Q1 Earth and Life Science Module PDF

Summary

This document is a module for a first-quarter Earth and Life Science course at Colegio de los Baños High School. It outlines course requirements, including assessment activities and a grading system.

Full Transcript

EARTH AND LIFE SCIENCE
Level: SENIOR HIGH SCHOOL Semester: FIRST
Subject Group: CORE SUBJECT Quarter: FIRST
Course Description:
This learning area is designed to provide a general background for the understanding of Earth
Science and Biology. It presents the history of the Earth through geologic time. It discusses the
Earth’s structure, composition, and processes. Issues, concerns, and problems pertaining to natural
hazards are also included. It also deals with the basic principles and processes in the study of
biology. It covers life processes and interactions at the cellular, organism, population, and ecosystem
levels.
Course Requirements:
Below are the list of activities that must be completed and submitted.
Raw Final
WEEK
ACTIVITIES Date of Completion Score Grade
Enabling Assessment Activity No. 1 –
1 30
The Goldilocks Planet
Performance Check 1 – Exogenic
2 50
Process in your Community
Performance Check 2 – Chocolate
3 50
Mantle Convection Experiment
Enabling Assessment Activity No. 2 –
4 30
Igneous Rocks
Enabling Assessment Activity No. 3 –
5 30
Deformation of the Earth’s Crust
Enabling Assessment Activity No. 4 –
6 30
Geologic Time Scale
Performance Check 3
50
7 Seismic and Volcanic Hazard 15%
Preparedness
Performance Check 4 – Hydro-
8 50 15%
Meteorological Hazard Preparedness
TOTAL 320 100%

Grading System (Earth and Life Science)
QUARTER 1

Performance Check 50%

Enabling Assessment Activity 30%

Quarterly Examination 20%

FIRST QUARTERLY GRADE TOTAL 100%
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PRE-REQUISUTE ASSESSMENT
1. Why are the inner planets called terrestrial planets?
2. Why are the outer planets called Jovian and Gas planets?

LEARNING MATERIALS: Module, pen, paper, old earth science books, internet (if applicable)
PRE-REQUISITE CONTENT KNOWLEDGE: Inner and Outer Planets
PRE-REQUISITE SKILL: Describe the composition of the planets in the Solar System

TIME ALLOTMENT: 4 HRS
CONSULTATION: For inquiries and clarifications regarding the lesson, you may contact your
teacher thru his FB Messenger or thru his email

RUA: At the end of the lesson, you should be able to:
a. Recognize the uniqueness of Earth, being the only planet in the solar system with
properties necessary to support life
b. Explain that the Earth consists of four subsystems, across whose boundaries matter
and energy flow

INSTITUTIONAL VALUES: Environmental Awareness, Critical and Analytical Thinking
Students will be able to apply
a. Critical and Analytical thinking skills in explaining the reason why Earth is habitable.
b. Environmental awareness on the sub-systems of Earth and its inter-relationship with
one another

OVERVIEW OF THE LESSON
This lesson is all about the earth, particularly the Earth’s subsystems and the relationship of
one subsystem to another, as well as the factors that make a certain planet habitable

STUDENT’S EXPERIENTIAL LEARNING
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1. Venus, Earth, and Mars are part of the inner terrestrial or "rocky" planets. Their composition
and densities are not too different from each other.
2. Venus is considered to be the Earth's twin planet. It has a very similar size and mass with
the Earth. Mars is about half the Earth's size.
3. Orbital period and velocity are related to the planet's distance from the sun. Among the three
planet, Venus is the nearest and Mars is the farthest from the Sun.
4. Rotational speed of Earth and Mars are very similar. Rotational speed of Venus is extremely
slow.
5. Abundance of liquid water on Earth, hence the blue color. The Earth is a habitable planet.

CHUNK 1: FACTORS THAT MAKE A PLANET HABITABLE

FACTORS THAT Not Enough of Just Right Too Much of Situation in
MAKE A PLANET the Factor the Factor the Solar
HABITABLE System
1. Temperature Low Life seems to At about Surface: only
influences how temperatures be limited to 125oC, the Earth’s
quickly atoms and cause a proteins, surface is
molecules move. chemicals to temperature carbohydrate in this
react slowly, range of - molecules, temperature
which 150C to genetic range.
interferes with materials (e.g.,
115oC. In this
the reactions DNA and Subsurface:
necessary for range, liquid
water can RNA) start to the interior of
life. It can also break apart. the solid
cause the still exist
Also, high planets and
freezing of under certain moons may be
conditions. temperatures
water, making cause the in this
liquid water quick temperature
unavailable. evaporation of range.
water.
2. Atmosphere Small planets Earth & Venus Venus’s Of the solid
Traps heat, shields and moons are the right atmosphere is planets &
the surface from have size to hold a 100 times moons, only
harmful radiation, insufficient sufficient-sized thicker than Earth, Venus,
and provides gravity to hold atmosphere. Earth’s. It is & Titan have
chemicals needed an atmosphere. Earth’s made almost significant
for life, such as The gas atmosphere is entirely of atmospheres.
molecules about 100 greenhouse
nitrogen and carbon Mars’
escape to miles thick. It gasses,
dioxide. atmosphere is
space, leaving keeps the making the about 1/100th
the planet or surface warm surface too hot that of Earth’s,
moon without & protects it for life. The too small for
an insulating from radiation four giant significant
blanket or a & small- to planets are insulation or
protective medium-sized completely shielding.
shield. meteorites. made of gas.
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3. Energy When there is With a steady Light energy is Surface: The
Organisms use light too little input of either a problem if it inner planets
or chemical energy to sunlight or too light or makes a planet get too
run their life few of the chemical too hot much sunlight
processes. chemicals that energy, cells or if there are for life. The
provide energy can run the too many outer planets
chemical harmful rays, get too little.
to cells, such
as iron or reactions such as
sulfur, necessary for ultraviolet. Too Sub-surface:
life. many Most solid
organisms die.
energyrich planets &
chemicals are moons have
not a problem energy-rich
chemicals.
4. Nutrients Without All solid Too many Surface: Earth
Used to build and chemicals to planets & nutrients are has water
maintain an make proteins moons have not a problem. cycle, an
organism’s body. & the same However, too atmosphere,
carbohydrates, general active a and volcanoes
organisms chemical circulation to circulate
cannot grow. system, such nutrients.
makeup, so
Planets without as the constant Venus, Titan,
systems to nutrients are Io, and Mars
volcanism on
deliver present.
Jupiter’s moon, have nutrients
nutrients to its Those with a Io, or the and ways
organisms water cycle or churning to circulate
(e.g., a water volcanic atmospheres of them to
cycle or activity can the gas organisms.
volcanic transport and planets,
activity) cannot replenish the interferes with Sub-surface:
support life. chemicals an organism’s Any planet or
Also, when required by ability to get moon with sub-
nutrients are living enough surface water
spread so thin organisms. nutrients. or molten rock
that they are can circulate
hard to obtain, and replenish
such as on a nutrients for
gas planet, life organisms
cannot exist.
Source: https://www.lpi.usra.edu/education/explore/our_place/hab_ref_table.pdf
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CHUNK 2: EARTH’S SUBSYSTEM
Definition of a System
A set of interconnected components
that are interacting to form a unified
whole.
Earth System as closed system
A closed system is a system in
which there is only an exchange of
heat or energy and no exchange of
matter. The earth is a closed
system. It receives energy from the
sun and returns some of this
energy to space.

The Earth system.
(Source: https://www.earthonlinemedia.com)

The atmosphere is the thin gaseous layer that
envelopes the lithosphere.
The present atmosphere is composed of 78%
nitrogen (N), 21% oxygen (O2), 0.9% argon,
and trace amount of other gases.
One of the most important processes by which
the heat on the Earth's surface is redistributed
is through atmospheric circulation.
There is also a constant exchange of heat and
moisture between the atmosphere and the
hydrosphere through the hydrologic cycle.

Atmosphere
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The lithosphere includes the rocks of the crust and
mantle, the metallic liquid outer core, and the solid
metallic inner core.
Briefly discuss the Plate Tectonics as an important
process shaping the surface of the Earth.
The primary driving mechanism is the Earth's
internal heat, such as that in mantle convection.

Lithosphere

The biosphere is the set of all life forms on Earth.
It covers all ecosystems—from the soil to the
rainforest, from mangroves to coral reefs, and from
the plankton-rich ocean surface to the deep sea.
For the majority of life on Earth, the base of the food
chain comprises photosynthetic organisms. During
photosynthesis, CO2 is sequestered from the
atmosphere, while oxygen is released as a
byproduct. The biosphere is a CO2 sink, and
therefore, an important part of the carbon cycle.
Sunlight is not necessary for life.

Biosphere
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About 70% of the Earth is covered with liquid water
(hydrosphere) and much of it is in the form of ocean
water (Figure 3).
Only 3% of Earth's water is fresh: two-thirds are in
the form of ice, and the remaining one-third is
present in streams, lakes, and groundwater.
The oceans are important sinks for CO2 through
direct exchange with the atmosphere and indirectly
through the weathering of rocks.
Heat is absorbed and redistributed on the surface of
the Earth through ocean circulation.

Hydrosphere

WEEK 1 ANSWER SHEET (Please submit only the answers. Do not return the entire module.)

Name: ________________________________ Section: _______________________
LAST NAME, FIRST NAME MIDDLE INITIAL

ENGAGEMENT Score: _____/15
Enabling Assessment Activity No. 1: The Goldilocks Planet
Here is the task you've been assigned. Read the six-stanza poem below first. Find the
Goldilocks element that is mentioned in each stanza next. Third, explain the significance of
the variable mentioned in each verse. And finally, answer the guide questions below.

The Goldilocks Planet

I am happy I’m on earth and not anywhere else Stanza 1:
I breathe well with the greens and everyone else Factors: (1 pt.) _________________
The warmth in the morning balanced by the coolness at night Importance: (2 pts.) _____________
My skin loves summer as I got shield from too much sunlight! _____________________________
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Not too cold and not too warm Stanza 2:
I felt just right even with the storm Factors: (1 pt.) _________________
Water in varied forms you made possible Ignoring Importance: (2 pts.) _____________
you on earth is just impossible! _____________________________

Warming the oceans, creating weather patterns Stanza 3:
The earth is at right distance from you and it matters Your Factors: (1 pt.) _________________
energy gets photosynthesis going Importance: (2 pts.) _____________
So that oxygen and food will keep everyone growing! _____________________________

Living things everywhere, abound and flourish Stanza 4:
They need each other to keep them nourished Factors: (1 pt.) _________________
You make survival a possibility Importance: (2 pts.) _____________
For the Earth’s ecosystems’ sustainability and stability! _____________________________
What would earth be without you? Stanza 5:
Oceans, icebergs, and vapor offer a clue Factors: (1 pt.) _________________
71% of Earth is covered by you Importance: (2 pts.) _____________
Indeed, life on earth is possible because of you! _____________________________

1. What are the layers of the Earth? Describe each one
briefly. (5pts)

2. What are the factors and the four subsystems of the
earth and how do they contribute to the habitability of
the planet? (5pts)

3. What do you think would happen if the Earth is
closer/nearer to the Sun? Can Earth still support life?
Explain your answer concisely. (5pts)

RUA of Student’s Learning Score: _____/15
Since the earth is the only spot in the solar system that can support life, list three issues our
planet is currently facing and suggest a potential solution for each issue you have raised.
You may write a short essay, poem, slogan or draw a poster (15 pts)

___________________________________________________________________
SIGNATURE OVER PRINTED NAME OF PARENT/GUARDIAN
DATE: _____________________
PRE-REQUISITE ASSESSMENT
1. Are limestones considered mineral? Explain
2. Explain why mineral water is not considered a mineral?
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LEARNING MATERIALS: Module, pen, paper, old earth science books, internet (if applicable)
PRE-REQUISITE CONTENT KNOWLEDGE: Inorganic compounds
PRE-REQUISITE SKILL: Ability to distinguish inorganic from organic

TIME ALLOTMENT: 4 HRS
CONSULTATION: For inquiries and clarifications regarding the lesson, you may contact your
teacher thru his FB Messenger

RUA: At the end of the lesson, you should be able to:
identify common rock-forming minerals using their physical and chemical
properties
classify rocks into igneous, sedimentary, and metamorphic describe how
rocks undergo weathering

INSTITUTIONAL VALUES: Environmental Awareness, Excellence, Critical and Analytical
Thinking
Students will be able to apply
a. Excellence in identifying minerals
b. Critical and Analytical thinking skills in classifying rocks
c. Environmental awareness on how minerals affect the environment and man’s manner
of living

OVERVIEW OF THE LESSON
This lesson is all about minerals; its classification and properties, and the classification of rocks

STUDENT’S EXPERIENTIAL LEARNING

Review on minerals and the important properties which define a mineral.
A. Mineral — a naturally occurring (not man-made or machine generated), inorganic (not a
by-product of living things) solid with an orderly crystalline structure and a definite
chemical composition
B. Minerals are the basic building blocks of rocks

CHUNK 1: MINERALS
table salt Mineral Name: Halite
Chemical composition: NaCl
Luster: Non-metallic – vitreous; transparent to
transluscent
Hardness: Soft (2-2.5)
Color: White
Streak: White
Crystal Form / Habit: Cubic
Cleavage: Perfect cubic
Image Source: vayain Specific Gravity: Light (2.2)
Other Properties: Salty taste; very soluble;
produces reddish spark in flame

The geology of a given area, particularly the rocks and minerals, plays a large role in
the local environment.
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Rocks and minerals break down to form soils.
The minerals and nutrients in a particular soil influences what sorts of plants and
therefore animals will occur in an area.
Most rocks are formed from one or more minerals.
Minerals are inorganic substances with specific physical and chemical properties.
Minerals can be used to identify rocks and soils.

Chemical Properties of Minerals
Approximately 95% of minerals are silicates which contain silicon (Si) and oxygen (O)
atoms bonded together.
Oxygen (46%) and silicon (28%) are the two most abundant elements in the Earth’s
crust.
Carbonates contain CO3 molecules.
Sulfates contain S04 molecules, sulfides contain elemental sulfur (S).
Oxides of iron and aluminium are relatively common, e.g. haematite.

Physical Properties of Minerals
These properties that help geologists identify a mineral in a rock are: color, hardness, luster,
crystal forms, density, and cleavage. Crystal form, cleavage, and hardness are determined
primarily by the crystal structure at the atomic level. Color and density are determined primarily
by the chemical composition.
Color/Streak
A lot of minerals can exhibit
same or similar colors.
Individual minerals can also
display a variety of colors
resulting from impurities and
also from some geologic
processes like weathering.
Streak test
Hardness – it is a measure of
the resistance of a mineral (not
specifically surface) to
abrasion.
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intensity of reflected light
exhibited by the mineral

Crystal Form/Habit
It is the natural shape of the
mineral before the
development of any cleavage
or fracture.

Cleavage – the property of
some minerals to break along
specific planes of weakness to
form smooth, flat surfaces

Density is the objects’ mass
divided by its volume, usually
in g/cm 3
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Common rock-
forming minerals are
the most abundant
minerals found on
our planet Earth.
Most rocks found on
the surface are
composed of these
minerals.

CHUNK 2: ROCK CLASSIFICATIONS
Rocks are classified on the basis of the mode of formation. The three rock types are igneous,
sedimentary and metamorphic rocks.
1. Igneous rocks - rocks that are formed from the solidification of molten rock material
(magma or lava). Molten rock material can solidify below the surface of the earth
(plutonic igneous rocks) or at the surface of the Earth (volcanic igneous rocks).
Minerals are formed during the crystallization of the magma.
Note that the rate of cooling is one of the most important factors that control crystal
size and the texture of the rock in general.
Igneous rocks are also classified according to silica content: felsic, intermediate, mafic
and ultramafic.
 felsic: also called granitic; >65% silica, generally light-colored
 intermediate: also called andesitic; 55-65% silica; generally medium colored
(medium gray)
 mafic: also called basaltic; 45-55% silica; generally dark colored
 ultramafic: 1cm is called bedding and anything less is called lamination; layering
is the result of a change in grain size and composition; each layer represents a
distinct period of deposition.
 Fossils: remains and traces of plants and animals that are preserved in rocks

Non-clastic / Chemical/Biochemical – derived from sediments that precipitated from
concentrated solutions (e.g. seawater) or from the accumulation of biologic or organic
material (e.g. shells, plant material). They are further classified on the basis of
chemical composition.
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Clastic/terrigenous - form from the accumulation and lithification of sediments derived
from the breakdown of pre-existing rocks. They are further classified according to
dominant grain size.
1. Conglomerate on top left
relatively large and rounded
clasts
as compared to the angular clasts
of the breccia on top right.

2. Sandstone middle left
with visible grains and prominent
layering and claystone on middle
right with several embedded
fossils.

3. Non-clastic sedimentary
rocks limestone on bottom left
and coquina on bottom right.

3. Metamorphic rocks - rocks that form from the transformation of pre-existing rocks
(igneous, sedimentary, or metamorphic rocks) through the process of metamorphism.
Metamorphism can involve changes in the physical and chemical properties of rocks in
response to heat, pressure, and chemically active fluids. They are commonly formed
underneath the earth through metamorphism
Contact metamorphism
 Heat as the main factor: occurs when a pre-existing rocks get in contact with a heat
source (magma)
 Occurs on a relatively small scale: around the vicinity of intruding magma
 Creates non-foliated metamorphic rocks (e.g. hornfels)
Regional metamorphism
 Pressure as main factor: occurs in areas that have undergone deformation during
orogenic event resulting in mountain belts
 Occurs in a regional/large scale

The rock cycle illustrates how geologic processes occurring both at the surface and
underneath the Earth’s surface can change a rock from one type to another.
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CHUNK 3: EXOGENIC PROCESSES

The processes which occur on the earth’s surface due to the influence of exogenic forces are
called exogenic processes or exogenic geomorphic processes.
Weathering, mass wasting, erosion, and deposition are the main exogenic processes. All
the exogenic processes are covered under a general term- denudation, which means strip off
or uncovers.
The elements of nature capable of doing these exogenic processes are termed geomorphic
agents (or exogenic geomorphic agents). E.g. the wind, water, waves etc.

Weathering
occurs as a response to the low pressure, low temperature, and water and oxygenrich
nature of the Earth’s surface.
It is the breaking down or dissolving of rocks and minerals on Earth’s surface.

Categories of weathering:
1. Physical weathering (or mechanical weathering) disintegrates rocks, breaking them
into smaller pieces. The processes that lead to the mechanical disintegration of rocks:
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Frost wedging- when water gets inside the Abrasion – wearing away of rocks by
joints, alternate freezing and thawing constant collision of loose particles

episodes pry the rock apart.

Salt crystal growth- force exerted by salt Biological activity - plants and animals as
crystal that formed as water evaporates from agents of mechanical weathering
pore spaces or cracks in rocks can cause
the
rock to
fall
apart.

Source: https://www.geology.com

2. Chemical weathering decomposes rocks through chemical reactions that change the
original rock-forming minerals. The major processes of chemical weathering are as
follows:
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Dissolution – dissociation of molecules Hydrolysis- change in the composition of
into ions; common example includes minerals when they react with water

dissolution of limestone in water

Oxidation- reaction between minerals
and oxygen dissolved in water

Factors that affect the type, extent, and rate at which weathering takes place:
a. Climate – areas that are cold and dry tend to have slow rates of chemical weathering and
weathering is mostly physical; chemical weathering is most active in areas with high
temperature and rainfall
b. Rock type – the minerals that constitute rocks have different susceptibilities to weathering.
Those that are most stable to surface conditions will be the most resistant to weathering. Thus,
olivine for example which crystallizes at high temperature conditions will weather first than
quartz which crystallizes at lower temperature conditions.
c. Rock structure- rate of weathering is affected by the presence of joints, folds, faults,
bedding planes through which agents of weathering enter a rock mass. Highlyjointed/fractured
rocks disintegrate faster than a solid mass of rock of the same dimension d. Topography-
weathering occurs more quickly on a steep slope than on a gentle one
e. Time- length of exposure to agents of weather determines the degree of weathering of a
rock

Erosion and Deposition
Erosion is the acquisition and transportation of rock debris by geomorphic agents like
running water, the wind, waves etc.
Though weathering aids erosion, it is not a pre-condition for erosion to takes place.
(i.e., erosion can take place in unweathered conditions also)
The deposition is a consequence of erosion. The erosional agents lose their velocity
and energy on gentle slopes and materials carried by them start to settle themselves.
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AGENTS OF EROSION
1. Running water carries
particles called the load.

3. Wind erodes by: deflation (removal
of loose, fine particles from the
surface), and
abrasion

Example: rivers and streams

2. Ocean or Sea Waves can 4. Gravity erodes through mass wasting
break solid rock and throw broken (the downslope movement of soil,
pieces rock, and regolith under the direct
against influence
shore of gravity)

5. Glacier — a moving body of
ice on land that moves
downslope or outward from
an area of accumulation

Mass movements (also called mass-wasting) is the down-slope movement of regolith (loose
uncemented mixture of soil and rock particles that covers the Earth's surface) by the force of
gravity without the aid of a transporting medium such as water, ice, or wind.

Mass movements are classified into:
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Slow movements
Solifluction - the gradual movement of wet soil or other
material down a slope, especially where frozen subsoil
acts as a barrier to the percolation of water.

Rapid movements.
A) EARTHFLOW: B) MUDFLOW: C) DEBRIS AVALANCHE:
The movement of In the absence of It is more in humid regions
watersaturated clayey or silty vegetation and cover and with or without vegetation. It
earth materials down low with heavy rainfall, thick occurs in narrow tracks on
angle terraces or hillsides is layers of weathered steep slopes and is similar to
called earthflow. materials get saturated with snow avalanche.
water and either slow or
rapidly flow down along
definite channels is called
as a mudflow

WEEK 2 ANSWER SHEET (Please submit only the answers. Do not return the entire module.)

Name: ________________________________ Section: _______________________
LAST NAME, FIRST NAME MIDDLE INITIAL

ENGAGEMENT Score: _____/40
Performance Check No. 1: Exogenic Processes in Your Community
Observing your neighborhood is what you are supposed to do. To determine your Purok's
vulnerability to erosion and other exogenic processes that are now taking place in your
neighborhood, write an observation about it and include all necessary information should be
written down.

1. Name of Barangay: ____________________________ (1 pt.)
Municipality: __________________ (1 pt.)
Province: __________________ (1 pt.)
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2. Total Number of Purok in your Barangay? ____________________________ (1 pt.)
Which Purok do you live in? ____________________ (1 pt.)
3. Geographical Location (Latitude and Longitude): _______________________ (1 pt.)
4. Landforms near the Barangay with approximate distance:
______________________________________________________________ (1pt.)
5. Bodies of water near the Barangay with approximate distance:
______________________________________________________________ (1pt.)
Did you observe Effects of exogenic Effects of exogenic
this in your processes on the processes on the
Exogenic Process community? environment? people/citizen?

Yes or No (2 pts) (3 pts) (3 pts)
Weathering
(Physical, Chemical and
Biological Weathering)

Erosion
(Running/ground water,
glaciers, waves & wind)

Mass Movement
(Slow mass and rapid
mass movements)

Deposition
(Running/ground water,
glaciers, waves & wind)

RUA of a Student’s Learning Score: _____/10
Write various strategies and ways that can be implemented to effectively prevent landslides
and ensure the safety of communities. You may write a short essay, poem, slogan or draw a
poster about it (10 pts)
___________________________________________________________________
SIGNATURE OVER PRINTED NAME OF PARENT/GUARDIAN
DATE: _____________________
PRE-REQUISITE ASSESSMENT
What are the 6 layers of the Earth?
Why is the Earth’s core solid if its temperature is so hot?

LEARNING MATERIALS: Module, pen, paper, old earth science books, internet (if applicable)
PRE-REQUISITE CONTENT KNOWLEDGE: Earth’s Layers
PRE-REQUISITE SKILL: Ability to explain the composition and processes in each layer of
the Earth

TIME ALLOTMENT: 4 HRS
CONSULTATION: For inquiries and clarifications regarding the lesson, you may contact your
teacher thru his FB Messenger
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RUA: At the end of the lesson, you should be able to:
describe where the Earth’s internal heat comes from
describe how magma is formed (magmatism)

INSTITUTIONAL VALUES: Environmental Awareness, Excellence, Critical and Analytical
Thinking
Students will be able to apply
a. Excellence in describing the process of magmatism
b. Critical and Analytical thinking skills in explaining the reason where the Earth’s internal
heat came from
c. Environmental awareness on the effect of Earth’s internal heat

OVERVIEW OF THE LESSON
This lesson is all about different exogenic processes including magmatism to explain the
reason for the Earth’s internal heat

STUDENT’S EXPERIENTAL LEARNING

CHUNK 1: HEAT IN THE INTERIOR OF THE EARTH
1. Two categories of the internal heat sources of the Earth:
a. Primordial heat: heat from accretion and bombardment of the Earth during the early stages
of formation. If you hit a hammer on hard surface several times, the metal in the hammer will
heat up (kinetic energy is transformed into heat energy).
b. Radioactive heat (the heat generated by long-term radioactive decay): its main sources
are the four long-lived isotopes (large half-life), namely K40, Th232, U235 and U238 that made
a continuing heat source over geologic time.

2. The estimated internal temperature of the Earth
a. The mantle and asthenosphere are considerably hotter than the lithosphere, and the core is
much hotter than the mantle.
b. Core-mantle boundary: 3,700°C
c. Inner-core – outer-core boundary: 6,300°C ±
800°C
d. Earth’s center: 6,400°C ± 600°C

3. Redistribution of the Earth’s heat:
a. Simultaneous conduction, convection and radiation
b. Convection occurs at the mantle, but not between the core and mantle, or even between
the asthenosphere and lithosphere (except at sea-floor spreading zones).The only heat
transfer mechanism in these transition zones is through conduction.

4. The concept of convection can be explained by comparing it to coffee preparation
a. Mechanisms that occur when boiling water:
i. There is a heat source at the bottom of the water.
ii. The heat rises to the top from the bottom, causing the surface water to become hot. It
radiates its heat into the air and then cools.
iii. The cooler water sinks into the space vacated by the ascending warmer water. This cooler
water starts to warm up, while the water that rises starts to cool.
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iv. The process continues, forming a top-to-bottom circulation of water.

b. Observations after pouring in the coffee (while the water is still hot):
i. The top portion has a relatively lighter color, compared to the lower zone. This represents
the top of a convection cell.
ii. Condensing water vapor marks the top of rising columns of warm water. The dark line
separating them marks the location of sinking cooler water.

CHUNK 2: MAGMA FORMATION

The special conditions required for the formation of magma
Crust and mantle are almost entirely solid, indicating that magma only forms in special
places where pre-existing solid rocks undergo melting.
Melting due to decrease in pressure (decompression melting): The decrease in
pressure affecting a hot mantle rock at a constant temperature permits melting forming
magma. This process of hot mantle rock rising to shallower depths in the Earth occurs
in mantle plumes, beneath rifts and beneath mid-ocean ridges.
Melting as a result of the addition of volatiles (flux melting): When volatiles mix with
hot, dry rock, the volatile decreases the rock’s melting point and they help break the
chemical bonds in the rock to allow melting.
Melting as a result of heat transfer from rising magma (heat transfer melting). A rising
magma from the mantle brings heat with it that can melt the surrounding rocks at the
shallower depths.

WEEK 3 ANSWER SHEET (Please submit only the answers. Do not return the entire module.)

Name: ________________________________ Section: _______________________
LAST NAME, FIRST NAME MIDDLE INITIAL

ENGAGEMENT Score: _____/40
Performance Check No. 2: Chocolate Mantle Convection

Perform the following exploratory activity carefully.
Objective: To illustrate how heat works in the mantle.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
Materials: Pan, Water, Chocolate/ Cocoa Powder, Stove or Candles

Instructions:
I. Put pan on the stove.
II. Put water in the pan. Sprinkle it with chocolate powder until the top is thickly covered
with dry powder.
III. Turn on the stove or light on the candles
IV. Let it boil for a few minutes. Observe what happens.

EXPERIMENT GUIDE QUESTION

a. In the "Chocolate Mantle Convection" experiment. What does the pan, water, chocolate
powder, and heat source represent to the concept of mantle convection? (10 pts)
_________________________________________________________________________
_________________________________________________________________________

b. What are the observable changes that occur during the Chocolate Mantle Convection
experiment, and how do they relate to the movement of tectonic plates? (10 pts)
_________________________________________________________________________
_________________________________________________________________________

c. How does the presence of chocolate powder in the experiment simulate the behavior of
magma in the Earth's mantle? (10 pts)
_________________________________________________________________________
_________________________________________________________________________

d. What will likely to happen to the tectonic plates when the convection of the mantle suddenly
stops due to the absence of heat? (10 pts)
_________________________________________________________________________
_________________________________________________________________________

RUA of a Student’s Learning Score: _____/10
As the time progresses, the amount of coal, oils, and natural gas continue to decrease
worldwide. Different organizations and government officials seek for alternative energy
resources to produce electricity.

Is there a possibility or ways to convert earth’s internal heat into electricity? How are we able
to utilize it? You may write a short essay, poem, slogan or draw a poster about it (10 pts)

___________________________________________________________________
SIGNATURE OVER PRINTED NAME OF PARENT/GUARDIAN
DATE: _____________________
PRE-REQUISITE ASSESSMENT
1. What causes metamorphism of rocks?
2. Which of the following can undergo metamorphism; igneous or sedimentary rocks?
Why?

LEARNING MATERIALS: Module, pen, paper, old earth science books, internet (if applicable)
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
PRE-REQUISITE CONTENT KNOWLEDGE: Rock Cycle
PRE-REQUISITE SKILL: Ability to explain how rock transforms from one classification to
another

TIME ALLOTMENT: 4 HRS
CONSULTATION: For inquiries and clarifications regarding the lesson, you may contact your
teacher thru his FB Messenger

RUA: At the end of the lesson, you should be able to:
Describe the physical and chemical changes in rocks due to changes in pressure and
temperature (metamorphism)
Compare and contrast the formation of the different types of igneous rocks

INSTITUTIONAL VALUES: Environmental Awareness, Excellence, Critical and Analytical
Thinking
Students will be able to apply
a. Excellence in describing the process of metamorphism
b. Critical and Analytical thinking skills in classifying types of igneous rocks
c. Environmental awareness on the effect of rock cycle to the environment

OVERVIEW OF THE LESSON
This lesson is all about different processes involving in rock cycle like metamorphism,
volcanism and plutonism
STUDENT’S EXPERIENTIAL LEARNING

CHUNK 1: METAMORPHISM

Metamorphism is the recrystallization of minerals in rocks due to a change in pressure and
temperature conditions.
The word "Metamorphism" comes from the Greek: meta = after, morph = form, so
metamorphism means the after form. In geology this refers to the changes in mineral
assemblage and texture that result from subjecting a rock to pressures and temperatures
different from those under which the rock originally formed.
The original rock that has undergone metamorphism is called the protolith.
During metamorphism the protolith undergoes changes in texture of the rock and the
mineral makeup of the rock. These changes take place mostly in the solid state and are
caused by changes in physical or chemical conditions, which in turn can be caused by such
things as burial, tectonic stress, heating by magma or interactions with fluids.

Factors that Control Metamorphism
Metamorphism occurs because rocks undergo changes in temperature and pressure
and may be subjected to differential stress and hydrothermal fluids.
Metamorphism occurs because some minerals are stable only under certain conditions
of pressure and temperature. When pressure and temperature change, chemical
reactions occur to cause the minerals in the rock to change to an assemblage that is
stable at the new pressure and temperature conditions.

Factors that control the mineral composition of a metamorphic rock
attained temperature
pressure
the bulk composition of the precursor rock and
the composition of fluid present during metamorphism.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
Metamorphic grade pertains to the temperature and/or pressure condition(s) to which a rock
has been subjected during metamorphism.

Image source: http://www.geologyin.com/

Fossils may be found in metamorphic rocks especially in low-grade metamorphic rocks. The
fossils however are expected to be not in the original form due to the effect of the change in
temperature and pressure.

Textural Changes in Rocks that are Subjected to Metamorphism
1. Grain Size
In general, the grain size of metamorphic rocks tends to increase with the increasing
metamorphic grade. With the increasing metamorphic grade, the sheet silicates
become unstable and mafic minerals like hornblende and pyroxene start to grow. At
the highest grades of metamorphism all of the hydrous minerals and sheet silicates
become unstable and thus there are few minerals present that would show a preferred
orientation.
Grain size Classification
fine, medium, coarse-grained = these modifiers are useful for all metamorphic rocks
except slates and phyllites, where a fine grain size is implied by the name. Grain
sizes are, for fine-grained < 0.75 mm, for medium grained 0.75-1 mm, for
coarsegrained 1-2 mm and very coarse-grained > 2 mm.
There is a direct correlation between the grain size of metamorphic rocks and the
metamorphic grade.

2. Foliation
It is the pervasive planar structure that results from the nearly parallel alignment of
sheet silicate minerals and/or compositional and mineralogical layering in the rock.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024

Image source: https://www.thinglink.com/
a. Differential stress is formed when the pressure applied to a rock at depth is not
equal in all directions. Effects of differential stress in the rock’s texture if present during
metamorphism include Rounded grains can become flattened in the direction of the
maximum compressional stress.
b. Minerals that crystallize or grow in the differential stress field may develop a
preferred orientation. Sheet silicates and minerals that have an elongated habit will
grow with their sheets or direction of elongation orientated perpendicular to the
direction of maximum stress.

Non-foliated metamorphic rock is formed when heat is the main agent of
metamorphism. Generally, non-foliated rocks are composed of a mosaic of roughly
equidimensional and equi-granular minerals.
Non-foliated metamorphic rocks are generally of two types: those made up of mainly
one mineral like quartzite (from medium to high-grade metamorphism of quartz-rich
sandstone) and marble (from low to high-grade metamorphism of limestone or
dolostone), and those in which the different mineral grains are too small for the naked
eye, such as hornfels (hornfels if the grain size is small and granulite if the grain size
is large).

CHUNK 2: IGNEOUS ROCKS
Where (and why) do igneous rocks form?
Rocks melt when the temperatures, pressures, and/or water content are sufficient to bring the
rock to the melting temperature.
This occurs:

when rocks have been brought up from deeper in the mantle for example at a RIDGE
rocks with water in them are brought from the surface down into the mantle, for
example at a SUBDUCTION ZONE, or there is some "HOT SPOT" arising from deep
in the mantle unrelated to a plate boundary. About 90% of all melting occurs at plate
boundaries (spreading or subducting). The rest is called "intra-plate".
When a partial melt forms, it rises and collects in a magma chamber. In the magma chamber,
the melt continues to crystallize thus changing its chemistry. This is a process known as
magmatic differentiation. As magmas cool, different minerals will crystallize out of the melt.
By studying the crystallization of melts in the laboratory, this process is fairly well understood.
If these minerals settle out of the melt to the floor of the magma chamber, the chemistry of the
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
remaining melt changes from a more mafic to a more felsic melt; thus, if fractional
crystallization is taken to the extreme granite can be gotten from what was originally a basaltic
melt.
The magma chamber may erupt from time
to time.

If the melt does not make it to the surface, it
forms an intrusive rock. Intrusive bodies
can be big balloon shapes (plutons),
subhorizontal slabs (sills) or sub-vertical
walls (dikes).

If it does make it, it becomes an extrusive
rock. Extrusives can flow out over the
ground (lava flows) or be blasted into the
air to form ash falls and pyroclasts

Types of Igneous Rocks

Extrusive igneous rocks erupt onto the Intrusive igneous rocks crystallize below
surface, where they cool quickly to form Earth's surface, and the slow cooling that
small crystals. Some cool so quickly that occurs there allows large crystals to form.
they form an amorphous glass. These Examples of intrusive igneous rocks are
rocks include andesite, basalt, dacite, diorite, gabbro, granite, pegmatite, and
obsidian, pumice, rhyolite, scoria,

and tuff.

peridotite.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024

WEEK 4 ANSWER SHEET (Please submit only the answers. Do not return the entire module.)

Name: ________________________________ Section: _______________________
LAST NAME, FIRST NAME MIDDLE INITIAL

ENGAGEMENT Score: ___/20
Enabling Assessment Activity No. 2: Igneous Rocks
Using table below, identify the name and the classification of rocks whether it is intrusive
igneous rock or extrusive igneous rock based on the description provided.
Name of the Classification
Igneous Rocks Igneous Rock (Intrusive and Extrusive)

1. A fine-grained, igneous rocks that are
usually light to dark gray in color.
2. A black or dark green in color and
composed mainly of the plagioclase.

3. An igneous rock that is normally light in
color and it is often porphyritic.

4. An igneous rock that forms during the
final stage of a crystallization.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
5. A dark-colored, ultramafic igneous
rocks that is usually contain olivine

6. A dark-colored, fine-grained, igneous
rock composed mainly of plagioclase.

7. A light-colored igneous rock composed
of feldspars and quartz.

8. A coarse-grained igneous rock with a
composition of granite and basalt.

9. A dark-colored igneous rock with
abundant round bubble-like cavities.

10. An igneous rock that forms a natural
glass by the rapid cooling of lava.

RUA of a Student’s Learning Score: ___/10
Explain why there is an abundant and lush vegetation underneath or near a volcano. You may
write a short essay, poem, slogan or draw a poster (10 pts)

___________________________________________________________________
SIGNATURE OVER PRINTED NAME OF PARENT/GUARDIAN
DATE: _____________________
PRE-REQUISITE ASSESSMENT
What would the ocean floor look like if we drain away all the seawater? What
is Continental Drift Theory?

LEARNING MATERIALS: Module, pen, paper, old earth science books, internet (if applicable)
PRE-REQUISITE CONTENT KNOWLEDGE: Continental and Oceanic Crust
PRE-REQUISITE SKILL: Ability to explain how rock transforms from one classification to
another

TIME ALLOTMENT: 4 HRS
CONSULTATION: For inquiries and clarifications regarding the lesson, you may contact your
teacher thru his FB Messenger

RUA: At the end of the lesson, you should be able to:
Explain how the movement of plates leads to the formation of folds and faults
Describe how layers of rocks (stratified rocks) are formed
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
INSTITUTIONAL VALUES: Environmental Awareness, Excellence, Critical and Analytical
Thinking
Students will be able to apply
a. Excellence in describing the process involved in plate tectonics
b. Critical and analytical thinking skills analyzing different rock layers
c. Environmental awareness on the effect moving tectonic plates

OVERVIEW OF THE LESSON
This lesson is all about plate tectonics, folding, faulting and stratification of rocks

STUDENT’S EXPERIENTIAL LEARNING

CHUNK 1: PLATE BOUNDARIES

Theory of Plate Tectonics
1. Main principles Plate Tectonics
The Earth’s outermost rigid layer (lithosphere) is broken into discrete plates each
moving more or less as a unit.
Driven by mantle convection, the lithospheric plates ride over the soft, ductile
asthenosphere.
Different types of relative motion and different types of lithospheres at plate boundaries
create a distinctive set of geologic features.
2. Concept of lithospheric plate
a. The lithosphere consists of the crust and the uppermost mantle.
Average thickness of continental lithosphere :150 km
Average thickness of old oceanic lithosphere: 100 km
b. Composition of both continental and oceanic crusts affect their respective densities.
c. The lithosphere floats on a soft, plastic layer called asthenosphere.
d. Most plates contain both oceanic and continental crust; a few contain only oceanic
crust.
e. A plate is not the same as a continent.

Types of Plate Boundaries:
1. Convergent boundaries: where two plates are colliding.
Subduction zones occur when one or both of the tectonic plates are composed of oceanic
crust. The denser plate is subducted underneath the less dense plate. The plate being forced
under is eventually melted and destroyed.

i. Where oceanic crust meets ocean crust
Island arcs and oceanic trenches occur when both of the plates are made of oceanic crust.
Zones of active seafloor spreading can also occur behind the island arc, known as back-arc
basins. These are often associated with submarine volcanoes. ii. Where oceanic crust
meets continental crust
The denser oceanic plate is subducted, often forming a mountain range on the continent.
The Andes is an example of this type of collision.
iii. Where continental crust meets continental crust
Both continental crusts are too light to subduct so a continent-continent collision occurs,
creating especially large mountain ranges. The most spectacular example of this is the
Himalayas.

2. Divergent boundaries – where two plates are moving apart.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
The space created can also fill with new crustal material sourced from molten magma that
forms below. Divergent boundaries can form within continents but will eventually open up
and become ocean basins.
i. On land
Divergent boundaries within continents initially produce rifts, which produce rift valleys.

ii. Under the sea
The most active divergent plate boundaries are between oceanic plates and are often
called mid-oceanic ridges.

3. Transform boundaries – where plates slide passed each other.
The relative motion of the plates is horizontal. They can occur underwater or on land, and crust
is neither destroyed nor created.

Because of friction, the plates cannot simply glide past each other. Rather, stress builds up
in both plates and when it exceeds the threshold of the rocks, the energy is released –
causing earthquakes.

CHUNK 2: FOLDING AND FAULTING

What Happens When Rock Layers Bend?
Folding happens when rock layers bend under stress. Folding causes rock layers to look bent
or buckled. The bends are called folds. Most rock layers start out as horizontal layers.
Therefore, when scientists see a fold, they know that deformation has happened.

TYPES OF FOLDS
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
Three of the most
common types of folds
are synclines, anticlines,
and monoclines.
In a syncline, the
oldest rocks are found
on the outside of the
fold. Most synclines
are Ushaped.
In an anticline, the
youngest rocks are
found on the outside
of the fold. Most
anticlines are shaped.
In a monocline, rock
layers are folded so
that both ends of the
fold are horizontal.
The figure below
shows these kinds of
folds.

What Happens When Rock Layers Break?
When rock is put under so much stress that it can no longer bend, it may break. The crack
that forms when rocks break and move past each other is called a fault. The blocks of rock
that are on either side of the fault are called fault blocks. When fault blocks move suddenly,
they can cause earthquakes

HANGING WALL AND FOOTWALL
When a fault forms at an angle, one fault block is called the hanging wall and the other is
called the footwall. The figure below shows the difference between the hanging wall and the
footwall.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
NORMAL FAULTS
In a normal fault, the hanging wall moves
down, or the footwall moves up, or both.
Normal faults form when rock is under
tension. Tension is stress that pulls rock
apart. Therefore, normal faults are common
along divergent boundaries, where Earth’s
crust stretches.

REVERSE FAULTS
In a reverse fault, the hanging wall moves
up, or the footwall moves down, or both.
Reverse faults form when rock is under
compression. Compression is stress that
pushes rock together. Therefore, reverse
faults are common at convergent
boundaries, where plates collide.

STRIKE-SLIP FAULTS
In a strike-slip fault, the fault blocks move
past each other horizontally. Strike-slip
faults form when rock is under shear stress.
Shear stress is stress that pushes different
parts of the rock in different directions.
Therefore, strike-slip faults are common
along transform boundaries, where tectonic
plates slide past each other.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024

WEEK 5 ANSWER SHEET (Please submit only the answers. Do not return the entire module.)

Name: ________________________________ Section: _______________________
LAST NAME, FIRST NAME MIDDLE INITIAL

ENGAGEMENT Score: _____/20
Enabling Assessment Activity No. 3: Deformation of The Earth’s Crust
Fill all the blank spaces in the table to describe the three main types of plate tectonic, its
definition, corresponding fault type, and the kind of stress acted in the faults.

Name of the Plate Description of the Type of Fault Type of Stress
Boundary Plate Boundary Present Present
(1 pt.) (2 pts.) (1 pt.) (1 pt.)

1. Explain how plate tectonic contribute to the Earth's geological processes and the creation
of the seven continents from the super continent called “Pangaea” (5 pts.)
_________________________________________________________________________
_________________________________________________________________________
_________________________________________________________________________

RUA of Student’s Learning Score: _____/10
Since the Philippine archipelago belongs to the Pacific Ring of Fire or Circum-Pacific Belt,
discuss the impacts of Ring of Fire in relation to seismic activities to the people, economy,
and the physical environment of the country. You may write a short essay, poem, slogan or
draw a poster (10 pts)
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CDLB – EARTH AND LIFE SCIENCES 2023-2024

___________________________________________________________________
SIGNATURE OVER PRINTED NAME OF PARENT/GUARDIAN
DATE: _____________________
PRE-REQUISITE ASSESSMENT
How are layers of rocks formed?
How does deposition contribute to the formation of rock layers?

LEARNING MATERIALS: Module, pen, paper, old earth science books, internet (if applicable)
PRE-REQUISITE CONTENT KNOWLEDGE: Stratification, Sedimentary deposition PRE-
REQUISITE SKILL: Ability to recognize how strata is formed

TIME ALLOTMENT: 4 HRS
CONSULTATION: For inquiries and clarifications regarding the lesson, you may contact your
teacher thru his FB Messenger

RUA
At the end of the lesson, you should be able to:
Describe the different methods (relative and absolute dating) to determine the age of
stratified rocks
Explain how relative and absolute dating were used to determine the subdivisions of
geologic time
Describe how the Earth’s history can be interpreted from the geologic time scale

INSTITUTIONAL VALUES: Environmental Awareness, Excellence, Critical and Analytical
Thinking
Students will be able to apply
Excellence in acknowledging the difference of relative and absolute dating
Critical and Analytical thinking skills determining the type of dating to be used
Environmental awareness on how surface of the Earth changes thru time

OVERVIEW OF THE LESSON
This lesson is all about the History Of the Earth’s Surface, including the interpretation of
geologic time scale, and using technologies such as absolute and relative dating in
determining the age of the Earth

STUDENTS’ EXPERIENTIAL LEARNING

CHUNK 1: STRATIFICATION

Stratification is the layering process of rocks.
Rock layers are also called strata (the plural form of the Latin word stratum).
Stratigraphy is the science of strata. it deals with all the characteristics of layered rocks; it
includes the study of how these rocks relate to time.
Most rocks are sedimentary rocks which are formed from older rocks that have been broken
down by water or wind. The older rocks become sedimentary particles such as gravel, sand,
and mud. These particles can also bury dead plants and animals.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
Gravel becomes
conglomerate.

Sand becomes
sandstone;

Mud becomes shale or
mudstone.

The animals or plants
buried with them
become fossils.

As time goes by, the particles accumulate, and those that are at the bottom of the pile become
rocks. These series of events form the different layers of rocks.
Age of the Earth
The Earth has a very long history — 4.6 billions of years of history.
The age of the Earth is based from the radioactive isotopic dating of meteorites.
The oldest dated rock from the Earth is only ~3.8 billion years old.

Rocks and Fossils
The history of the Earth is recorded in rocks but the rock record is inherently incomplete.
Some of the "events" do not leave a record or are not preserved. Some of the rock record
may have also been lost through the recycling of rocks (Recall the rock cycle)
Preserved in rocks are the remains and traces of plants and animals that have lived and
died through-out Earth's History — fossils. The fossil record provides scientists with one of
the most compelling evidence for Charles Darwin's Theory of Evolution. (increasing
complexity of life through time).

Methods to Determine the Age of Stratified Rocks
There are two methods of determining the ages of rocks: relative dating and absolute dating.
1. Relative dating
is a method of arranging geological events based on the rock sequence.
cannot provide actual numerical dates of rocks and only tells that one rock is older than
the other but does not tell how old each of the rock is
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
Principles of Relative Dating
a) The law of superposition states that, in any sequence of layered sedimentary rocks,
the top layer is younger than the bottom layer. It is important in the interpretation of the
Earth's history because it indicates the relative age of the rock layers and fossils.
b) The law of original horizontality states that most sediments were originally laid down
horizontally. However, many layered rocks are no longer horizontal. Based on the law
of original horizontality, the rocks that were tilted may be due to later events such as
tilting episodes of mountain building.
c) The law of lateral continuity states that rock layers extend laterally or out to the sides.
These layers may cover broad surfaces. Erosion may have worn away some parts of
the rock, but the layers on either side of the eroded areas still match.
d) The law of cross-cutting relationship states that fault lines and igneous rocks are
younger features that cut through older features of rocks.

2. Absolute dating
is a method that gives an actual date of the rock or period of an event.
is a method used to determine the age of rocks by measuring its radioactive decay A
radioactive isotope in the rock decays into a stable daughter isotope. The decay
occurs at a predictable rate, so the age of the sample could be determined.
Examples
a) Radiocarbon dating for organic remains could date up to 60 000 years.
b) K-Ar dating and U-Pb dating for volcanic rocks could date up to five billion years.

CHUNK 2: GEOLOGIC TIME SCALE

The geologic time scale shows the geologic time intervals based on the geologic rock
records, which describe the relationships between the events that happened throughout the
Earth’s history. The sequence of events is based on the radiometric dating of igneous rocks
associated with the fossil-bearing sedimentary rocks.

A geologic time scale is revised as more fossil-bearing sedimentary rocks are dated. It is
calibrated by integrating results from relative and absolute dating. Below is an example of how
geologic time scale is calibrated.
 Raw data composed of strata or layers are reviewed.
 The unique succession of events in the layers is recognized based on the laws of
relative dating leading to a chronological order of events.
 Numerical or absolute age of the events is given using absolute dating or radiometric
methods. Absolute dating provides the age for the ash layers while relative dating
provides at least six strata with relative ages – first and last occurrences of the fossils
and the volcanic eruption events.

The Geologic Time Scale – the time line of the History of the Earth, is based from the rock
record.
Geologic time is subdivided into hierarchal intervals, the largest being Eon, followed by Era,
Period, and Epoch, respectively. Subdivision of Geologic time is based from significant
events in the Earth’s History as interpreted from the rock record.
The mass extinction event which leads to the extinction of the dinosaurs occurred around
66.4 million years ago marks the boundary between the Mesozoic Era (Age of the Reptiles)
and the Cenozoic Era (Age of Mammals). This mass extinction event may have been pivotal
in the rise in dominance of the mammals during the Cenozoic Era.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
DIVISIONS OF TIME INTERVAL DURATION % of Geologic
GEOLOGIC TIME (in millions of (in millions of Time
years) years)
Cenozoic Era 66.4 - present 66.4 1.46
Mesozoic Era 245 - 66.4 178.6 3.93
Paleozoic Era 570 - 245 325 7.14
Pre- Cambrian
Proterozoic 2500 - 570 1930 42.42
Archean 3800 - 2500 1300 28.57
Hadean 4550 - 3800 750 16.48

WEEK 6 ANSWER SHEET (Please submit only the answers. Do not return the entire module.)

Name: ________________________________ Section: _______________________
LAST NAME, FIRST NAME MIDDLE INITIAL

ENGAGEMENT Score: _____/25
Enabling Assessment Activity No. 4: Geologic Time Scales
Listed in the first column are different eon with respective era and period. Indicate 2 species
of animals/plants living for each period.

EON ERA PERIOD SPECIES

1.
Quaternary
2.
Cenozoic
P 1.
Tertiary
H 2.
A 1.
N Cretaceous
2.
E
1.
R Mesozoic Jurassic
2.
O
Z 1.
Triassic
O 2.
I 1.
Permian
C 2.
Paleozoic
1.
Carboniferous
2.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
1.
Devonian
2.
1.
Silurian
2.
1.
Ordovician
2.
1.
Cambrian
2.
Also known 1.
as Proterozoic
2.
PreCambrian Pre-Cambrian
Archean 1.

RUA of Student’s Learning Score: _____/5
Explain the importance of the geologic time scale in understanding Earth's history and the
significance of fossil discoveries in reconstructing past environments and life forms. You may
write a short essay, poem, slogan or draw a poster (5 pts)

___________________________________________________________________
SIGNATURE OVER PRINTED NAME OF PARENT/GUARDIAN
DATE: _____________________

PRE-REQUISITE ASSESSMENT
How safe is the Philippines from Natural Hazards?
Why is the Philippines prone to earthquakes and volcanic eruptions?

(SEISMIC) AND MASS MOVEMENT
LEARNING MATERIALS: Module, pen, paper, old earth science books, internet (if applicable)
PRE-REQUISITE CONTENT KNOWLEDGE: Natural Geologic Hazards
PRE-REQUISITE SKILL: Ability to distinguish effects of different geologic hazards

TIME ALLOTMENT: 4 HRS
CONSULTATION: For inquiries and clarifications regarding the lesson, you may contact your
teacher thru his FB Messenger (Chard Pascua or Levin Salud) or thru email
([email protected]) ([email protected])

RUA: At the end of the lesson, you should be able to:
Describe the various hazards that may happen in the event of earthquakes, volcanic
eruptions, and landslides
Using hazard maps, identify areas prone to hazards brought about by earthquakes,
volcanic eruptions, and landslides
Identify human activities that speed up or trigger landslides

INSTITUTIONAL VALUES: Environmental Awareness, Excellence, Critical and Analytical
Thinking
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
Students will be able to apply
Excellence in acknowledging the different effect of geologic hazards
Critical and Analytical thinking skills using hazard map
Environmental awareness on the effect of human activities that triggers different
hazards

OVERVIEW OF THE LESSON
This lesson is all about the Geologic hazards like earthquake, volcanic eruption and landslides,
as well as the possible effect of these hazards

STUDENT’S EXPERIENTIAL LEARNING

CHUNK 1: NATURAL HAZARDS

Natural hazards are those resulting from an adverse interaction between a natural process
and human society or its man-made environment.

Natural hazards that may be faced by a community are dictated largely by the climate,
geography, geology, and land use practices of that community. Natural hazards are further
defined by the following categories:

1. Tectonic (Seismic) Hazards – These hazards are associated with the movement of
the Earth's tectonic plates. They include:
o earthquakes, o
volcanoes, and o
tsunamis.
2. Mass-Movement Hazards – These are hazards associated with rapid gravity-induced
downward debris movements, or by the non-seismic expansion or subsidence of the
Earth. Mass-movement hazards include: o debris movements such as
landslides, rock falls, debris flows, and avalanches, o land subsidence such as
sinkholes, and o soil expansion.
3. Hydrologic Hazards – These hazards are characterized by a severe excess or lack
of water, including:
o floods, o drought,
o desertification, o
coastal erosion, and o
soil erosion.
4. Meteorological Hazards – These are hazards related to atmospheric patterns or
conditions and are generally caused by weather factors such as precipitation,
temperature, wind speed, and humidity. Meteorological hazards include: o tropical
cyclones such as hurricanes, typhoons, and cyclones, o monsoons, o tornadoes, o
waterspouts, o ice storms, o severe winter storms, o hailstorms, o frost,
o extreme cold or
heat, o
windstorms, o
sandstorms, o
wildfires, o
thunderstorms, o
fog, o El Niño /
La Niña, and o
climate change.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
5. Biological / Health-Related Hazards – These are hazards that cause or are related
to disease of plants, animals, and humans. Biological hazards include: o human,
animal (livestock), and plant (agricultural) epidemics, and o other unique natural
hazards that do not fit neatly into a single category, such as meteors, poisoning, and
salination.

CHUNK 2: GEOLOGIC HAZARDS

Earthquake
An earthquake is a shaking of the ground caused by sudden slippage of rock masses
below or at the surface of the earth. It is a wavelike movement of the earth’s surface.
An earthquake may be classified as either tectonic or volcanic.
In certain cases, earthquakes can result from man-made activities such as detonation
of explosives, deep mining activities, etc. However, these earthquakes are mild and
may be felt only as tremors.
Magnitude measures the energy released Intensity measures the strength of shaking
at the source of the earthquake. produced by the earthquake at a certain
Magnitude is determined from location. Intensity is determined from
measurements on seismographs. Uses effects on people, human structures, and
Ritcher Magnitude Scale the natural environment
Uses Modified Mercalli Intensity Scale

A very severe earthquake is usually associated with shocks called foreshocks and
aftershocks.
 Foreshocks are a series of tremors that occur before the main earthquake.
 Aftershocks are weaker earthquakes follow the main shocks and can cause
further that damage to weakened buildings.
Since 1968, PHIVOLCS has recorded twelve destructive earthquakes in the
Philippines. This record includes the infamous July 16,1990 Luzon earthquake which
caused innumerable injuries and at least 1,100 deaths. Seismicity (geographic and
historical distribution of earthquake events) is all over the country except in the
Palawan region.
The top ten provinces that are at
risk to earthquakes are:
1. Surigao Del Sur
2. La Union
3. Benguet
4. Pangasinan
5. Pampanga
6. Tarlac
7. Ifugao
8. Davao Oriental
9. Nueva Vizcaya
10. Nueva Ecija
1990 Luzon Earthquake
IMAGE Wikimedia Commons

Tsunamis
are giant sea waves generated by earthquakes and volcanic eruptions under the
seabed. Not all submarine earthquakes, however, cause tsunamis.
Tsunamis can only occur when the earthquake is strong enough (M7.0+) to displace
the seabed, creating pressures in the water above it.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
Other sources of tsunamis include submarine or coastal landslides, pyroclastic flow
and large volume debris avalanches from oceanic and partly submerged volcanoes,
and caldera collapse.
Although tsunamis may be triggered in various ways, their effects on the coastal areas
are similar. The large waves of a tsunami are preceded by initial lowering of the water
level even beyond the lowest tidal levels. This phenomenon resembles the low tides
which may have led to tsunamis being falsely called “tidal waves”.
Tsunamis generated in distant locations will generally give people enough time to move
to higher ground.
For locally-generated tsunamis, where you might feel the ground shake, you may only
have a few minutes to move to higher ground.
Most of the coastal areas have experienced a tsunami or have a tsunami hazard
potential.
The top ten provinces that are at
risk to tsunamis are:
1. Sulu
2. Tawi-tawi
3. Basilan
4. Batanes
5. Guimaras
6. Romblons
7. Siquijor
8. Surigao del Norte
9. Camiguin
10. Masbate Image source: https://www.thequint.com

Volcanic Eruption
a process wherein volcanic materials such as molten or hot fragmented rocks or
gaseous materials are ejected from a volcano
Hazards from volcanoes may be of different nature. These hazards include flowing of
fast-moving molten rocks and other ejecta. The ejected fragments range in size from
fine dust (volcanic ash) to large boulders (volcanic bombs or blocks).
Besides liquid and solid materials, volcanoes give off poisonous gases, sometimes in
superheated gas jets.
Other hazards associated with volcanic eruption are earthquakes, fissuring caused by
the force of upward-moving magma, tsunami and water displacement, subsidence due
to retreat or withdrawal of magma, landslides due to too much bulging on one side of
the volcano or those triggered by earthquakes or rainfall.
The Philippines lies within the Ring of Fire, a region of subduction zone volcanism
surrounding the Pacific Ocean. This explains the distribution of most volcanoes in the
Philippines. In 1991, Mt. Pinatubo eruption was well known to be the most violent
eruption in the 20th century. Philippine Volcanoes are classified as Active, Inactive and
Potentially active. Twenty-two (22) historically active volcanoes are distributed all over
the archipelago.
Since volcanoes are not present in some provinces, these particular areas have no
risk to volcanic eruptions.
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
The top ten provinces at risk are:
1. Camiguin
2. Sulu
3. Biliran
4. Albay
5. Bataan
6. Sorsogon
7. South Cotabato
8. Laguna
9. Camarines Sur
10. Batanes
Taal Volcano Eruption 2020
https://electroverse.net/

Landslide
A landslide is a massive outward and downward movement of slope-forming materials.
The term landslide is restricted to movements of rocks and soil masses. These masses
may range in size up to entire mountainsides. Their movements may vary in velocity.
A landslide is initiated when a section of a hill slope or sloping section of a sea bed is
rendered too weak to support its own weight.
This is generally triggered by other natural hazards such as prolonged, heavy rainfall
or by other sources of water which increase the water content of the slope materials.
Landslide as a geological hazard is caused by earthquake or volcanic eruption.
Susceptibility of hill slope to landslide is developed as a result of denudation of
mountainsides which removes the trees or ground cover that holds the soil, or
alteration of the surface of the ground like grading for roads or building constructions.
Most of the provinces, except Palawan, are susceptible to landslide hazards.
The top ten provinces that are at
risk to earthquake-induced
shallow landslides are:
1. Ifugao
2. Lanao Del Sur
3. Sarangani
4. Benguet
5. Mountain Province
6. Bukidnon
7. Aurora
8. Davao del Sur
9. Davao Oriental
10. Rizal 1999 Cherry Hill Landslide
FILE PHOTO BY ROMEO
GACAD/AFP
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WEEK 7 ANSWER SHEET (Please submit only the answers. Do not return the entire module.)

Name: ________________________________ Section: _______________________
LAST NAME, FIRST NAME MIDDLE INITIAL

ENGAGEMENT Score: _____/30
Performance Check No. 3: Seismic and Volcanic Hazard Preparedness
An earthquake can happen anytime and anywhere. It is important that every building has their
own emergency evacuation plan in case of the occurrences of an earthquake. Your task for
this lesson is to create an emergency evacuation plan of the school.

Objective: To develop an understanding of emergency preparedness and create an effective
evacuation plan for your school.

Materials:
Paper or poster board
Markers, colored pencils, or crayons
Ruler

Notes:
1. You may observe or tour the entire school premises, during your free time to visualize
every corner and facilities that the school have. DO NOT ENTER FACILITIES UNLESS
AUTHORIZED.
2. The output should be a scaled-down representation of the school layout on the paper
or poster board. It should include important features such as classrooms, hallways,
exits, stairwells, and other relevant locations.
3. Also consider obstacles like locked doors, blocked hallways, or damaged areas that
may impede evacuation routes, designated meeting points outside the school, the
location of fire extinguishers, first aid kits, or emergency equipment.
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RUA of Student’s Learning Score: _____/20
Understanding how to respond to any hazard is one way to safety. Accomplish the activity
below by writing what are the action that you should do BEFORE, DURING, AND AFTER a
volcanic eruption. You may write a short essay, poem, slogan or draw a poster

HAZARD WHAT ACTIONS SHOULD YOU DO?

BEFORE DURING AFTER

Volcanic
Eruption

___________________________________________________________________
SIGNATURE OVER PRINTED NAME OF PARENT/GUARDIAN
DATE: _____________________
PRE-REQUISITE ASSESSMENT
1. Why is the Philippines prone to strong typhoons?
2. Which province is more prone to typhoons and why?

TYPHOONS
LEARNING MATERIALS: Module, pen, paper, old earth science books, internet (if applicable)
PRE-REQUISITE CONTENT KNOWLEDGE: Natural Hydrometeorological Hazards PRE-
REQUISITE SKILL: Ability to distinguish effects of different hydrometeorological hazards

TIME ALLOTMENT: 4 HRS
CONSULTATION: For inquiries and clarifications regarding the lesson, you may contact your
teacher thru his FB Messenger
RUA: At the end of the lesson, you should be able to:
Using hazard maps, identify areas prone to hazards brought about by tropical cyclones,
monsoons, floods, or ipo-ipo
Describe how coastal processes result in coastal erosion, submersion, and saltwater
intrusion
Cite ways to prevent or mitigate the impact of land development, waste disposal
and construction of structures on control coastal processes

INSTITUTIONAL VALUES: Environmental Awareness, Excellence, Critical and Analytical
Thinking
Students will be able to apply
Excellence in acknowledging the different effect of hydrometeorological hazards
Critical and Analytical thinking skills using hazard map
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CDLB – EARTH AND LIFE SCIENCES 2023-2024
Environmental awareness on the effect of human activities that triggers different
hazards

OVERVIEW OF THE LESSON
This lesson is all about the hydrometerological hazards like typhoon, tornado, flood, storm
surge and coastal processes as well as some possible effects of these hazards to society

STUDENT’S EXPERIENTIAL LEARNING
CHUNK 1: HYDROMETEOROLOGICAL HAZARDS
Cyclone
A cyclone is an intense low-pressure system which is characterized by
strong spiral winds towards the center, called the “Eye” in a counter-
clockwise flow in the northern hemisphere. Hazards due to tropical cyclones
are strong winds with heavy rainfall that can cause widespread
flooding/flashfloods, storm surges, landslides and mudflows.
Classification o Tropical Depression – maximum winds from 35 kph to 63
kph o Tropical Storm – maximum winds from 64 kph to 118 kph o Typhoons
– maximum winds exceeding 118 kph

Typhoon
A typhoon is a large, powerful and violent tropical cyclone. It is a low-pressure area
rotating counterclockwise and containing rising warm air that forms over warm water
in the Western Pacific Ocean.
Less powerful tropical cyclones are called Tropical Depressions and Tropical Storms.
A typhoon is called a hurricane in the Atlantic Ocean, a cyclone in the Indian Ocean
and wily-wily in Australia. Typhoons can inflict terrible damage due to thunderstorms,
violent winds, torrential rain, floods, landslides, large and very big waves associated
with storm surges.
Hurricane-force winds can reach out as little as 40 km from the center of a small
hurricane and as far as 240 km in a large hurricane. Tropical storm-force winds can
extend as far as 480 km from the center of a large hurricane. These are very dangerous
storms.

The Modified Public Storm Warning Signals (PSWS) in the Philippines
 PSWS 1 Winds of 30-60 kph may be expected in at least 36 hours or intermittent rains
may be expected within 36 hours. (When the tropical cyclone develops very close to
the locality, a shorter lead of time of the occurrence of the winds will be specified in the
warning bulletin)
 PSWS 2 Winds of greater than 60 kph and up to 120 kph may be expected in at least
24 hours.
 PSWS 3 Winds greater than 120 kph up to 170 kph may be expected in at least 18
hours.
 PSWS 4 Very strong winds greater than 170 kph up to 220 kph may be expected in at
least 12 hours.
 PSWS 5 Very strong winds of mo