Earthquakes occur as a result of motions on
faults. In this lesson we examine how geologists
characterize and classify faults. We have two
learning objectives; To introduce key terms
geologists use to classify faults; and, to
illustrate examples the major faults so that
you can learn how to draw and label a sketch
of each type the fault.
We use the term dip to indicate the slope or
inclination of any geological surface measured
relative to horizontal.
The steeper the slope the larger the dip angle.
A second characteristic of inclined surfaces
is the strike. A strike line is any horizontal
line drawn or inscribed on a sloping surface.
It is the water line in a sink or bathtub,
or the line your coffee makes as it rests
in your cup. Dip and strike are perpendicular
or 90 degrees from each other.
We can see examples of the dip and strike
on various surfaces we encounter in our daily
lives. The mortar between these bricks is
parallel to the strike and dip
as the corners of the bricks are a ninety
degree angles so it makes sense that their
different edges could be parallel to strike
and dip. Likewise, we can identify the strike
and dip directions for this dumpster panel.
More sloping brick services give us alternative
views of strike and dip directions as well
as different dip angles.
Finally, this sandwich board sign has a steeply
inclined dip
and the strike is parallel to the top or bottom
up the sign.
We can also define strike and dip on this sloping concrete panel.
Two other key terms that we need to know to
classify faults are hanging wall and footwall.
Geologists name
the block above an inclined fault surface
the hanging wall, and the block below the
surface, the footwall.
A simple way to identify which is which is
to place your finger on the fault surface
and move it upward. it will automatically
be located in the hanging wall.
The only time we can't use these terms is
when the fault is vertical and neither block
of rock can be considered to be above or below the other.
Here are three images of faults, with the faults
indicated by the red lines. 
Can you identify the hanging wall and
footwall for these three faults.
Notice that "X" is only above the fault, or
in the hanging wall for this image and it
is in the footwall
below the fault, in both these images.
Geologist label a fault as a dip slip fault
if the hanging wall
moves up or down the fault surface, parallel
to the dip direction.
Normal faults form when the hanging
wall
moves down relative to the footwall. Reverse
faults form when the hanging wall moves up relative
to the footwall.
Notice that the normal faults form under tension,
where rocks move apart or diverge, similar
to conditions found along oceanic ridges.
Reverse faults form under compression, conditions
that are characteristic of convergent plate
boundaries.
Here are two more images of faults. Can you
identify them as normal or reverse on the
basis of the information provided?
In the left hand image, the hanging wall is
to the left to the fault, those layers have
moved up relative the ones on the right,
therefore, this is a  reverse fault. In the case on the right, the hanging wall is again above the
fault. However, in this case the layers have moved down relative to the block on the right so
this must be a normal fault.
Geologists identify strike-slip faults when
rocks move horizontally with little vertical displacement.
For example, these yellow lines have been offset by a fault that cuts across this road in California.
Strike-slip faults are associated mostly with transform plate boundaries. Just as we can
classify dip slip faults as normal or reverse, we can classify strike-slip
faults as right or left lateral. We have to find some
feature we can
match up across the fault to determine the
type to slip.
For example in this hyper realistic portrayal
of a geological event, our geologist is standing
on a deserted
road just as an earthquake occurs. After the
event he is dazed and confused, he looks across the fault trying to classify the offset of the road. 
Would he have to look right
or left to match up the road. He looks
right, making this a right lateral fault.
If he had to look left, we would classify it as a left lateral fault. 
Let's look at some pictures of strike-slip
faults and you can classify them as left or
right lateral.
What about this example? Is this line of trees from China offset by right or left lateral strike-slip fault?
In this case, this is a right lateral fault.
Follow the line of trees in the foreground
to the end and then you would have to move to the right to match up with the next line of trees.
Is this stream valley offset by a right or
left lateral strike-slip fault?
In this case you will notice that the stream in the upper part of the image is offset to the right the stream in
the lower part of the image, making it the
right lateral fault. This is the San Andreas fault.
OK, last one, we promise, are these colorful layers of rock offset by a right- or left-lateral strike-slip fault?
If you were to walk to the end up one of these colorful layers in the lower part the image,
you have to turn to your left to see the same layer in the upper part of the image. 
Consequently, this would be a left lateral fault.
We had two learning objectives for today.
How confident are you that you can complete both of these learning objectives?
What's going on there? Is that big foot? 
No Jen, that's just me in front of a fault, thanks.
