Lecture 2 con't part (3)

 
2.1.10 Petroleum accumulations
A petroleum accumulation must have (1) a source of oil and gas, (2) a porous and
permeable bed or reservoir rock and (3) a trap that acts as a barrier to fluid flow so that
accumulation can occur.
2.1.10.1 Origin of petroleum
Oil and gas probably originated from organic matter in sedimentary rocks. The origin of
coal on land is a process similar to the origin of petroleum in the sea. In the formation of
coal, dead vegetation in the absence of oxygen ceases to decompose and accumulates as
humus in the soil and as deposits of peat in bogs and swamps. Peat buried beneath a
cover of clays and sands becomes compacted. As the weight and pressure of the cover
increase, water and gases are driven off. The residue, very rich in carbon, becomes coal.
In the sea a similar process takes place. An abundance of marine life is eternally falling
in a slow, steady rain to the bottom of the sea. Vast quantities of matter are eaten or
oxidized before they reach the bottom but a portion of this microscopic animal and plant
residue escapes destruction and is entombed in the ooze and mud on the sea floor. The
organic debris collects in sunken areas at the bottom and is buried within an
ever-increasing accumulation of sands, clays and more debris until the sediment is
thousands of feet thick. As the sediment builds, the pressure of deep burial begins to
work. Bacteria take oxygen from the trapped organic residues and gradually break down
the matter, molecule by molecule, into substances rich in carbon and hydrogen. The
extreme weight and pressure of the mass compacts and squeezes the clays into hard
shales. Within this deep. unwitnessed realm of immense force, oil is born.
2.1.10.2 Reservoir rocks
A petroleum reservoir is a rock capable of containing gas, oil, or water. To be
commercially productive, it must be big enough, be thick enough, and have enough pore
space to contain an appreciable volume of hydrocarbons. Also, it must give up the
contained fluids at a satisfactory rate when the reservoir is penetrated by a well.
Sandstones and carbonates (such as limestone and dolomite) are the most common
reservoir rocks.

Besides porosity, a reservoir rock must also have permeability; i.e., the pores of the rock
must be connected. Connected pores allow petroleum to move from one pore to another.
2.1.10.3 Traps
Migration is a continuing process once the hydrocarbons have been generated and
expelled from the source rock. Hydrocarbons will move ever upward until they escape at
the surface unless something stops the movement. Therefore, a barrier, or trap, is needed
to impede this migration in order to get subsurface accumulation of petroleum.
A trap is produced by geological conditions that cause oil and gas to be retained in a
porous reservoir. Reservoir traps for hydrocarbons have two general forms: (1) an arched
upper surface, commonly called structural and (2) an up-dip termination of porosity,
called stratigraphic (Figure 2-8).


2.1.10.4 Structural traps
A structural trap is formed by the folding or faulting of the rock layer that contains the
hydrocarbons (Figure 2-9). Structural traps vary widely in size and shape. Some of the
more common structural traps are anticlinal traps, fault traps and dome and plug traps.


2.1.10.5 Stratigraphic Traps
A stratigraphic trap is caused either by a nonporous formation sealing off the top edge of
a reservoir bed or by a change of porosity and permeability within the reservoir bed itself
(Figure 2-10). Two general kinds of stratigraphic traps are the disconformity and the
angular unconformity, both resulting from unconformities.


 


2.1.10.6 Combination traps
Another common type of reservoir is formed by a combination of folding, faulting,
changes in porosity and other conditions - some structural and some stratigraphic in
origin. Examples of reservoirs of this nature are the many reservoirs found in the
Seeligson field in Southwest Texas or parts of the East Texas field.





Lecture 2 con't part (2)


2.1.9 Structural geology
2.1.9.1 Introduction
At destructive plate margins, the sediments and the top part of the crust are compressed
and deformed by the process of collision. The rocks are bent and fractured. The study of
the structures that result and the processes that form them is called Structural Geology.
2.1.9.2 Earth movements
Most rocks are fractured during earth movement, resulting in cracks called joints. If the
rock layers on one side of a fracture have moved in relation to the other side, the fracture
is called a fault (Figure 2-4). Displacement - or how far apart the sides of the fault have
moved - may range from only a few inches to many miles, as along the San Andreas fault
in California.



2.1.9.3 Faults
A simple classification system outlines four kinds of faults: normal, reverse, thrust, and
lateral (Figure 2-4). The names are derived from the movement of adjacent blocks.
Movement is up or down in normal and reverse faults but is mainly horizontal in thrust
and lateral faults. A combination of vertical and horizontal movements is also possible in
all faults.
Rotational faults and upthrusts (Figure 2-5) are variations of normal and reverse faulting.
They are most important to the petroleum geologist because they affect the location of
oil and gas accumulations.


Earth movements often bury or prevent the depositing of part of a sediment series that is
present elsewhere. Such buried erosion surfaces are called unconformities. Two general
kinds of unconformities are the disconformity and the angular Figure 2-6). Earth
movements are most important to petroleum geology because they produce barriers that
cause a large proportion of petroleum accumulations.



2.1.9.4 Folds
Folds can be classified in many ways, one of the simplest is into anticlinal and synclinal
folds.
As compressional forces increase, the folds become tighter and the limbs drop more
steeply. Assymetric folds are ones in which one limb dips more steeply than the other.
These dips can eventually become greater than vertical and folds become overturned.
Axial plane cleavage can develop which is caused by alignment of platey minerals
parallel to the fold axis. With increasing deformation this cleavage can dominate the
structure of the rock, obliterating the original bedding. Fold axes need not be horizontal,
in which case they are said to plunge.
If more than one episode of the folding takes place, then the axial planes cleavage
developed by the first phase may itself be folded. This is then known as superimposed
folding and can often be recognized by statistical analysis of several fold axes in one
area.


Folding in sedimentary rocks is important as it creates the potential for oil traps on the
Crest of folds, and these are a major cause of hydrocarbon accumulations.


2.1.9.5 Joints
These are fractures in the rock which are not associated with any significant movement
of the rock. They typically occur in Limestones and Dolomites due to solution along
natural planes of weakness by percolating underground waters, or by removal of
overlying weight of rock by erosion which allows the rock to expand slightly from stress
release, and fracture. They normally develop in three planes, all at right angles, and often
have a strong control on the geomorphology of the area. Jointing in the rocks can lead to
large volumes of porosity and is an important reservoir type, particularly in carbonate
rocks. It can also give lost circulation problems when drilling a highly jointed or
cavernous area.
2.1.9.6 Unconformities
Although these are not strictly structural features, we will look briefly at unconformities.
An unconformity is any break in the geological sequence.