SUG Board Review Module 1 PDF

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This document is a Society of USeP Geologists 2014 module on geological principles. It details the basic structures of geology and Earth's formation.

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 Table of Contents

PRINCIPLES OF GEOLOGY........................................................................................................................ 3
GEOMORPHOLOGY.................................................................................................................................... 31
GEOLOGY OF THE PHILIPPINES AND SOUTHEAST ASIA............................................................... 62
HISTORICAL GEOLOGY AND PALEONTOLOGY................................................................................. 92
STRUCTURAL GEOLOGY....................................................................................................................... 105
VOLCANOLOGY........................................................................................................................................ 134
STRATIGRAPHY........................................................................................................................................ 152
ANSWER KEYS...................................................................................................................................... 165

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PRINCIPLES OF GEOLOGY

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 As the solar nebula continued to collapse and
PRINCIPLES OF GEOLOGY rotate, the planetesimals in the inner solar system
started to gravitationally attract each other and
GEOLOGY accrete, or accumulate, into larger and larger
bodies. This process of accretion is how the
- from the Greek words geo (earth) and logos terrestrial planets - Mercury, Venus, Earth, and
(discourse); literally the science of the Mars - gradually formed over millions of years.
Earth, dealing with the study of its
composition, structure, history, past life The gravity of these growing protoplanets would pull
forms and processes responsible for the in and incorporate more planetesimals, heating
Earth’s present configuration. them up through the energy of these impacts. This
heating led to planetary differentiation, where
denser materials like iron and nickel sank to the
core, while lighter silicate materials rose to the
CHALLENGES IN UNDERSTANDING THE
surface, forming the mantle and crust.
EARTH
Over time, the majority of planetesimals were either
incorporated into the growing planets or ejected
- The Earth is a dynamic body with many from the solar system entirely. However, some
interacting parts and a complex history; remnants of this early planetesimal population still
exist today as asteroids, comets, and other small
- The Earth has been changing throughout solar system bodies.
its long existence and continues to
The accumulation of planetesimals into the planets
change; and
was a crucial step in the formation of our solar
system around 4.7 billion years ago, laying the
- Changes can be rapid and violent (e.g.,
foundations for the diverse worlds we see today.
landslides, volcanic eruptions) or slow and
gradual.

TWO MAIN BRANCHES OF GEOLOGY

1. Physical or Dynamic Geology – involved in
the study of the material composition,
appearance, structure and processes of the
Earth.

2. Historical Geology – deals with the history of
the Earth. This includes the Earth’s origin,
relative and absolute timing of events that
have shaped the Earth, as well as the life
forms that have appeared in Earth’s history.

EARTH ORIGIN PROCESSES

Around 4.7 billion years ago, the solar system was
in the early stages of its formation (Figure 1.1). At
this time, the solar nebula - the cloud of gas and
dust that collapsed to form the Sun and planets -
was still present. Within this nebula, small solid Figure 1.1. Steps in Forming the Solar System. This illustration
particles called planetesimals began to form. shows the steps in the formation of the solar system from the solar
nebula. As the nebula shrinks, its rotation causes it to flatten into a
Planetesimals were the building blocks of the disk. Much of the material is concentrated in the hot center, which
will ultimately become a star. Away from the center, solid particles
planets. They were conglomerations of various
can condense as the nebula cools, giving rise to planetesimals, the
silicate compounds (containing silicon, oxygen, and building blocks of the planets and moons.
other elements), iron and magnesium oxides, and
smaller amounts of other chemical elements. These
planetesimals ranged in size from a few kilometers
to tens of kilometers in diameter.

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 PLANETARY DIFFERENTIATION LAYERS BASED ON COMPOSITION

− Planetary differentiation is the process by
The Crust consists of:
which a planet's interior chemically
separates into distinct layers due to
1. The continental crust - relatively light
differences in density and chemical
“granitic” rock that includes the oldest rock
properties of its constituent elements. This
of the crust; generally richer in Na and K;
occurs through partial melting driven by
thickness ranges from 30 to 80 km,
heat from radioactive decay and planetary
sometimes attaining 100 km in some
accretion.
portions.

Differentiation happens through: 2. The oceanic crust - composed of dark,
dense volcanic rocks (basalt) with densities
▪ Gravitational separation - Dense iron sinks much greater than that of granite; more Fe-
inward, taking siderophile elements with it. rich than the continental crust and thinner,
Lighter elements rise. ranging from 3 to 10 km in thickness; young
▪ Collision - Earth's Moon likely formed from and relatively undeformed by folding.
material splashed into orbit by a giant impact,
removing lighter silicates and leaving dense The Mantle surrounds or covers the core;
metal behind. constitutes the great bulk of Earth (82% of its
volume and 68% of its mass); composed of iron and
magnesium silicate rock.
At about 1 billion years after the Earth was formed,
the temperature at depths of 400-800 km was The Core is the central mass about 7000 km in
enough to melt Fe. diameter; density increases with depth but
averages about 10.78 g/cm3 ; constitutes only 16%
Large drops of Fe have fallen toward the center,
of Earth’s volume but accounts for 32% of Earth’s
displacing the lighter minerals.
mass; mostly composed of iron.
About 1/3 of the material sank to the center, a large
part being converted to a molten state. EARTH’S OUTER LAYERS

The molten material floated upward to cool and form The outermost layers of Earth are the
a primitive crust. atmosphere, hydrosphere, and
Such differentiation resulted in the Earth’s internal biosphere.
layering (Figure 1.2).
The continents and ocean basins are
Differentiation probably initiated the escape of Earth’s major surface features.
gases from the interior which eventually led to the
formation of the atmosphere and oceans, and
ultimately, life.
THE CONTINENTS AND OCEAN BASINS
The transfer of internal heat to the surface was
accomplished by convection, even when the mantle
The ocean basins occupy about two-
solidified.
thirds of Earth’s surface; characterized by a
spectacular topography. The continents
rise above the ocean basins as large
platforms.

MAJOR FEATURES OF THE CONTINENTS

Three basic components:

Figure 1.2. The1.
MajorShield - large
Structural Units ofareas of (1)
the Earth. highly
Crust:deformed igneous and metamorphic rock (basement complex).
Thin, rigid outer shell (continental and oceanic); (2) Mantle: Solid,
slowly deformable iron-magnesium silicate layer; and (3) Core:
Iron-nickel inner and outer layers.

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 2. Stable platform or craton - extensive flat,
stable regions of the continents in which
complex crystalline rocks are exposed or
buried beneath a relatively thin
sedimentary cover.

3. Folded mountain belts – uplifted
mountain ranges that are sites of tectonic
convergence.

The relative sizes and ratios of these three Figuew 1.3. Major Provinces of the Ocean Floor.
components vary from continent to continent. For
example, Africa has the largest shield areas, while
Asia has more fold mountains and volcanic belts.

MAJOR FEATURES OF THE OCEAN FLOOR

1. Mostly basalt, a dense volcanic rock, and its
major topographic features are somehow related
to volcanic activity.
Figure 1.4. Oceanic Ridge
2. The rocks are young in a geologic time frame;
most are less than 150 million years old.

3. The rocks have not been deformed by Tectonics – study of the origin and
compression. arrangement of the broad structural
features of the earth’s surface (e.g.,
4. The major provinces (Figure 1.3) of the ocean continents, mountain belts, island arcs,
floor are: earthquake belts, faults, folds, etc.).
a. Oceanic ridge - most striking and
important feature on the ocean floor; a Plate – a large, mobile slab of rock that is
huge, crack-like valley, called the rift part of the earth’s surface. It may be made
valley, runs along the axis of the ridge up entirely of sea floor (e.g., Nazca plate)
throughout most of its length (Figure 1.4). or both continental and seafloor (e.g., North
b. Abyssal Plain - vast areas of broad, American plate).
relatively smooth, deep- ocean basins on
both sides of the ridge; lies at depths of Plate tectonics – the principle that the
about 4000 m; consists of: earth’s surface is divided into large, thick
plates that move slowly and change size
Seamounts - isolated peaks of relative to one another.
submarine volcanoes.
Plate boundary – narrow areas of intense
c. Trenches - the lowest areas on Earth’s geologic activity where plates move away
surface; adjacent to island arcs or coastal from one another, past one another or
mountain ranges of the continents. toward one another.

d. Continental margins - zone of transition
3 PLATE BOUNDARIES
between a continental mass and an ocean
basin consisting of continental shelf and 1. Diverging plate boundaries (Figure
continen 1.5)
▪ Where plates move away from
e. tal slope. each other, either within the
ocean or continent.

Types:
▪ Continental extension
▪ Continental rifting
▪ Ocean spreading.

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 ROCKS AND MINERALS

Rock - the material or substance,
consisting of a mineral or aggregate of
minerals, the Earth is made of.

Mineral

1. It occurs naturally as an inorganic
Figure 1.5. Divergent Boundary and its Landform Created.
solid;

2. It has a specific internal structure;
that is, its constituent atoms are
2. Converging plate boundaries (Figure precisely arranged into a crystalline
1.6) solid;
▪ where two plates move toward
each other. 3. It has a chemical composition that
Types: varies within definite limits and can be
▪ Ocean-Ocean Convergence expressed by a chemical formula; and
▪ Ocean-Continent
Convergence 4. It has definite physical properties
▪ Continent-Continent (hardness, cleavage, crystal form, etc.)
Convergence that result from its crystalline structure
and composition.

THE STRUCTURE OF MINERALS

Law of Constancy of Interfacial Angles - each
mineral has a characteristic crystal form. Although
the size and shape of a mineral crystal form may
Figure 1.6. Convergent Boundary and its Landform Created. vary, similar pairs of crystal face always meet at the
same angle.

Polymorphism - ability of a specific chemical
3. Transform boundaries (Figure 1.7) substance to crystallize with more than one type of
▪ where one plate slides structure. Example: Diamond and graphite, pyrite,
horizontally past another plate and marcasite, etc.
along a fault or a group of
parallel faults.

▪ the displacement along the
fault abruptly ends or PHYSICAL PROPERTIES OF MINERALS
transforms into another kind of
displacement 1. Crystal Form - natural crystal faces that
assume a specific geometric form.
Figure 1.7. Transform
Boundary. At 2. Cleavage - tendency of a crystalline
transform boundaries, substance to split or break along smooth
tectonic plates slide planes parallel to zones of weak bonding in
past each other
the crystal structure.
horizontally, creating a
fault line between
them. This motion does 3. Hardness - measure of a mineral’s
not generate or destroy resistance to abrasion (Review Moh’s
crust, but it does cause
earthquakes. Transform
Scale).
boundaries are not
sites of volcanic 4. Specific Gravity - the ratio of the weight of
activity (Estrada, a given volume of a substance to the weight
of an equal volume of water.

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 5. Color – the external identity of a mineral characteristic of deep intrusive rocks that
that can occur as one or as many colors slowly cooled.
due to impurities.
Aphanitic – fine grained; the mineral
6. Streak - It is the color of a mineral in components are not visible to the naked
powder form. eye (i.e., microscopic); formed by relatively
fast cooling of some volcanic rocks (e.g.,
basalt).
IGNEOUS ACTIVITY
Glassy – texture of igneous rock with a
high glass content; formed by very rapid
An igneous rock is one that is formed from
cooling, such that minerals had no time to
the solidification of magma.
form crystals.
Magma - is the hot-liquid molten material,
generated within the Earth, that forms Porphyritic – igneous texture in which
igneous rocks when solidified. crystals visible to the naked eye are
embedded in a matrix of aphanitic texture;
Magmas may be: it represents a solidifying magma that has
suddenly erupted to the surface.
1. Intrusive (plutons) - magmas stored
within the crust. HOW MAGMA FORMS

2. Extrusive – magma erupted on the
Magma originates principally by partial melting of
surface either as lava or as fragments
pre-existing rock.
sent into the air (pyroclastic material).

Plutons may be emplaced as concordant or
Sources of heat:
discordant bodies in relation to the layering
of the intruded rock or host rock.
1. Geothermal gradient
a. Sills are concordant plutons; they are flat,
2. The hotter mantle – geothermal gradients
tabular bodies intruded parallel to the
are higher in hot spots, where mantle
layering of the host rock.
plumes, which are narrow upwellings of hot
material within the mantle occur.
b. Dikes are discordant plutons that cut
across the layering of the host rock. When
no layering in the host rock is evident, the
Factors affecting melting temperatures:
pluton is called a dike.
1. Pressure – In general, the melting point of
c. A volcanic neck is an intrusive structure
a mineral increases with increasing
apparently formed within the throat of a
pressure (P). Upwelling mantle material
volcano.
originating from deeper high- pressure
portions would melt at shallower portions
d. Laccoliths are mushroom-shaped bodies
where there is lower P.
that rise near the surface and domes the
overlying layers while it spreads laterally.
2. Water – water vapor under high pressure
can lower the melting temperature (T) of
e. Batholiths are enormous, complex rock
rocks.
bodies that cover at least 100 km2.
EVOLUTION OF MAGMA
f. Stocks are plutons like batholiths but
smaller in size ( 256 mm, cobble 5. Lithification – The
256-64 mm and pebble 64-2 mm). conversion of sediment into
rock trough such processes
2. Sand – grains from 1/16-2 mm. as compaction, cementation,

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 and recrystallization. temperatures and chemical conditions that
prevail deep within the earth.
6. Recrystallization – the It alters the mineralogy, texture and
formation of new crystalline structure of the rocks, to give rise to
mineral grains in a rock. metamorphic rocks.

CLASSIFICATION OF SEDIMENTARY ROCKS
FACTORS CONTROLLING THE
CHARACTERISTICS OF METAMORPHIC
ROCKS
Sedimentary rock – rock that has formed from: (i)
lithification of sediment; (ii) precipitation from 1) Composition of the parent rock.
solution; consolidation from the remains of plants
and animals. 2) Temperature
Types of sedimentary rock:
3) Pressure and stress - buried rocks
1. Clastic (or detrital) – are subjected to confining pressure
formed from cemented (or geostatic pressure), or the
sediment grains that are pressure applied equally on all
surfaces of a body because of
fragments of preexisting
burial.
rocks (e.g.,
conglomerate,
4) Fluids
sandstone, shale)
2. Chemical – deposited by
5) Time
precipitation of minerals from
solution (e.g., rock salt,
limestone).
DIFFERENTIAL STRESS
3. Organic or biochemical –
rocks formed by the The stronger or weaker stress acting on a body
accumulation of the remains of in different directions; often caused by tectonic
organisms. forces.

There are 2 types:

a) Compressive stress
SEDIMENTARY STRUCTURES
b) Shearing stress
Bed (or stratum) – The smallest division Foliation – planar texture that develops as a
of stratified (or bedded) sedimentary rock, result of differential stress.
consisting of a single distinct sheet-like
layer of sedimentary material, separated
from the beds above and below by
CLASSIFICATION OF METAMORPHIC
relatively well-defined planar surfaces
ROCKS
called bedding planes which mark a
break in sedimentation.

Stratification – the condition shown by
sedimentary rocks of being disposed in 1. Non-Foliated Rocks (Figure 1.10)
horizontal layers of beds. (name based on mineral content)

Lamina – the thinnest or smallest
recognizable unit layer of original
deposition in a sediment or sedimentary
rock