perpendicular component
• nXV=O
•Tangential slip rate t = n.V
Strike-Slip Fault
Perpendicular motion :
• n.V=0•perpendicular slip : e =p.V
Vn
n
np
The concept of Azimut to define the orientation of the plate
boundary in the horizontal plane
nNorth
Azimut
Horizontal plane
GPS velocities
Their Kinematic - motion
Divergent plate boundary condition in Atlantic
The segmentation of the mid oceanic ridge (MOR)