Big Ban.-ES Unit 1-01.pdf

Full Transcript

Unit 1
The Origin of the Universe and the
Solar System
Table of Contents

Table of Contents 1

Introduction 3

Essential Questions 4

Review 4

Lesson 1.1: Big Bang Theory 5
Objectives 5
Warm-Up 5
Learn about It 7
Key Points 11
Web Links 12
Check Your Understanding 12
Challenge Yourself 13

Lesson 1.2: Steady State Theory and Oscillating Universe Theory 15
Objectives 15
Warm-Up 16
Learn about It 17
Key Points 21
Web Links 21
Check Your Understanding 22
Challenge Yourself 23

Lesson 1.3: Nebular Theory 24
Objectives 24
Warm-Up 24
Learn about It 27
Key Points 31
Web Links 32
 Check Your Understanding 32
Challenge Yourself 34

Lesson 1.4: Encounter Theory 35
Objectives 35
Warm-Up 35
Learn about It 36
Key Points 38
Web Links 39
Check Your Understanding 39
Challenge Yourself 40

Laboratory Activity 41

Performance Task 42

Self Check 44

Key Words 44

Wrap Up 46

Photo Credits 46

References 47

2
EARTH SCIENCE | GRADE 11/12

Unit 1
The Origin of the
Universe and the Solar
System

Do you have little siblings, nephew, or niece at home? Have you noticed that these
kids are very curious about the things around them? They have too many questions
such as why is the sky blue, why do stars seem to twinkle, why are plants green,
who made us, why do I need to sleep early, why aren’t there any more dinosaurs,
why do people have varying features and so many more. These endless questions
are so tiring to answer. You end up saying, "It is just because things work that way."
How about if they started to ask you how the universe began, how would you
answer? How can you explain to a kid the origin of the universe in a 'nutshell'?

3
 Essential Questions

At the end of this unit, you should be able to answer the following questions.

What are the possible explanations of the origin of the universe?
How do the proponents of different theories come up with their ideas of the
origin of the universe?
Are the theories widely accepted?

Review

When a wave (either a sound wave or electromagnetic wave) travels between
two objects, the wavelength seems to change if one or both of them are
moving.
○ The Doppler effect is the change in the wavelength (or frequency) of a
wave when there is a motion that increases or decreases the distance
between the receiver and the source.
○ Redshift occurs when electromagnetic waves shift to longer
wavelengths (shift towards the red end of the spectrum when the
source of the waves is moving away from the observer).
In 1916, Albert Einstein proposed the theory of general relativity describing
the concept of space-time as a fabric that can be stretched (a concept
originated by Hermann Minkowski in 1908).
○ The concept of redshift describes that as space-time stretches, any
photon that travels in space also stretches, increasing its wavelength.
Therefore, the photons that travel from far away galaxies are
stretched more, making larger redshifts as compared to photons from
nearby galaxies.

4
 Lesson 1.1: Big Bang Theory

Objectives
In this lesson, you should be able to:
explain the origin of the universe according to the big bang
theory;
identify different proponents that support the big bang theory;
and
enumerate the negative implications of the big bang theory.

Have you ever wondered how the universe began? Don’t worry, you are not alone.
Most people seek to find the answer to this question. The good thing is, scientists
are working hard to find accurate answers to these questions. There are various
theories trying to explain the origin of the universe. The most common is the big
bang theory. How did the big bang theory explain the origin of the universe?

Warm-Up
Big Bang Balloon Activity

Materials:
balloon
permanent marker
string
ruler
clothespin

Procedure:
1. Partially inflate the balloon. Use the clothespin to clip the end so that the air
will not escape.
2. Using a permanent marker, draw six widely spaced dots on the balloon.

5
 Label one dot "H" which indicates home and the other dots A to E.
3. Since the balloon is curved, a string could be used first to measure the
distance from "H" to each dot. Then, use a ruler to measure the length of the
string. Record each distance on the initial measurement column on the table
provided.
4. Remove the clothespin. Then, inflate the balloon again to make it bigger.
5. Observe what happens to the dots. Repeat step 3 but record the distances
on the Trial 1 column on the table provided.
6. Repeat steps 4 and 5 two more times. Record your measurements under
Trial 2 and 3 column.

Data and Results:
Distances (cm)
Location
H to A H to B H to C H to D H to E

Initial
measurement

Trial 1

Trial 2

Trial 3

Guide Questions:
1. As the balloon gets bigger, what happens to the distances from the "H" dot to
the other dots?
2. What dot(s) move(s) the farthest? Is it the dot near the "H" or the dot farther
from "H"?
3. If the dots correspond to groups of stars and the balloons represent the
universe, how will you explain the concept of expanding universe?

6
 Learn about It

The big bang theory is a cosmological model explaining how the universe began. It
suggests that the universe started its expansion about 13.8 billion years ago.

Overview of the Big Bang Theory
Some might think of the concept of the big bang as an explosion of something
leading to the creation of the universe. However, the idea of the big bang theory is
somewhat similar to the bread-raisin model. The bread is compared to the universe
while the raisins are the galaxies. As shown in Fig. 1, the raisin does not expand. It
only moves apart as the dough rises.

Fig. 1. The raisin-bread model of expanding universe.

The bread-raisin model is similar to the universe. As shown in Fig. 2, the galaxies,
represented by dots, are not expanding. Distances in relation to other galaxies just
increase because of the expanding universe.

Fig. 2. In the big bang theory, matter dilutes as the universe expands.

7
The big bang theory suggests that the universe started as a “singularity”—an area
predicted to be in the core of a black hole with very high temperature and density.
The nature of the singularity is still a mystery to many scientists, but they stated
that this singularity constantly expands and cools. The rate of expansion is almost
equal to the rate of cooling. The intense heat led to the formation of matter and
antimatter particles that were destroyed every time they collided with each other.

Nucleosynthesis is the formation of elements, such as hydrogen and helium. The
presence of these elements led to the formation of the stars and the galaxies. The
presence of the stars led to the formation of other cosmic bodies such as planets,
comets, and asteroids.

Fig. 3. Nucleosynthesis of helium.

Proponents of the Big Bang Theory
There are different proponents who suggested an explanation of this expanding
universe. They are Georges Henri Joseph Edouard Lemaître, Edwin Powell Hubble,
Arno Penzias, and Robert Wilson.

8
Georges Henri Joseph Edouard Lemaître
Georges Henri Joseph Edouard Lemaître, a Belgian
priest, suggested the idea of the expanding universe.
He is considered the first proponent of the big bang
theory.

In 1931, during the British Association meeting, he
explained that the universe originated in an
explosive act of primeval atom or the ‘Cosmic egg’
which was like a huge atomic nucleus. The immense
energy from the explosion of this primeval atom was
sufficient to initiate the expansion of the universe.
However, his theory was not recognized by most
cosmologists since it was not supported by empirical
evidence at that time.

Lemaître thought that if the universe came from a hot state, it would leave traces
that can be subjected to analysis. He then realized that there were indeed traces in
the form of cosmic rays. He explained that the cosmic rays were “ashes and smoke
of bright but very rapid fireworks,” and they originated when the primeval atom
disintegrated. He first visualized that the primeval atom would disintegrate into
atomic stars. Then as the atomic stars disintegrate, they would produce cosmic rays
and become ordinary matter. Therefore, cosmic rays were not the direct product of
primeval atom but rather, of the early formation of the stars 10 billion years ago.

In his publication, he stated that “Cosmic rays would
be glimpses of the primeval fireworks of the formation
of a star from an atom, coming to us after their long
journey through free space.”

Edwin Powell Hubble
Edwin Powell Hubble was an American astronomer
who established the Hubble’s law which provided
evidence that the universe was not static but
expanding. In 1923, Hubble spotted what he thought
as a flaring nova star in the M31 nebula or the
Andromeda constellation using a Hooker telescope.
The Andromeda constellation is now known as
Andromeda galaxy, the nearest galaxy in the Milky
Way.

9
 Fig. 4. The Hooker telescope (left) and the Cepheid star (right).

Hubble carefully studied the photographic plates captured by other astronomers
and realized that what he saw was a Cepheid star ― a star that pulsates radially,
brightening and dimming periodically. Hubble used this radial pulse to measure the
distance of the star from Earth. Based on his calculations, he was able to postulate
the existence of other galaxies. He noted that there was more to the universe
beyond the Milky Way.

He then began to classify other nebulae,
measuring their velocities based on their
emitted spectral lights. Then in 1929, he
noticed that all the galaxies seemed to be
moving away from Earth with velocities that
increased in proportion to their distance. This
means that the amount of redshift is
proportional to the distance of the galaxy, i.e.
nearby galaxies have smaller redshifts than
distant galaxies. This relationship of the
velocities of distant objects in the universe in
proportion to their distance from Earth is
called Hubble’s law. He published a report in
the same year about his discovery. This ultimately supported Lemaître’s proposal of
the expanding universe.

10
Arno Penzias and Robert Wilson
American astronomers, Arno Penzias, and Robert Wilson studied the cosmic
radiation in 1964. They discovered that microwaves with wavelengths of about 7
centimeters were present in space. These waves were referred to as the cosmic
microwave background (CMB) radiation.

Arno Penzias Robert Wilson
(born 1933) (born 1941)

CMB radiation is believed to be the thermal energy released when the ionized gases
became neutral particles as the early universe cooled down. This radiation served
as a ‘leftover’ when the universe was formed. The discovery of this cosmic radiation
provided strong evidence that the universe began from the sudden expansion of a
singularity, which supported Lemaître’s study.

Drawbacks of the Big Bang Theory
One of the problems in the big bang theory is that it failed to explain how the
universe was created. It just explains how it evolves and not where it originated. In
addition, this theory also failed to explain how the galaxies formed.

Key Points

The big bang theory suggests that the universe started as a “singularity”—
an area predicted to be in the core of a black hole with very high

11
 temperature and density.
There are different proponents who suggested an explanation of this
expanding universe. They are Georges Henri Joseph Edouard Lemaître,
Edwin Powell Hubble, Arno Penzias, and Robert Wilson.
Hubble’s law states that the relationship of the velocities of distant objects
in the universe is directly proportional to their distance from Earth.
The big bang theory failed to explain how the universe was created.

Web Links

For further information, you can check the following web links:
Watch this video clip from National Geographic to deepen your
knowledge on the big bang theory
National Geographic. 2009. ‘Before Time and Space.’
https://www.youtube.com/watch?v=nVsHjnY-o9s

Try this interactive activity to have an idea of how big is the
universe.
Primax Studio. n.d.. ‘Scale of the Universe.’
http://scaleofuniverse.com

Listen to this big bang song to remember the idea of big bang
theory better.
Barenaked Ladies. 2016. ‘The Big Bang Theory Song.’
https://www.youtube.com/watch?v=CMSYv_Z4SI8

Check Your Understanding

A. Identify the proponent of the theory that explains the following statements.
1. He used the radial pulse of Cepheid star to measure the distance of the star
from Earth.
2. He stated that the amount of redshift is proportional to the distance of the
galaxy.
3. He concluded that the relationship of the velocities of distant objects in the

12
 universe is in proportion to their distance from Earth.
4. He explained that the cosmic rays were “ashes and smoke of bright but very
rapid fireworks,” and they originated when the primeval atom disintegrated.
5. He discovered cosmic microwave background radiation.
6. He used the Hooker telescope to support his idea.
7. He discovered that microwaves with wavelengths of about 7 centimeters
were present in space.
8. He studied the photographic plates captured by other astronomers and
realized that what he saw was a Cepheid star.
9. He is considered the first proponent of the big bang theory.
10. He proposed that the universe originated in an explosive act of primeval
atom or the ‘cosmic egg'.

B. Use the data provided in the table below to answer the following.
Distance
0.45 0.9 0.9 1.7 2.0 2.0 2.0
(Mpc)

Velocity
200 650 500 960 850 800 1090
(km/s)

1. Plot a graph based on the data given on the table above.
2. Calculate the range of distances to the galaxies (in light years) in the given
sample. Take note that one megaparsec (Mpc) is equal to 3.26 million light
years.
3. According to the data, are the distances and speeds of the galaxies
correlated, anti-correlated or unrelated?
4. What can you conclude about the galaxy that is very far away from Earth?
5. How can you summarize the Hubble's law by using the data provided?

Challenge Yourself

Answer the following questions. Limit your answer in 2 to 3 sentences.
1. Why is the bread-raisin model compared to the big bang theory?
2. How will you explain the big bang theory by relating it to mass, volume, and
density?

13
3. Who are the proponents of the big bang theory? What are their ideas that
support the big bang theory?
4. How do the velocities of distant objects and distance from Earth related to
Hubble’s law?
5. What is nucleosynthesis? Describe how nucleosynthesis leads to the
formation of stars and galaxies.

14
 Lesson 1.2: Steady State Theory and
Oscillating Universe Theory

Objectives
In this lesson, you should be able to:
explain the origin and the fate of the universe according to
steady state theory and oscillating universe theory;
identify different proponents of the steady state and oscillating
universe theory; and
enumerate negative implications of steady state and oscillating
universe theory.

Do you usually go to the grocery store with your mom? If you do, you should have
noticed that grocery stores love promos. They usually asked you to buy a thing in
packages. For instance, if plastic containers are on sale, it is usually sold in a
package of 3 to 5 pieces with varying sizes. At a glance, you know that the bigger
size of the plastic containers will be heavier to carry. If you don’t want your packed
lunch to add weight on your bag especially if you carry a lot of other things, you will
not ask your mom to use the bigger Tupperware for your packed lunch. However,
choosing a smaller container means less food can fit inside. This is a problem
especially if you want to eat more because you need more energy to accomplish
tasks in school.

In these situations, you could conclude that mass and volume is directly
proportional. As the plastic container increase in volume, it gets heavier as well.
How about the container’s density? Does it change as the object increases in size?
How could this mass, volume, and density relate to a theory of the origin of
the solar system called steady state theory?

15
 Warm-Up
Bar of Soap - A Model of an Expanding Universe

Materials:
square shaped bath soap (or any square-shaped object that can be sliced)
plastic knife
weighing balance
ruler
clean cloth

Procedure:
1. Slice the square-shaped bath soap twice lengthwise and twice crosswise to
form 9 equal pieces.
2. Get one slice of the soap and measure its side using a ruler.
3. Calculate the volume of a piece of soap by multiplying the length by width by
height (l × w × h). Record the calculated volume of the soap.
4. Put the one slice of soap on a clean cloth first before putting on the weighing
balance. Record its weight.
5. Calculate the density by dividing its mass by volume. Record.
6. Repeat steps 2 to 5 but this time using four slices of soap.
7. Repeat steps 2 to 5 but this time using nine slices of soap.

Guide Questions:
1. What is the relationship between mass, volume, and density in the
experiment?
2. What can you say about the density of the soap as the number of slices
increases?
3. Relate this activity with this statement: "The density of the universe remains
constant as it continuously expands while simultaneously creating matter".

16
 Learn about It

The Steady State Theory
The steady state theory is another theory that tries to explain the origin of the
universe. As opposed to the big bang, this theory states that the universe has no
beginning and no end.

Overview of the Steady State Theory
The steady state theory suggests that the universe has always been here and will
always be present. It also suggests that the universe always looks the same in any
time or space, but the universe continuously expands while simultaneously creating
matter. During expansion, the density of the universe remains constant; hence, the
name steady state. It also explains that the rate of the death of stars is equal to
the rate of birth of stars. Hence, as a whole, the universe is not evolving over
time.

Both the big bang and steady state theory explains that the universe is expanding.
However, the difference is that the big bang shows that as the universe expands,
the density of matter decreases over time. On the other hand, steady state shows
that the universe maintains a constant density as it expands. This means that
matter such as stars and galaxies are continuously being added to the universe. Fig.
6 illustrates the primary concept of the steady state theory.

Fig. 6. In the steady state theory, matter is constantly created as the universe
expands.

17
Proponents of the Steady State Theory
The steady state theory was proposed by Hermann Bondi, Thomas Gold, and Fred
Hoyle in 1948. These three physicists from Cambridge released the idea of the
steady state theory by submitting two papers to Monthly Notices of the Royal
Astronomical Society, one from Bondi and Gold, and the other one from Hoyle.

Hermann Bondi Thomas Gold Fred Hoyle
(1919–2005) (1920–2004) (1915–2001)

The steady state idea of Bondi and Gold may have started when they watched a
movie together late 1940s. It was a horror movie entitled “Dead of Night” which
started and ended in the same way. The circular plot of the movie inspired them to
suggest that the universe was dynamic but unchanging. This means that the
universe is constantly changing yet remains the same. Some criticism arose since
the theory did not explain how matter could be generated out of nothing.

18
Drawbacks of the Steady State Theory
The steady state theory was so simple that it was widely accepted even before the
proposal of the big bang theory. Other astronomers did not favor this theory since
it is not parallel with the law of conservation of energy and mass where energy and
matter cannot be created nor destroyed but can only change their form.

The discovery of the cosmic microwave background radiation significantly
supported the explanations given by the big bang theory and led many scientists to
reject the steady state theory in 1965. The steady state theory explained that the
cosmic radiation was a result of a supernova. However, after thorough research, it
was proven that the radiation is equal in any direction of the universe and could not
be a result of many supernovae.

The Oscillating Universe Theory
Have you ever wondered how many universes are there? Or is our universe the
only one? If the oscillating theory holds true, our universe might be the first of the
probable series of the universe or nth universe in the series.

The oscillating universe theory discusses that the universe is expanding and will
contract once all the energy after the big bang has been used up, only to expand
again once it approaches the point of singularity (i.e., the beginning of a new
universe). It is also referred to as the pulsating theory.

Overview of the Oscillating Universe
Theory
The oscillating universe theory can
be described as the combination
of the big bang and the big crunch.
The big crunch occurs when the
universe expands and eventually
reverses, then collapses causing
the formation of a singularity or
the occurrence of another big
bang. The oscillating universe
theory suggests that once the
universe reverses and attains
the point of singularity, another
universe will be born. This is
referred to as the big bounce.

19
Richard Tolman, an American mathematical physicist,
and physical chemist theorized that the universe may
be first in the cycle, or it could be a result of a
previous big bounce event.

Proponent of Oscillating Universe Theory
Besides being a mathematical physicist and physical
chemist, Richard Tolman was someone to look up to
when it comes to statistical mechanics. He later
became physical chemistry and mathematical physics
professor at California Institute of Technology
(Caltech). One of his students is Linus Pauling to
whom he taught the pre-Schrödinger quantum
theory.

In the years after Einstein discovered the general relativity, Tolman made essential
contributions to theoretical cosmology. In his monograph entitled, “Relativity,
Thermodynamics, and Cosmology”, he documented and explained that the
universe has zero energy because the positive mass energy and negative
gravitational energy cancel each other. His theory on the oscillating universe caught
attention to struggles regarding entropy and resulted in its demise.

Drawbacks of Oscillating Universe Theory
Like the steady state theory, scientists discovered many loopholes in the oscillating
universe theory. This theory suggested that the universe would collapse on its own
after it reached its full expansion, which would violate some current laws of physics,
such as the postulated existence of dark energy. The dark energy is believed to be
the driving force of the accelerating expansion of the universe.

At present, the postulated end of the universe is by big freeze or heat death. The
universe would continuously expand until it reaches a point wherein all its energy
dissipates.

20
 Key Points

The steady state theory suggests that the universe has always been here
and will always be present.
○ It was proposed by Hermann Bondi, Thomas Gold, and Fred Hoyle in
1948.
The oscillating universe theory discusses that the universe is expanding
and will contract once all the energy after the big bang has been used up,
only to expand again once it approaches the point of singularity
○ It is also referred to as the pulsating theory.
○ Richard Tolman is the proponent of oscillating universe theory.

Web Links

For further information, you can check the following web links:

Watch this video to study the difference between the big bang
theory and steady state theory.
Pichael Moon. 2014. ‘Big Bang Theory vs Steady State Theory.’
https://www.youtube.com/watch?v=SuslgoGJdiw&t=21s

Watch this video to know more about the steady state theory.
The Audiopedia. 2018. ‘What is the Steady State Theory?.’
https://www.youtube.com/watch?v=hsMerhcEcEM

21
 Check Your Understanding

A. Write S if the statement describes the steady state theory or O if it describes
oscillating universe theory.
1. Other astronomers did not favor this theory since it did not follow the law of
conservation of energy and mass
2. It states that our universe might be the first of the probable series of the
universe or nth universe in the series.
3. During expansion, the density of the universe remains constant.
4. It suggests that the universe has always been here and will always be
present.
5. The universe is not evolving over time.
6. It discusses that the universe is expanding and will contract once all the
energy after the big bang has been used up, only to expand again once it
approaches the point of singularity.
7. The universe continuously expands while simultaneously creating matter.
8. This theory can be described as the combination of the big bang and the big
crunch.
9. This theory suggests that once the universe reverses and attains the point of
singularity, another universe will be born.
10. It explains that the rate of the death of stars is equal to the rate of birth of
stars.

B. Draw a Venn diagram.
Write two unique
features of the steady
state theory on the first
outer circle and two
unique features of the
oscillating universe
theory on the second
outer circle. Then, write
at least one similar
feature in the inner
circle.

22
 Challenge Yourself

Answer the following questions. Limit your answers in 2 to 3 sentences.
1. Why is the steady state theory termed as such?
2. What are the similarities and differences of the big bang theory and steady
state theory?
3. Based on the steady state theory, how can the universe expand but
maintained a constant density?
4. What makes the steady state theory unacceptable?
5. Why is the oscillating universe called such?

23
 Lesson 1.3: Nebular Theory

Objectives
In this lesson, you should be able to:
explain the origin of the solar system according to the nebular
theory;
describe how planets were formed based on the nebular theory;
be familiar with the contribution of the proponent that support
the nebular theory; and
enumerate the negative implications of the nebular theory.

Did you spend most of your childhood playing? It is undeniable that most kids love
to play. One of the most common things that kids want to do with their playmates
is playing with toy building bricks or molding clay. Most of the time, kids compete
with their playmate in building better toy building bricks or clay structure.

Both of these situations, building using toy bricks or molding clay, involves creating
a larger structure out of the smaller parts. For instance, one toy building brick when
combined with other blocks can form a robot or a building. The same is true in
molding clay. A small amount of clay can make a certain object when extra clay is
added. One theory regarding the origin of the universe also works this way. How
can smaller structures become a huge matter such as planets?

Warm-Up

Modeling Accretion

Materials:
student role cards
○ interstellar dust card (red for metallic grains, blue for icy grains, and
yellow for rocky grains)

24
 ○ planetesimal card
○ protoplanet card

Procedure:
1. Distribute the different interstellar dust card (metallic, icy, and rocky) evenly
among the students. Make sure every student will have one interstellar dust
card (A larger area is needed to do this activity because the students need to
move around to tag other students).
2. Assign one student to stand in the middle of the circle of students. This
represents the sun.

First Round
3. The goal of the game is to tag other students with the same role card as
theirs. They cannot tag other students with a different type of role card. For
example, a student with a metallic grains card can only tag other students
with the same role card. They cannot tag students with icy or rocky grains
card.
4. Before the game will start, keep these reminders in mind. First, students
should move in a counterclockwise circular path around the sun. One

25
 student will act as the sun in the middle. Second, students should only jog as
they move around. They are not allowed to run. Third, the arms should only
stay at the sides as the students jog around.
5. Start tagging other students. If you are tagged, you should move together
with the person who tagged you.
6. After several minutes, students should stop tagging others.
7. The winner of this round is the group who formed the largest clumps.

Second Round
8. Students formed in clumps can now tag other students in clumps as well.
However, only those with the same role card can be tagged and grouped.
9. After several minutes, students should stop tagging others.
10. The winner of this round is the group who formed the largest clumps.
11. Give each clump of interstellar dust another card with planetesimal written
on it. Students in this stage simulated the first stage of solar system
formation.

Third Round
12. Each planetesimal can now tag other planetesimals with different role card.
For example, a planetesimal consisting of a group of metallic grains can now
tag planetesimals consisting of rocky or icy grains.
13. The final winner is the one with the largest group.
14. Hand out a protoplanet role card to the planetesimal group with different
interstellar dust.

Guide Questions:
1. What happens in the interstellar dust in the first round of the activity?
2. What is the difference between interstellar dust, planetesimals, and
protoplanets in the activity?
3. What are the differences between the first stage and second stage of planet
formation which is represented by the second and third round respectively?
4. How is the activity related to how planets were formed?

26
 Learn about It

Another theory that explained the origin of the solar system is the nebular theory.
From the term itself, "nebula" means cloud. This indicates that stars originate from
interstellar gas and dust. The shift from undifferentiated cloud to whole solar
system formation complete with planets, moons, and stars takes approximately a
hundred million years.

Description of the Nebular Theory
There are three major steps on how the solar system was formed according to
nebular theory. These are cloud collapse, formation of the protoplanetary disk, and
growth of planets.

Cloud Collapse
The origin of the planets and sun in the solar system is a huge cloud of molecular
gas and dust. Then, something occurred that made the cloud to collapse. Possible
reasons are shockwaves from a supernova or the effect of a passing star. Whatever
the reason, the result was a collapse at the center of the cloud due to gravity. As
shown in Fig. 8, the collapsing of the cloud makes it spin faster.

Fig. 8. Cloud collapse.

27
Have you ever tried to watch a skating competition? One of the tricks of the
contestant that amazes people is when they spin so fast without falling. If you are a
keen observer, they can only do the trick if they bring in their arms. Extending their
arms while attempting to spin fast will result to a failure of the act. As shown in
Fig. 9, this is possible because rotational velocity is inversely proportional to radius.

Fig. 9. Relationship of radius and rotational velocity.

In relation to the nebular theory, the collapsed cloud of interstellar gas and dust
results to a smaller radius which means it will spin faster. This resulted to a
flattened disk of cloud with a central bulge.

Formation of Protoplanetary Disk
Metals and silicates could exist near the sun because these compounds have higher
boiling points. As a result, terrestrial planets including Mercury, Venus, Earth, and
Mars were eventually formed containing a high concentration of these compounds.

28
The terrestrial planets could not grow in huge diameter because of the limited
reserve of metallic elements in the solar nebula.

Fig. 10. Terrestrial planets. From left to right: Mercury, Venus, Earth, and Mars.

Jovian planets composed of Jupiter, Saturn, Uranus, and Neptune are huge planets
made up of gases without land surfaces. These planets were formed farther from
the sun because the temperature is cool enough for the gases to condense,
forming these massive, but low-density planets.

Fig. 11. Jovian planets. From left to right: Jupiter, Saturn, Uranus, and Neptune.

29
 Fig. 12. The formation of a protoplanetary disk in nebular theory.

Growth of Planets
As shown in Fig. 13, dust and grains surrounding the sun eventually formed clumps.
These clumps then accreted forming planetesimals. Planetesimal is a small
celestial body that once collide together, it tends to fuse to form the planets of the
solar system.

Fig. 13. Growth of planets in the nebular theory.

30
Proponents of the Nebular Theory
The nebular theory can be credited to Emanuel Swedenborg, Immanuel Kant,
and Pierre-Simon Laplace.

Emmanuel Swedenborg Immanuel Kant Pierre-Simon Laplace
(1688–172) (1724–1804) (1749–1827)

Drawbacks of the Nebular Theory
One problem of the nebular theory is that it assumes that dust particles will be
attached to each other forming a planet. However, this is not true for Saturn
because the particles surrounding it repel each other. Another problem is that it
does not follow the law of angular momentum. If it does, the sun should be
spinning at a higher rate than the others. Moreover, this theory did not consider
Uranus and Venus, which rotates in a clockwise direction. This is opposing to the
counterclockwise rotation of other planets. If this theory is correct, all the planets
should be moving in the same direction.

Key Points

Nebula means cloud. This indicates that stars originate from interstellar gas
and dust.
There are three major steps on how the solar system is formed according to
nebular theory. These are cloud collapse, formation of the protoplanetary
disk, and growth of planets.

31
 Terrestrial planets include Mercury, Venus, Earth, and Mars. These would
eventually form closer to the sun.
Jovian planets composed of Jupiter, Saturn, Uranus, and Neptune are huge
planets made up of gases without land surfaces. These planets were formed
farther from the sun.
The nebular theory can be credited to Swedenborg, Kant, and Laplace.

Web Links

For further information, you can check the following web links:

Click this link to deepen your knowledge on the nebular theory.
OHMS Science Class Videos. 2014. ‘The Nebular Theory.’
https://www.youtube.com/watch?v=PL3YNQK960Y

Listen to this short lecture to make the nebular theory clear to
you.
London Jenks. 2014. ‘Nebular Hypothesis - Formation of the Solar System’
https://www.youtube.com/watch?v=y7eXbIPSYes

Check Your Understanding

A. Arrange the following events of the nebular theory in order by writing numbers
1 to 5 on the blank provided below.
__________ Protoplanets and moon forming

__________ Solar system

__________ Protosun forming

__________ Formation of the nebula

__________ Spinning planetary disk

32
B. Complete the following flowchart. Choose the letter of the correct answer in the
choices below.
A. Interstellar cloud (nebula) F. Accretion
B. Protoplanetary disk G. Terrestrial planets
C. Protosun H. Jovian planets
D. Sun I. Asteroids
E. Gases, ice J. Comets

33
 Challenge Yourself

Answer the following questions. Limit your answers in 2 to 3 sentences.
1. How does the dust cloud become a planet?
2. Why did the interstellar gas and dust collapse?
3. Why did the nebula spin faster as they shrink or collapse?
4. What is the difference between inner and outer protoplanets?
5. What should be the composition of the materials in the core, mantle, and
crust based on the nebular theory?

34
 Lesson 1.4: Encounter Theory

Objectives
In this lesson, you should be able to:
explain the origin of the solar system based on the encounter
theory;
differentiate the planetesimal and tidal theory;
be familiar with the proponents of the planetesimal and tidal
theory; and
enumerate the negative implications of the planetesimal and
tidal theory.

Warm-Up
Planet Formation

Material:
electronic gadget with an internet connection

Procedure:
1. Click this link to watch a one-minute video clip on how dust traps aid in
forming the planets.

How does planet formation happen?
Tech Insider. 2017. ‘Scientists have found how Planet Formation Occurs.’
https://www.youtube.com/watch?v=aeNixsYTdB4

2. Take down important notes while watching the video.
3. Answer the guide questions below.

35
Guide Questions:
1. What happens when two objects bump into each other too fast?
2. Give at least two characteristics of a dust trap.
3. What is the importance of dust traps?

Learn about It

The encounter theory proposes that the planets were formed from the material
ejected from the sun during an encounter with another celestial object. This
celestial object could have been another star. The encounter theory has several
forms, including the planetesimal theory and the tidal theory.

Fig. 14. The encounter theory proposes that the planets formed from the material
ejected from the sun during an encounter with another star.

The Planetesimal Theory
According to the planetesimal theory, a passing star termed as intruding star
nearly collided with the protosun. The massive gravitational pull of the intruding
star causes the protosun to eject filaments of material. These materials condensed
into planetesimals from which the planets were formed through accretion. Unlike
the nebular theory which describes Earth starting from molten mass, the
planetesimal theory describes Earth starting from a solid mass smaller than its
present size. The oceans and the atmosphere were formed on Earth through
volcanic activities.

36
Proponents of the Planetesimal Theory
The planetesimal theory was proposed by an American geologist, Thomas
Chrowder Chamberlin and an American astronomer, Forest Ray Moulton in 1905.
Moulton started working with Chamberlin when he took graduate studies in
Chicago. As opposed to what Kelvin proposed on the age of Earth, Chamberlin
realized that Earth was older. He proposed that accretion of minute solid particles
created planets and their moons rather than by gaseous or liquid material
condensation. However, Moulton provides mathematical calculations to
Chamberlin’s idea making it into a solid theory.

Thomas Chrowder Chamberlin Forest Ray Moulton
(1843–1928) (1843–1928)

Drawbacks of the Planetesimal Theory
This theory is no longer accepted today due to the fact that hot material from the
sun expands and dissipates rather than contract. In addition, the force from the
passing star will pull dust and gases far away from the sun, that they would not be
able to form the planets in the solar system.

The Tidal Theory
The tidal theory explains that the solar system formed as a result of a near
collision between a passing star and the sun. However, unlike the planetesimal
theory, the tidal theory proposes that the hot gas from the passing star condensed
into planets instead of condensing into planetesimals. When the star passed near

37
the sun, the gravitational attraction pulled the mass of dust and gas from the
remaining nebula around the sun. The gas particles then condensed into liquid and
solid states. The particles clump together to form cosmic bodies of different sizes.
These bodies further condensed into planets. Therefore, the interaction from the
gravity of the passing star and the sun led to the formation of the planets in the
solar system. The materials closer to the sun are denser. This explains the positions
of the terrestrial planets near the sun. In contrast, the materials from the passing
star are less dense; thus, explaining the positions of the Jovian planets.

Proponents of the Tidal Theory
The tidal theory was proposed by James Jeans, an English physicist, and
astronomer, and Harold Jeffreys, an English mathematician, and astronomer in
1918.

Drawbacks of the Tidal Theory
One problem of the tidal theory is that the hot material from either star cannot
contract. Thus, planets will not form.

Key Points

The encounter theory proposes that the planets formed from the material
ejected from the sun during an encounter with another celestial object. It has
several forms, including the planetesimal theory and the tidal theory.
The planetesimal theory describes Earth starting from a solid mass smaller
than its present size.
○ It was proposed by an American geologist Thomas Chrowder
Chamberlin and an American astronomer Forest Ray Moulton.
○ It is no longer accepted today due to the fact that hot material from
the sun will expand and dissipate rather than contract.

38
 The tidal theory proposes that the hot gas from the passing star condensed
into planets instead of condensing into planetesimals.
○ It was proposed by James Jeans, an English physicist, and astronomer,
and Harold Jeffreys, an English mathematician, and astronomer.
○ One problem of the tidal theory is that the hot material from either
star cannot contract. Thus, planets will not form.

Web Links

For further information, you can check the following web links:
Watch this video to make the difference of the planetesimal
theory and nebular theory clear to you.
Daniel Gaies. 2014. ‘Planetesimal Theory versus Nebular Theory’
https://www.youtube.com/watch?v=12PkSkgo_mU

View this video to help you visualize what is the planetesimal
theory talking about
Rose Ann Antonio. 2013. ‘Planetesimal Theory’
https://www.youtube.com/watch?v=Ct-BMiK7NSE

Check Your Understanding

Arrange the following events in order. Write numbers 1 to 5.

Planetesimal theory
__________ Materials ejected from the protosun condensed into
planetesimals.

__________ The oceans and the atmosphere were formed on Earth through
volcanic activities.

__________ The planets formed by accretion.

__________ The protosun ejects filaments of materials.

__________ An intruding star nearly collided with a protosun.

39
 Tidal theory
__________ These bodies further condensed into planets.

__________ The gravitational attraction pulled the mass of dust and gas from
the remaining nebula around the sun.

__________ The particles clumped to form cosmic bodies of different sizes.

__________ The gas particles then condensed into liquid and solid states.

__________ A star passed near the sun.

Challenge Yourself

Answer the following questions. Limit your answers in 2 to 3 sentences.
1. Why is the encounter theory called such?
2. What is the difference between the nebular theory and planetesimal theory?
3. Why is the planetesimal theory no longer accepted today?
4. What is the difference between planetesimal and tidal theory?
5. Is the tidal theory widely accepted? Why or why not?

40
 Laboratory Activity

Activity 1.1
Dust in the Universe

Objectives
At the end of this laboratory activity, the students should be able to:
investigate different properties of dust;
relate the features of dust collected to its location; and
identify how astronomers investigate dust in space.

Materials and Equipment
clear tape
clean short bond paper
magnifying glass
ruler

Procedure
1. Choose five locations around the classroom or school where you will collect
dust samples.
2. Use the sticky side of the clear tape to get dust samples on your chosen area.
3. Sort out the dust samples by their physical features (size, shape, and color).
Put the sorted clear tape with dust samples on a separate sheet of paper.
4. List the properties of the dust groups that you formed. Record your
observations.
5. Record your observation on the characteristics of each location where you
find your dust samples.
6. Use a ruler and magnifying glass to measure the size of the dust samples.
Record your observation.

Waste Disposal
Put the wastes in the appropriate trash bins.

41
Data and Results

Table 1. Description of dust samples in five locations.

Description Description of the Dust Samples Collected
Location of the Area Size Shape Color

Location A

Location B

Location C

Location D

Location E

Guide Questions
1. Do you think there is a relationship between the kind of dust samples
collected to the location where it is found? Explain.
2. What is the range of sizes of the dust samples that you collected?
3. What do you think will be the largest size that will qualify as dust?
4. How do astronomers investigate dust in space based on your dust
investigation activity?

Performance Task

Infographics on the Origin of the Universe and Solar System

Goal
Your task is to make an infographic that shows illustration and information
on the origin of the universe and solar system. Choose only one theory.

Role
You have been asked to become a graphic designer and Earth Science expert.

Audience

42
 Your target audience is Grades 7 to 12 students.

Situation
You need to have accurate information and related illustration in your
infographics.

Product
You will create an infographic to spread awareness to other students in an
interesting and creative way.
Your product needs to be simple, creative and accurate.

Standards
Your work must meet the standards found in the rubric below.

Below Needs Successful Exemplary
Criteria Expectations, Improvement Performance Performance
0% to 49% 50% to 74% 75% to 99% 100%

Accuracy Most information is Most information Most All the
correct. With three is correct. With information is information in
or more inaccurate two inaccurate correct. With the
fact. facts. one inaccurate infographics
fact. are correct

Layout and Does not meet any Has met only 1 of Has met only 2 Met all of the
of the criteria given. the criteria given. of the criteria following
Neatness
given. criteria:
- text is
relevant to the
photo.
- has a catchy,
relevant title.
- overall output
is neat.

Overall output The overall output The overall The overall The overall
needs to be creative output is creative output is output is
and informative but has some creative and exceptionally
inaccurate facts. informative creative,
unique and
informative

43
 Self Check

After studying this unit, can you now do the following?

Check I can…

describe the different theories on the origin of the universe.

identify the contribution of different proponents of the different theories on
the origin of the universe.

enumerate drawbacks of each theory of the origin of the universe.

Key Words

Big bang theory It suggests that the universe started as a “singularity”—
an area predicted to be in the core of a black hole with
very high temperature and density.
Encounter theory It proposes that the planets formed from the material
ejected from the sun during an encounter with another
celestial object.
Hubble’s law It states that the relationship of the velocities of distant
objects in the universe is directly proportional to their
distance from Earth.
Jovian planets It is composed of Jupiter, Saturn, Uranus, and Neptune
are huge planets made up of gases without land surfaces.
These planets were formed farther from the sun.
Nebula It means cloud. ir indicates that stars originate from
interstellar gas and dust.
Nucleosynthesis It is the formation of elements, such as hydrogen and
helium.

44
Oscillating universe It suggests that the universe is expanding and will
theory contract once all the energy after the big bang has been
used up, only to expand again once it approaches the
point of singularity
Planetesimal theory It describes Earth starting from a solid mass smaller than
its present size.
Terrestrial planets It includes Mercury, Venus, Earth, and Mars. These would
eventually form closer to the sun.
Tidal theory It proposes that the hot gas from the passing star
condensed into planets instead of condensing into
planetesimals.

45
 Wrap Up

Origin of the Universe and the Solar System

Photo Credits

Fig. 4. Georges Henri Joseph Edouard Lemaître by Tonynetone is licensed under CC
BY 2.0 via Flickr

Fig. 5. Edwin Hubble via Wikimedia Commons; Hooker telescope by Andrew Dunn is
licensed under CC BY-SA 2.0 via Wikimedia Commons.

46
Fig. 6. Cepheid star via Wikimedia Commons

Fig. 8. Arno Penzias is licensed under CC BY-SA 3.0 via Wikimedia Commons; Robert
Wilson is created under license CC BY 2.0 via Wikimedia Commons;

Fig. 12. Richard Tolman via Wikimedia Commons

Fig. 15. Terrestrial Planets via Wikimedia Commons

Fig. 16. Jovian Planets via Wikimedia Commons

Fig. 19. Emmanuel Swedenborg, Immanuel Kant, and Pierre-Simon Laplace via
Wikimedia Commons

Fig. 20. Thomas Chrowder Chamberlin, and Forest Ray Moulton via Wikimedia
Commons

References

Rodney Holder and Simon Mitton. 2013. Georges Lemaître: Life, Science and
Legacy, Germany: Springer Science & Business Media.

John Chambers and Jacqueline Mitton. 2013. From Dust to Life: The Origin and
Evolution of Our Solar System, New Jersey: Princeton University Press.

Michael Mark Woolfson. 2012. Time, Space, Stars and Man: The Story of the Big
Bang, Singapore: World Scientific.

J. Schombert. 2012. Origin of the Solar System. Accessed March 16, 2017
http://abyss.uoregon.edu/~js/ast121/lectures/lec24.html

D. Darling. 2016. Chamberlin-Moulton planetesimal hypothesis. Accessed March 16,
2017http://www.daviddarling.info/encyclopedia/C/CMplanhypoth.html

47