Physical Science SHS 1st/2nd Sem 2021-2022 PDF

Summary

This is a Physical Science course material for Senior High School, covering topics like the formation of elements during the Big Bang and stellar evolution, as well as the distribution of chemical elements and isotopes in the universe. Note that it may include various topics covering different lessons, including questions.

Full Transcript

DIVISION OF NAVOTAS CITY

Physical Science
1st or 2nd Semester

S.Y. 2021-2022
NAVOTAS CITY PHILIPPINES
Physical Science for Senior High School
Alternative Delivery Mode
1st or 2nd Semester
Second Edition, 2021

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Published by the Department of Education
Secretary: Leonor Magtolis Briones
Undersecretary: Diosdado M. San Antonio

Development Team of the Module
Writers: Christian James T. Malapitan, Heydiliza A. Santos, Don King O. Evangelista,
Lea Z. Malaca, Jasmin B. Tiongson,
Editor: Hydiliza A. Santos
Reviewer: Russell P. Samson
Illustrator: Rodel R. Rimando, SDO-La Union, Region I
Layout Artist: Russell P. Samson
Management Team: Alejandro G. Ibañez, OIC- Schools Division Superintendent
Isabelle S. Sibayan, OIC- Asst. Schools Division Superintendent
Loida O. Balasa, Chief, Curriculum Implementation Division
Russell P. Samson, EPS in Science
Grace R. Nieves, EPS In Charge of LRMS
Lorena J. Mutas, ADM Coordinator
Vergel Junior C. Eusebio, PDO II LRMS

Inilimbag sa Pilipinas ng ________________________

Department of Education – Navotas City
Office Address: BES Compound M. Naval St. Sipac-Almacen Navotas City
____________________________________________
Telefax: 02-8332-77-64
____________________________________________
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 Table of Contents
Quarter 1 or Quarter 3
What I Know................................................................................1

Module 1......................................................................................2

Module 2......................................................................................11

Module 3......................................................................................20

Module 4......................................................................................30

Module 5......................................................................................36

Module 6......................................................................................43

Module 7......................................................................................47

Module 8......................................................................................50

Assessment..................................................................................52

Quarter 2 or Quarter 4

What I Know................................................................................54

Module 9......................................................................................55

Module 10....................................................................................62

Module 11....................................................................................66

Module 12....................................................................................70

Module 13....................................................................................73

Module 14....................................................................................75

Module 15....................................................................................81

Module 16....................................................................................84

Assessment..................................................................................89

Answer Key..................................................................................91

References...................................................................................96
Directions: Choose the letter of the best answer. Write the chosen letter on a separate
sheet of paper.

1. What causes the formation of heavier atomic nuclei during big bang?
A. the increase in temperature C. the unchanging temperature
B. the cooling down of the universe D. none of the above

2. Sodium chloride is made up of sodium (Na) ion and chlorine (Cl) ion. Which of the
following types of bonds is describe the compound?
A. covalent bond C. nonpolar covalent bond
B Ionic bond D. polar covalent bond

3. Why are dispersion forces high in molecules with great number of electrons?
A. The electron distribution of big molecules is easily polarized.
B. The nucleus in the molecules has greater effective shielding effect.
C. The electrons move freely around the nucleus resulting to greater energy.
D. The electrons in the molecules can easily jump from one orbital to another.

4. Cellulose is the most abundant organic chemical on Earth. Cellulose consists of
long chains of glucose. What type of carbohydrate is cellulose?
A. Monosaccharide C. Oligosaccharide
B. Disaccharide D. Polysaccharide

5. Which of the following would NOT increase the rate of reaction?
A. adding catalyst
B. raising the temperature
C. increasing the volume of the container
D. increasing the concentration of the reaction

6. Why the dust particles suspended in the air inside unheated grain elevators can
sometimes react explosively?
A. because of high kinetic energy.
B. because of high activation energy.
C. because it has the catalytic effect on the reaction.
D. because it has a large surface area for the reaction.

7. Which of the following statements is FALSE for the chemical equation given below
in which nitrogen gas reacts with hydrogen gas to form ammonia gas assuming the
reaction goes to completion?

N2 + 3H2 2NH3
A. One mole of N2 will produce two moles of NH3
B. The reaction of 14 g of nitrogen produces 17 g of ammonia
C. The reaction of one mole of H2 will produce 2/3 moles of NH3
D. The reaction of three moles of hydrogen gas will produce 17 g of
ammonia.

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8. What is the ratio of the actual yield to the theoretical yield, multiplied by 100%?
A. mole ratio C. percent yield
B. excess yield D. Avogrado yield

9. Hydroelectric power is a renewable source of electricity. Which of the following
energy phase that the hydroelectric power plant is a source of electricity?
A. electricity is extracted from water
B. water is converted into steam to produce electricity
C. potential energy possessed by stored water is converted into electricity
D. kinetic energy possessed by stored water is converted into potential energy

10. What is the best way to dispose of hazardous chemicals at home?
A. bury them on a yard
B. carefully pour them down the drain
C. read the labels to see how to dispose on each
D. put them in a leak-proof container in the trash

MODULE 1

This module was designed and written with you in mind. It is here to help you
master the formation of the elements during the Big Bang and during stellar
evolution as well as the distribution of the chemical elements and the isotopes in the
universe. The scope of this module permits it to be used in many different learning
situations. The language used recognizes the diverse vocabulary level of students.
The lessons are arranged to follow the standard sequence of the course. But the order
in which you read them can be changed to correspond with the textbook you are now
using.
The module includes lessons, namely:
Lesson 1.1: Formation of Light Elements during Big Bang
Lesson 1.2: Stellar Nucleosynthesis and the Formation of Heavy Elements
Lesson 1.3: From Outer Space to Laboratory
After going through this module, you are expected to:
1. Give evidence for and describe the formation of heavier elements during star
formation and evolution
2. Explain how the concept of atomic number led to the synthesis of new
elements in the laboratory

Lesson Formation of Light Elements
1.1 during Big Bang

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In the beginning…..
The sudden dropped of temperature to billion degrees caused the combination
of protons and neutrons. They stayed together to form nuclei of the simplest elements
like hydrogen, helium and lithium. However, in normal circumstances, protons and
neutrons repel each other because a positively charged nuclei (proton) do not interact
with an uncharged nucleus (neutron). Nuclear fusion (meaning: fusion = union)
brought together these neutrons and protons utilizing the very high temperature.
The formation of the nuclei of light elements a few minutes after the Big Bang is
called Big Bang nucleosynthesis or primordial nucleosynthesis (nucleo refers to
nuclear and synthesis means combination or parts to form a whole).
The formation of nuclei of ordinary hydrogen, its two isotopes, deuterium and
tritium, and the common isotope of helium is shown in the illustration below.

Nucleosynthesis Note: As the Universe cooled down to about a trillion degrees,
protons and neutrons fused to form heavier atomic nuclei

proton
p
p deuterium

p
p p
n n
n
n n
n
neutron tritium helium
n

It is clearly shown above that the combination of these particles is capable of
forming helium, (and as hydrogen nuclei are simply protons anyway, hydrogen does
not need to form by combinations of anything) and the unstable helium-3, tritium
and deuterium simply break down. But why does the helium not also simply break
down again under pressure, and why do heavier elements not form? In fact, heavier
elements do form, but like the helium-3, tritium and deuterium they are formed as
unstable isotopes.
Ordinary helium, (helium-4) is the most stable isotope formed in this mixture
of fundamental particles during the early stage of Big Bang. Because of very high
pressures and temperatures, many helium nuclei did break down again, but it must
be remembered that at the time, the Universe was rapidly expanding and cooling.
Remember that almost all nuclei heavier than hydrogen formed would be
unstable and break down (see the illustration). The only other elements formed to
even a small degree was deuterium, and lithium-7, which though stable requires the
collision of several particles simultaneously, and it therefore very unlikely.
The exact ratios of hydrogen, helium, lithium and deuterium created during
the period of Big Bang nucleosynthesis would have been very sensitive to the density
of the mixture of fundamental particles from which they were made. Because the
mixture was not entirely uniform in density, different amounts of each were created
in different areas of the compacted early universe. As an average though,

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approximately twelve protons (hydrogen nuclei) were left for each helium nucleus
produced.

proto p n n
p p p Lithium-5
n
p n p Unstable
n neutro p

n p n p n
p p Helium-5
n
n Unstable
n

p n p n p n
p n
p p Beryllium-8
n n p n p
n Unstable

So, after four minutes, the Universe had made the first basic nuclei, and this
marks the end of primordial nucleosynthesis. Currently, the universe was still too
hot to allow these nuclei to attract electrons and form atoms. After 100 millenia it
had created the first atoms.

Activity 1: Formation of elements
Directions: Arrange the correct sequence of stages of formation of light elements in
the below using the Graphic organizer below. Use the choices below the graphic
organizer.
Sequential Order

1. 2 3 4. 5.

Protons, Electrons combine Stars ignite by
neutrons emerge with H, He and burning H and
from the cooling other nuclei to He. The cosmos
quark soup form neutral atoms lights up.

Simple atomic Gravity causes the
nuclei are formed diffuse H2/He gas
(H, He) to form clouds
which collapse into
stars

4
 Lesson Stellar Nucleosynthesis and the
1.2 Formation of Heavy Elements

….and there was light
After Big Bang, the universe continued to expand. The clouds of gas floating
are made of clouds of hydrogen and helium, which are left over from supernovas.
Matter started to form lumps, and some of which clumped together and
formed galaxies. These clumped matters are called protogalaxies (also called primeval
galaxy, is a cloud of gas which is forming into a galaxy). Inside these protogalaxies,
the internal lumps collapsed due to gravitational forces.
The compression brought by gravitational forces heats the interior of these
clumps which resulted to an increase in internal temperature. An increased internal
temperature initiated the nuclear fusion, involving hydrogen and producing helium
along with a tremendous amount of energy. This
caused the shining of the star. The production
of nuclei heavier than hydrogen in stars is called
stellar nucleosynthesis.
Stellar nucleosynthesis is the process by
which elements are created within stars by
combining the protons and neutrons together
from the nuclei of lighter elements. All of the
atoms in the universe began as hydrogen.
Fusion inside stars transforms hydrogen into
helium, heat, and radiation. Heavier elements
are created in different types of stars as they die or explode.

When hydrogen in the core of a star is depleted,
the core of the star shrinks, and the core temperature
rises. When the temperature is high enough, helium
fusion becomes possible, and the heavier carbon
nucleus is formed.
Depending in the mass of the star this series of
fusion reactions in the core followed by shrinking and
temperature rise that trigger more fusion takes place
successively forming elements.
The burning of
helium to produce
heavier elements then continues for about 1 million
years. Largely, it is fused into carbon via the triple-
alpha process in which three helium-4 nuclei
(alpha particles) are transformed. The alpha
process then combines helium with carbon to
produce heavier elements, but only those with an
even number of protons. The combinations go in
this order:

5
 1. Carbon plus helium produces oxygen.
2. Oxygen plus helium produces neon.
3. Neon plus helium produces magnesium.
4. Magnesium plus helium produces silicon.
5. Silicon plus helium produces sulfur.
6. Sulfur plus helium produces argon.
7. Argon plus helium produces calcium.
8. Calcium plus helium produces titanium.
9. Titanium plus helium produces chromium.
10. Chromium plus helium produces iron.

In stars more massive that
about ten solar masses, the
successive burning to produce
heavier nuclei eventually
produces a nonburning core of
iron. Iron-56 and other nuclei
with mass number of 56 are
stable nuclei and their fusion with
a helium nucleus would require
energy instead of producing it. As
a result, stellar nuclear burning
stops at iron. With no further
production of energy at the core the gravitational forces take over and the core
collapses, quickly and catastrophically.
The massive star that ends up as supernovas are manufacturers of elements
heavier than iron. These heavier elements like gold, silver, lead and mercury require
the very special conditions of pressure and heat that exist inside a supernova during
those few seconds of the collapse. Supernovae are also distributors of the elements
in the universe because during the explosion, all the elements that have been formed
are flung into space. Our own Sun and the planets in the solar system were formed
from the debris of earlier stars that have run through their life cycles. Since then,
the Sun shines!

Activity 2: Formation of elements
Directions: Answer the following, identify the number of proton and neutron,
together with the name of the product yield in fusion. (refer to the example below).
Write your answer on the space provided for.
Blue Circle (Proton)
Orange Circle (Neutron)

Deuterium Tritium Helium – 4 1 neutron
1 proton 1 proton 2 protons
1 neutron 2 neutrons 2 neutrons

6
 Using your periodic table of elements, identify the name of the element, if the
number of protons is 2, its atomic number is the same, therefore the name of the
element is HELIUM, to identify the atomic mass, follow the formula (atomic mass =
number of proton + Number of Neutron). Thus Helium 4 is the product of two
deuterium, the number for added to the name of the product refers to its atomic
mass.

Helium - 4 Tritium ______________ ___________
______ proton _______ protons ______ protons
______ neutrons _______ neutrons ______ neutrons

Lesson From Outer Space to Laboratory
1.3

Timeline of Element Discovery
Note sometimes there are two dates for an element, when discovery and
isolated were separated. For more recently discovered elements, discovery dates
and credit may be hotly disputed even today.
Ancient Times: Before 1 A.D.
Gold, Silver, Copper, Iron, Lead, Tin, Mercury, Sulfur, Carbon
Time of the Alchemists: 1 A.D. to 1735
Arsenic (Magnus ~1250), Antimony (17th century or earlier), Phosphorus
(Brand 1669), Zinc (13th Century India),
1735 to 1745
Cobalt (Brandt ~1735), Platinum (Ulloa 1735)
1745 to 1755
Nickel (Cronstedt 1751), Bismuth (Geoffroy 1753),
1755 to 1765
No new elements discovered in this date range.
1765 to 1775
Hydrogen (Henry Cavendish 1766), Nitrogen (Rutherford 1772), Oxygen
(Priestley; Scheele 1774), Chlorine (Scheele 1774), Manganese (Gahn,
Scheele, & Bergman 1774)
1775 to 1785
Molybdenum (Scheele 1778), Tungsten (J. and F. d’Elhuyar 1783), Tellurium
(von Reichenstein 1782)
1785 to 1795

7
 Uranium (Peligot 1841), Strontium (Davey 1808), Titanium (Gregor 1791),
Yttrium (Gadolin 1794)
1795 to 1805
Vanadium (del Rio 1801), Chromium (Vauquelin 1797), Beryllium
(Discovery: Louis Nicloas Vauquelin 1798; Isolated: Friedrich Wöhler &
Antoine Bussy 1828), Niobium (Hatchett 1801), Tantalum (Ekeberg 1802),
Cerium (Berzelius & Hisinger; Klaproth 1803), Palladium (Wollaston 1803),
Rhodium (Wollaston 1803-1804), Osmium (Tennant 1803), Iridium (Tennant
1803)
1805 to 1815
Sodium (Davy 1807), Potassium (Davy 1807), Barium (Davy 1808), Calcium
(Davy 1808), Magnesium (Black 1775; Davy 1808), Boron (Discovery: Gay-
Lussac & Thenard June 1808; Isolated: Humphry Davy July 1808), Iodine
(Courtois 1811)
1815 to 1825
Lithium (Discovery: Johan August Arfvedson 1817; Isolated: William Thomas
Brande 1821), Cadmium (Stromeyer 1817), Selenium (Berzelius 1817),
Silicon (Berzelius 1824), Zirconium (Klaproth 1789; Berzelius 1824)
1825 to 1835
Aluminum (Wohler 1827), Bromine (Balard 1826), Thorium (Berzelius 1828)
1835 to 1845
Lanthanum (Mosander 1839), Terbium (Mosander 1843), Erbium (Mosander
1842 or 1843), Ruthenium (Klaus 1844)
1845 to 1855
No new elements discovered in this date range.
1855 to 1865
Cesium (Bunsen & Kirchoff 1860), Rubidium (Bunsen & Kirchoff 1861),
Thallium (Crookes 1861), Indium (Riech & Richter 1863)
1865 to 1875
Fluorine (Moissan 1866)
1875 to 1885
Gallium (Boisbaudran 1875), Ytterbium (Marignac 1878), Samarium
(Boisbaudran 1879), Scandium (Nilson 1878), Holmium (Delafontaine 1878),
Thulium (Cleve 1879)
1885 to 1895
Praseodymium (von Weisbach 1885), Neodymium (von Weisbach 1885),
Gadolinium (Marignac 1880), Dysprosium (Boisbaudran 1886), Germanium
(Winkler 1886), Argon (Rayleigh & Ramsay 1894)
1895 to 1905
Helium (Discovery: Pierre Janssen and Norman Lockyer 1868; Isolated:
William Ramsay, Per Teodor Cleve, Abraham Langlet 1895), Europium
(Boisbaudran 1890; Demarcay 1901), Krypton (Ramsay & Travers 1898),
Neon (Ramsay & Travers 1898), Xenon (Ramsay & Travers 1898), Polonium
(Curie 1898), Radium (P. & M. Curie 1898), Actinium (Debierne 1899),
Radon (Dorn 1900)
1905 to 1915
Lutetium (Urbain 1907)
1915 to 1925
Hafnium (Coster & von Hevesy 1923), Protactinium (Fajans & Gohring 1913;
Hahn & Meitner 1917)

8
1925 to 1935
Rhenium (Noddack, Berg, & Tacke 1925)
1935 to 1945
Technetium (Perrier & Segre 1937 ), Francium (Perey 1939), Astatine (Corson
et al 1940), Neptunium (McMillan & Abelson 1940), Plutonium (Seaborg et
al. 1940), Curium (Seaborg et al. 1944)
1945 to 1955
Mendelevium (Ghiorso, Harvey, Choppin, Thompson, and Seaborg 1955),
Fermium (Ghiorso et al. 1952), Einsteinium (Ghiorso et al. 1952), Americium
(Seaborg et al. 1944), Promethium (Marinsky et al. 1945), Berkelium
(Seaborg et al. 1949), Californium (Thompson, Street, Ghioirso, and Seaborg:
1950)
1955 to 1965
Nobelium (Ghiorso, Sikkeland, Walton, and Seaborg 1958), Lawrencium
(Ghiorso et al. 1961), Rutherfordium (L Berkeley Lab, USA – Dubna Lab,
Russia 1964)
1965 to 1975
Dubnium (L Berkeley Lab, USA – Dubna Lab, Russia 1967), Seaborgium (L
Berkeley Lab, USA – Dubna Lab, Russia 1974)

1975 to 1985
Bohrium (Dubna Russia 1975), Meitnerium (Armbruster, Munzenber et al.
1982), Hassium (Armbruster, Munzenber et al. 1984)
1985 to 1995
Darmstadtium (Hofmann, Ninov, et al. GSI-Germany 1994), Roentgenium
(Hofmann, Ninov et al. GSI-Germany 1994)
1995 to 2005
Nihonium – Nh – Atomic Number 113 (Hofmann, Ninov et al. GSI-Germany
1996), Flerovium – Fl – Atomic Number 114 (Joint Institute for Nuclear
Research and Lawrence Livermore National Laboratory 1999), Livermorium –
Lv – Atomic Number 116 (Joint Institute for Nuclear Research and Lawrence
Livermore National Laboratory 2000), Oganesson – Og – Atomic Number 118
(Joint Institute for Nuclear Research and Lawrence Livermore National
Laboratory 2002), Moscovium – Mc – Atomic Number 115 (Joint Institute for
Nuclear Research and Lawrence Livermore National Laboratory 2003)
2005 to Present
Tennessine – Ts – Atomic Number 117 (Joint Institute for Nuclear Research,
Lawrence Livermore National Laboratory, Vanderbilt University and Oak
Ridge National Laboratory 2009)

Will There Be More Elements?
The discovery of 118 elements completes the first seven periods of the periodic
table, but scientists are working to synthesize new elements. When another discovery
is verified, another row (period) will be added to the table.
However, before scientists or chemist discovered these elements, they studied first
the basic – the concept of atomic number and the isotopes.

9
 These are example of isotopes. What have you noticed? Normally all of them
are Hydrogen element. However, you will notice that they have different atomic
weight (number on the upper part of the element). What thus that implies to us?
What does this mean?

Atomic Mass

Atomic Number

1. The atomic mass is equal to the sum of the number of proton and neutron of an
element.
2. The Atomic number is equal to the number of protons of an element
Here is a simple description of the relationship of atomic number and atomic mass
to the subatomic particles of an element
Atomic number = Number of Proton
Atomic Mass = Number of Proton + Number of Neutron
Number of Neutron = Atomic Mass – Atomic Number
Number of Electron = Number of Proton

Following the formula above, we can simply identify the differences in terms of the
number of neutrons of each isotope.

Number of Proton 1 1 1
Number of Neutron 0 1 2
Atomic Mass 1 2 3
Number of Electron 1 1 1

Activity 3. Isotopes
Directions: Indicate the number of protons, neutrons, atomic mass, and electron of
the following isotopes of carbon element. Indicate your answer in the table below,
show your solution on the space provided for/separate worksheet

Number of Proton
Number of Neutron
Atomic Mass
Number of Electron

10
Activity: Infographic Making
Directions: In this activity, you will create an infographic that demonstrates your
understanding of the Big Bang.
The infographic needs to include attention to the following:
Topic: The topic of the infographic is specific in nature and is intended
to inform or convince the viewer.
Type: The type of infographic chosen (for example, timeline or
informational) highly supports the content being presented.
Objects: The objects included in the infographic are relevant and
support the topic of the infographic.
Data visualizations: The data visualizations present accurate data and
are easy to understand.
Style: Fonts, colors, and organization are aesthetically pleasing,
appropriate to the content, and enhance the viewer’s understanding of
the information in the infographic.
Citations: Full bibliographic citations for all sources used are included.

MODULE 2

This module was designed and written with you in mind. It is here to help you
master Physical Science. The scope of this module permits it to be used in many
different learning situations. The language used recognizes the diverse vocabulary
level of students. The lessons are arranged to follow the standard sequence of the
course. But the order in which you read them can be changed to correspond with
the textbook you are now using.
The module is divided into two lessons, namely:
Lesson 2.1 – Electronegativity and Polarities of Molecules
Lesson 2.2 – Molecular Structures and Polarities
Lesson 2.3 – Polarities and Properties
After going through this module, you are expected to:
1. Recall the definition of electronegativity.
2. Compute for electronegativity differences between two bonded elements.
3. Infer the polarity of a molecule given its molecular geometry.
4. Differentiate polar from non-polar compounds based on its properties.

11
 Lesson
Electronegativity and Polarity
2.1

Recall from your Junior High School years. Elements combine to form
compounds. When they form compounds, they either give up, take, or share their
valence electrons (outermost electrons). When they give up, take, or share their
valence electrons, just like tug-of-war, there are differences in their pull of electrons.
This is determined by their electronegativity. Electronegativity (EN) is a measure of
the relative tendency of an atom to attract electron to itself when chemically
combined with another atom. The higher the value of electronegativity, the more it
tends to attract toward itself.

For the representative
elements, electronegativity
usually increases from left to
right across periods and
decreases from top to bottom
within group the most reactive
metals then. The elements in the
lower left-hand corner of the
periodic table have the lowest
electronegativity values. These
are consistent with the trend in
ionization energy.

Figure 1 General trend in electronegativity of representative elements

Although electronegativity is an atom’s ability to attract the electrons, it also
involved in bonding. Because no two elements have the same electronegativities, in
a covalent bond between different elements, one of the atoms attracts the shared pair
more strongly than does the other. The differences of the electronegativities are
determined by the EN or electronegativity difference. The result of their EN will
determine the polarity of the bond, whether it is polar covalent, non-polar covalent,
or ionic. The value of electronegativity is first determined by Linus Pauling.

Electronegativity Difference
Type of Bond
(∆EN)

Ionic ≥1.7

Polar Covalent 0.5 to 1.6

Nonpolar Covalent ≤ 0.4

12
 The formula for getting the EN of a pair of elements is determined by this
equation:

EN = | ENelement 1 – ENelement2 |

Let us try for the following element pair:

HCl EN of H =2.1 EN of Cl =3.0 EN = 0.9

Therefore, the bonds that exist between hydrogen and chlorine in hydrogen
chloride is polar covalent because it is between 0.5 to 1.6.
Look at the electron density
diagram or the diagram that shows the
distribution of valence electrons of HCl. You
can see that Cl is a lot bigger than H. Going
back to our tug-of-war illustration, we can
infer that Cl will pull the H atom towards
itself. Therefore, it is polar covalent. H is now
a partially positive (ẟ+) element and Cl now is
a partially negative (ẟ-) element. The pull now
is towards chlorine. The arrow above is called
a electric dipole.
Let us try another pair of elements:

Cl2 EN of Cl =3.0 EN = 0

The electron density diagram of Cl 2 shows two chlorine
atoms. Since they are the same element of the same size, if we
apply the tug-of-war illustration, there will be an equal pull
among the poles. Thus, we cannot see a electric dipole or a
dipole moment. Moreover, the electronegativity difference is
zero. Therefore, we consider it as a nonpolar covalent
compound.

The presence of a polar bond in a molecule often
makes the entire molecule polar. In a polar molecule one
end of the molecule is slightly negative, and one end is
slightly positive, in the hydrogen chloride molecule the
partial charges on hydrogen and chlorine atoms are
electrically charged region, or poles. A molecule that that has two poles is called a
dipolar molecule, or dipole, hydrogen and chloride molecule is a dipole.

When polar molecules are placed in an
electric field, the negative ends of the
molecules orient toward the positively
charged plate and the positive ends of
the molecules orient toward the
negatively charged plate.

The positive and negative charges in a nonpolar molecule experience force in opposite
direction as a result of their opposite polarities. This force causes the electron cloud of
a nonpolar molecule to be displaced in the direction of the attraction.

13
 Let us have a final example:

ENNa = 0.9 ENCl = 3.0 (∆EN) = 0.9 – 3.0 = │-2.1│= 2.1 ionic

EN differences in an ionic bond is so strong that there is no sharing of
electrons but rather a giving and taking of electrons. In your Grade 9 Science, you
have learned that metals are always in the business of giving up electrons and
non-metals are always taking electrons to form their complete octet.
As per Dr. Magno of UP Diliman, there are limitations to the concept of
electronegativity when applied to some molecules, such as BF 3 (EN = 1.94) and SiF4
(EN = 2.08). These molecules have a large electronegativity difference that we would
think that they are ionic, but both compounds are covalent. They exist as gases in
room temperature, a property not held by ionic compounds. How can we explain this
covalent nature?
The electronegativity of an atom in a molecule is not precisely constant. It
may vary slightly to either side of the stated value depending on its environment. For
example, fluorine is less electronegative when it bonds with metalloids like B and Si,
or nonmetals such as C that it bonds with metals such as Na or Mg 1.
Use the illustration below as a summary to this lesson:

(Source: Raymond Chang’s Chemistry 9th Edition)

Activity 1. Give and Take or Sharing
Directions: A. Identify the type(s) of Bond(s) found on the following molecules: (Ionic
– metal and non-metal, Covalent – both non-metal)
Compounds Type(s) of Bonds
1. CCl4
2 Li2O
3 NF3
4 CAs
5 SO2
6 Mg (OH)2
7 BeCl2

1
For more information, you can refer to Marcelita Magno’s Foundational Course in College Chemistry, pp 279
– 280 for more information.

14
Directions: B. Determine if the bond between atoms in each sample below is nonpolar
covalent, polar colavent or ionic. Show the electronegativity differences in each.

8 H2
9 PCl
10 F2
11 NaBr
12 NF
13 MgO
14 CH
15 HCl

Lesson The Role of Molecular Geometry
2.2 in the Polarity of a Molecule

You just have learned how to predict the type of bond polarity simply by
calculating the electronegativity difference of atoms (specifically two atoms). How
about for those molecules consisting of more than two atoms like H2O, CCl4, NH3 and
CO2?
For polyatomic molecules, both the bond polarity and molecular shape
determine the overall molecular polarity. In terms of molecular geometry, the
valence shell electron pair repulsion (VSEPR) theory would help us to determine
the spatial arrangement of atoms in a polyatomic molecule.
The molecular geometry is important to determine if a molecule is polar or not.
Valence shell electron pair repulsion theory, or VSEPR theory, is a model used in
chemistry to predict the geometry of individual molecules from the number of
electron pair surrounding their central atoms. It helps predict the spatial
arrangement of atoms in a polyatomic molecule. The shapes are designed to minimize
the repulsion within a molecule.
According to VSEPR, there are seven basic shapes of molecules stipulated
below. You can predict the shape of the molecules if you know the number of total
valence electrons, number of bonding pairs, non-bonding pairs, and lone pairs in the
central atom. For deeper discussion regarding drawing plausible Lewis structures
and molecular geometry, it will be discussed in Chemistry 1 (STEM/GAS). For
Physical Science, we will deal more with symmetry and polarity.

15
 Here is a simple flowchart that you can follow to know if a molecule is polar
or non-polar given its molecular structure.

NO Is the shape YES
symmetrical
in 3D?

NO Are all atoms
The molecule is bonded to the
POLAR central atoms
the same?

YES

The molecule is
NONPOLAR

Figure 4. Flowchart to determine if a molecule is polar or nonpolar
Remember that as you look at the structure of the element, you need to see it
at a 3-D perspective. A flat thinking will not suffice. You need to think that some of
the elements is at the BACK of this page or at the FRONT of this page. Let us have
some examples so that you can visualize.

Examples:
CH4 (methane) has four hydrogen atoms attached to the
central Carbon atom.
A. Is the shape symmetrical in 3D? Yes
B. Are all atoms bonded to the central atoms the same? Yes
Therefore, CH4 is nonpolar. (Note: Broken lines in a Lewis Diagram
means that the bonded atom is at the BACK of the page.)

16
 H2O (water) has two hydrogen atoms attached to the central oxygen
atom with two lone pairs at the central atom.

A. Is the shape symmetrical in 3D? Yes
B. Are all atoms bonded to the central atoms the same? No. There is a
presence of lone pairs. Therefore, water is a polar molecule.
Polar molecules have dipole moments, which is the sum of the
direction of its polarity. For water, the dipole moment is upward towards oxygen
which is more electronegative.
CO2 is a combination of carbon and oxygen atoms double bonded to
the central carbon atom.
Is the shape symmetrical in 3D? Yes
A. Are all atoms bonded to the central atoms the same? Yes
Therefore, CO2 is a nonpolar molecule.

CH3Br is an organic molecule with the halogen bromine.
A. Is the shape symmetrical in 3D? No
Therefore, CH3Br is a polar molecule.

The existence of lone pairs in the central atom has a big factor in
making a molecule polar.
For example, H2O (Bent) - polar due to two lone pairs and NH3 (Trigonal pyramidal) -
polar due to one lone pair
To summarize:
Nonpolar molecules are symmetric with no unshared electrons.
Polar molecules are asymmetric, either containing lone pairs of electrons on
a central atom or having atoms with different electronegativities bonded.

Activity 2 – Geometries and Polarities
Directions: Given the following molecules and their respective molecular
geometries, give the polarity of the molecule if its polar or non-polar. The first one
is done for you.
Molecule ∆ EN Bond Polarity Molecular Polarity of Molecule
(refers to pairs) Geometry (considering the
geometry)

P – Cl Polar Non-polar
1. PCl5
|2.2 –
3.0|

0.8

17
 2. BeCl2

3. CH2Cl2

4. OF2

5. SF6

Lesson
Polarities and Properties
2.3

As you have learned on Lesson 1, there is a certain attraction to magnetic and
electric fields for polar molecules and there is no reaction for non-polar molecules.
This also has a relationship with their physical properties. Remember the rule: what
happens microscopically (or atomically) has an effect macroscopically
(physically).
The table below shows the general properties of polar and nonpolar molecules.

Polar molecules Nonpolar molecules

Usually exist as solids or Usually exist as gases at
liquids at room temperature room temperature

High boiling point Low boiling point

High melting point Low melting point

High surface tension Low surface tension

18
 Low vapor pressure High vapor pressure

Low volatility High volatility

Soluble in water Insoluble in water

Examples: Water Examples: Waxes, Oils, Carbon
Dioxide

Solubility of Polar and Nonpolar Compounds
Solubility is defined as the ability of a solid substance to be dissolved in a
given amount of solvent while miscibility is the ability of the two liquids to combine
or mix in all proportions, creating a homogenous mixture.
The general rule to remember about the solubility and miscibility of molecular
compounds can be summarized in a phrase, “like dissolves like” or “like mixes with
like”. This means that polar substances will only be dissolved or mixed with polar
substances while nonpolar substances will be soluble or miscible with another
nonpolar substance.
If we will go back to your simple experiment above, does the rule like dissolves
like hold? Water is a polar compound, and it mixes and dissolves with polar
compounds such as alcohol. However, it doesn’t dissolve well with oil, which is a
nonpolar compound.

Surface Tension
Because water is a very special compound, having been polar, it exhibits a lot
of special properties like surface tension.
In the chemistry sense, surface tension is the energy required to increase the
surface area by a unit amount. The stronger the forces are between the particles in
a liquid, the greater its surface tension. Polar molecules have a higher surface tension
than nonpolar molecules, due to the extra lone pairs that it has that connects it to
other molecules of the same compound, also known as intermolecular forces, to be
discussed in the next module. Look at the table of surface tension of different
compounds at 20oC.
Substance Surface Tension (J/m2)
Diethyl ether (slightly polar) 1.7 x 10-2
Water (polar) 7.3 x 10-2
Water has the highest surface tension of all the liquids. This property is vital
for surface aquatic life because it keeps plant debris resting on a lake surface which
provides shelter and nutrients for fishes, microorganisms, and insects.

Activity 3 – Like Dissolves Like
Directions: Generally, like dissolves like. Polar molecules dissolve polar molecules
and ionic compounds. Nonpolar molecules dissolve other nonpolar molecules.
Alcohols, depending on what alcohol it is, have the characteristics of both, tend to
dissolve both types of solvents, but do not dissolve ionic solvents. In the table below
are solutes and solvents. Check the appropriate column as to whether the solute is
soluble in a polar or a nonpolar solvent.

19
 Solvents
Carbon
Solutes
Water tetrachloride (non- Alcohol
polar)
NaCl (ionic)
I2 (non-polar)
Ethanol (alcohol)
C6H6/benzene
(non-polar)
Toluene (non-
polar)

Activity:
Directions: Compute the electronegativity differences of each pairs of elements and
arrange them afterwards from the LEAST POLAR to the MOST POLAR.

Element Pair Electronegativity Arrangement
Difference
C – O
C – N
C – Cl
C – F
C – H

MODULE 3

This module will provide you the knowledge, skills and understanding of
intermolecular forces of attraction.
The module is divided into two lessons:
Lesson 3.1 – Intermolecular Forces of Attraction
Lesson 3.2 – Effects of Intermolecular Forces of Attraction
At the end of this lesson, you are expected to:
1. Differentiate intramolecular forces from intermolecular forces of attraction.
2. Identify the intermolecular forces of attraction that exists between given
molecules.
3. Relate intermolecular forces of attraction to different properties of matter such
as viscosity, surface tension, and capillarity.

20
 Lesson Intermolecular Forces of
3.1 Attraction

Intramolecular vs Intermolecular Forces of Attraction
From your English class, you know that prefixes have meaning. Inter- means
between while Intra- means inside. Therefore, intramolecular forces of attraction are
forces that exists between the elements in a compound while intermolecular forces
are forces that exists between two molecules of a compound.
Intramolecular forces are stronger than intermolecular forces of attraction.
Intramolecular forces are also known as bonding forces. They are strong because
they involve larger charges, and they are closer together. Intramolecular forces
usually determine the chemical property of the compound. Intramolecular forces
are more permanent than intermolecular forces of attraction.
Intermolecular forces, on the other hand, are forces that form between
molecules, atoms, or ions. They are relatively weak because they involve smaller
charges that are far apart. Intermolecular forces usually determine the physical
property of the compound. Intermolecular forces are also known as van der Waals
forces.
Let us use the following comparison to differentiate the strengths of
intermolecular or intramolecular forces of attraction.
H2O (g) → 2 H2 (g) + O2 (g) absorbs 927 kJ/mol
(energy needed to break the bonds between hydrogen and oxygen atoms in water
molecule)
H2O (l) → H2O (g) absorbs 40.7 kJ/mol
(energy needed to break the forces between water molecules to transform the liquid
water to water vapor)
We can see from the illustration above that it takes less energy to turn liquid
to gas (breaking intermolecular forces) rather than separating hydrogen and oxygen
in a water molecule (breaking bonding forces).
The table below shows the comparison between bonding and nonbonding
(intermolecular) forces of attraction.

A. Bonding Forces (Intramolecular Forces)

21
 B. Nonbonding forces (Intermolecular Forces)

Source: Martin Silberberg’s Chemistry: The Molecular Nature of Matter and Change, pg 437

Types of Intermolecular Forces
A. Ion – Dipole Forces
This happens when an ion and a nearby polar molecule attract each other. The
ion comes from an ionic compound that dissociated or separated. Ions, by definition,
are charged particles.
Remember the basic rule of physics, opposites attract. So, if you have a polar
molecule with partially negative and partially positive ends, the partially negative end
with attract to an ion that is positive; and the partially positive end will attract the
ion that is negative.
The most basic example of ion-dipole forces takes place when an ionic compound
dissolves in water. The partially negative oxygen atom in water is attracted to the
Na+ ion in NaCl while the terminal partially positive H from water is attracted to Cl-
ions.

Source: https://lh3.googleusercontent.com/proxy/Z6ZJEuQ1UStY73Wp1xvvYzBfs5FizSggCIm2B7wVa0lPWYE0hPpDz5sPYym-
9X2Dx6lKudiWQYMt1f7DIYHTl88Ib1eVYRn3-7NOX7VBfY8

B. Dipole-Dipole Forces
When polar molecules lie near one another, their partial charges act as tiny
electric fields that orient them and give rise to dipole-dipole forces, where the positive
pole of one molecule attracts to the negative pole of the other molecule. You also need
to take look at the molecular structure or geometry of the compound for you to take
a look if the dipoles are available for intermolecular forces. Dipole – dipole forces exist
between polar covalent molecules.

22
B.1. Hydrogen Bond – A special type of Dipole-Dipole Force
A special type of dipole-dipole force arises between molecules that have a
terminal H atom bonded to a small, highly electronegative atom with lone electron
pairs, specifically fluorine (F), oxygen (O). and nitrogen (N). The F, O, and N must
be terminal or exposed so that it can bond with other H from another molecule. This
type of dipole-dipole force is a relatively strong form of molecular attraction.

The oxygen atom should be exposed so that the
partially positive H can interact with it.

C. Dispersion (London) Forces
Consider a neutral atom such as Helium or a nonpolar molecule such as H2. The
electrons in each of the case are in constant motion relative to the nucleus so that
in a given atom or molecule, the centers of positive and negative charges no longer
coincide, and a temporary dipole is produced. Its direction could change with the
movement of electrons. The electric field generated by a temporary dipole can induce
a dipole in phase with itself in neighboring atoms and weak attractions set in between
nearby induced dipoles. These temporary cohesive forces are known as London
dispersion forces. These are the weakest intermolecular forces, and they are the
most temporary.

These forces are present between all particles, whether atoms, ions, molecules.
Dispersion forces are the only force existing between nonpolar particles. However,
because it exists in all particles, dispersion forces contribute to the overall energy of
attraction of all substances. Therefore, all molecules exhibit London Dispersion
Forces.

D. Induced Dipole Forces
A nearby electric field can distort the electron cloud of a different molecule,
specifically a nonpolar molecule. In effect, the field induces a distortion in the electric
cloud. For a nonpolar molecule, this distortion creates a temporary, induced dipole
moment. For a polar molecule, it enhances its dipole moment that is already present.
The ease with which the electron cloud of a particle can be distorted is called
polarizability. There are two types of induced dipole forces: ion that induces a

23
nonpolar molecule to become a dipole, and a dipole molecule that induces a nonpolar
molecule to become a dipole.

D.1. Ion-Induced Dipole Forces
Ion-induced dipole forces is a charged-induced dipole forces when an ion
induces a nonpolar molecule so that it creates a temporary dipole in the nonpolar
molecule. This is a temporary interaction only and after the ion leaves the system,
the nonpolar molecule returns to being a nonpolar molecule.
One of the best examples of ion-induced dipole is the interaction of Fe2+ ion in
hemoglobin and the oxygen molecule (O2) in our blood. Oxygen molecule is a
nonpolar compound. Because Fe2+ is an ion, it induces a dipole in the oxygen
molecule, thus binds itself in the oxygen. Its role is for the delivery of oxygen to the
bloodstream.

D.2 Dipole-Induced Dipole Interaction
Dipole-induced dipole interaction are weaker than the ion-induced dipole.
These arise when a polar molecule distorts the electron cloud of a nearby nonpolar
molecule. The best example of this is the solubility of oxygen in water. Paint thinners
and grease solvents also function through dipole-induced dipole forces.

Identifying Intermolecular Forces Between Molecules
For you to correctly identify the intermolecular forces between the molecules,
you need to correctly identify as well the polarity of that molecule. With that, you can
determine the intermolecular forces that exists between the molecules.
The schematic diagram below can help you to identify the intermolecular
forces in a sample.

Interacting Particles

Ions Present Ions not Present

Polar + Nonpolar Nonpolar Molecules
Ion + Polar Molecule Polar Molecules Only
Molecules (Dipole- Only (Dispersion forces
(Ion-Dipole Forces) (Dipole - Dipole Forces)
Induced Dipole Forces) ONLY)

Ion + Nonpolar
H bonded to N, O, F
Molecule (Ion - Induced
(Hydrogen Bonding)
Dipole Forces)

DISPERSION FORCES ARE PRESENT IN ALL TYPES OF MOLECULES

24
Strength of Intermolecular Forces
We can now list down all the intermolecular forces and the strength that it
exhibits. The stronger the intermolecular force, the higher energy it needs for us to
break those forces. The weaker it is, the less energy needed.
The chart below tells us of the relative strengths of intermolecular forces. This
can be referred to when trying to relate the IMF to the properties of substances that
will be discussed in the following lesson.

Relative Strengths of Intermolecular Forces

Ion-dipole Strongest

H-bonding

Dipole-dipole

Dipole-induced dipole

London dispersion forces Weakest

Activity 1:
Directions: Check the type of intermolecular forces that exists between each of the
following molecules. Check ALL that applies. The first one is done for you.

Molecules
Ion – Dipole

Dispersion
Hydrogen
Bonding

Induced

Induced
Dipole –

London
Dipole-

Forces
Dipole

Dipole

Dipole
Ion –

1. CO2 /
2. Na+ and

3. HBr
4. I2
5. HF
6. NH3
7. CH3OH
8. CH4
9. C8H10
10. O2

25
 Lesson Effects of Intermolecular
3.2 Forces of Attraction

Since intermolecular forces happens in all types of compounds, it affects the
physical characteristics of the substance. Listed below are some of the properties of
substances that are greatly affected by the presence of intermolecular forces.
a. Boiling Point
In its strictest sense, the boiling point of a substance depends on the equilibrium
vapor pressure exerted by a liquid or solid above the liquid or solid. This means that
a substance reaches its boiling point if its rate of condensation is equal to its rate of
vaporization in a closed container. For example, at 100 oC, the vapor pressure of water
is equal to the atmospheric pressure of 1.00 atm. Since the vapor pressure of water
is equal to the vapor pressure of the environment, thus, boiling occurs.
Vapor pressure of a substance, however, is dependent on the strength of the
intermolecular forces present in that substance. When the intermolecular forces
are strong, the vapor pressure is low. Consequently, boiling will happen in a
higher temperature since it needs more energy to break the intermolecular
bonds for the substance to change it into vapor.
In essence, strong intermolecular forces produce lower rates of evaporation and
a lower vapor pressure. Therefore, we need to raise the temperature for the vapor
pressure to increase. The reverse is also true, weak intermolecular forces produces
a higher rate of evaporation and a higher vapor pressure. Therefore, we need lower
amounts of temperature for it to boil.

Example:
Select whether which of the following pairs of substances has the higher
boiling point.

1. MgCl2 or PCl3?
Answer: MgCl2 is an ionic compound, but PCl3 is a polar covalent
compound. Since PCl3 is composed of polar compounds, the IMF present
in it is dipole-dipole while in MgCl2, it is ionic bonding forces. The forces
in MgCl2 is stronger – thus MgCl2 has a higher boiling point.

2. CH3NH2 or CH3F?
Answer: Let us look at their structures.

Checking their molecular masses, they have almost the same molecular mass.
Since CH3NH2 has the N—H bonds, it means that it can form hydrogen bonds. CH3F,
although having the F atom, is not connected to H, so dipole-dipole forces occurs but
not hydrogen bonds. Therefore, CH3NH2 has the higher boiling point.

26
Boiling Point and Structures
For both nonpolar compounds that are considered isomers or with the same
molecular formula, the strength of the dispersion forces (which ultimately affects
their boiling points) is influenced by their molecular shape. Take into example n-
pentane and 2,2-dimethylpropane which has the same molecular formula C 5H12.

The figure on the left is n-pentane, and on the right is 2,2-dimethylpropane.
We can see that n-pentane has more contact points (shaped like a cylinder) rather
than 2,2-dimethylpropane (compact shape). Thus, n-pentane has more dispersion
forces, and a higher boiling point. Laboratory data shows that the boiling point of n-
pentane is 36.1oC while 2,2-dimethylpropane has a boiling point of 9.5oC.
Boiling Points, Size, and Polarizability
The strength of dispersion forces also depends on the size of the substance or
the number of electrons in the substances. The ease with which the electron
distribution is distorted explains the amount of dispersion forces that a substance
exhibits. The distortion of the electron distribution is known as polarizability.
The greater the polarizability of the electron distribution the greater are the
dispersion forces. When the dispersion forces are high, the boiling and melting points
are also high.
Br2 and F2 are both diatomic gases. They are also both nonpolar, but Br 2 is a
bigger molecule than F2. The polarizability of Br2 is greater than F2 so it has greater
dispersion forces. This explains why Br2 has a higher boiling point than F2. Greater
amount of energy is needed to overcome the big dispersion forces in Br 2 than in F2.

b. Melting Point
The condition given above for boiling point is also true for melting point. When
bond breaks easily, it affects the melting point of the substance. The greater the
intermolecular forces, the greater the temperature it needed for it to melt.
c. Volatility
Volatility is the tendency of substances to evaporate at normal temperatures.
For example, rubbing alcohol is volatile because it evaporates rapidly in our hands
while cooking oil does not. The more volatile a substance, the weaker is its
intermolecular force because it means that it just need less energy for the substance
to turn into vapor.
d. Viscosity
Viscosity is the measure of a liquid’s resistance to flow. When a liquid flows,
the molecules slide around and past each other. When a material is viscous, it means
that it has intermolecular forces that impedes its motion. It means that liquids that
have stronger intermolecular forces is more viscous than other.

e. Capillarity and Surface Tension
Surface tension is the amount of energy required to stretch the surface area
of a liquid. Liquids with high intermolecular forces have higher surface tensions. It
means that it has a stronger network that holds the liquid together. For example,
you can put a lot of drops of water in a one-peso coin and still hold the shape of the

27
liquid before it breaks. However, if the water is soapy, it means that there is an
interaction of nonpolar compounds such as soaps that breaks that surface tension.
Surface tension is also the reason why paperclip can float in water. It is also
the reason why mosquitos can lay their eggs on water without sinking.
Because surface tension happens, capillarity happens as well. It is the rising
of a liquid through a narrow space against the pull of gravity. Two forces, cohesion
and adhesion push surface tension on walls. Cohesion is the intermolecular
attraction between like molecules while adhesion is the attraction between unlike
molecules. To illustrate, the attraction between the water molecules is cohesion,
while the attraction between the water molecules and the sides of the glass tube is
adhesion.

Source: https://ib.bioninja.com.au/_Media/water-cohesion-and-adhesion_med.jpeg

If cohesion is greater than adhesion, there will be depression or lowering. If
there is lowering, there is a lower height of the liquid in the capillary tube. The
meniscus or the curve at the top of the liquid inside the glass tubing is curving
downwards or convex meniscus.
If adhesion is greater than cohesion, there will be rising of the liquid in the
tubing, and the meniscus will be curving upwards or called as concave meniscus.
Look at the illustrative example below:

Source:

https://www.quirkyscience.com/wp-content/uploads/2018/02/Figure-1-1.png

Glass is mostly silicon dioxide (SiO2), so the water molecules form hydrogen
bonds with the oxygen of the tube’s inner walls. Because the adhesive forces between
the water molecules (hydrogen bonding) is greater than the cohesive forces between
the water and the glass tubing, water creeps up to the wall of the tubing. The cohesive
forces now give rise to surface tension and then pulls the liquid surface upward.
These forces (cohesive and adhesive) combine to raise the water level and thus
produces the concave meniscus. This explains the action why water rises from the
roots of the plants to the leaves through the tubes inside the plant called xylem and
phloem.
In the case of mercury, since mercury (Hg) has stronger cohesive forces (due
to metallic bonding). We know that metallic bonding is stronger than the cohesive
forces that will happen to Hg and the glass. Therefore, the liquid Hg tends to pull

28
away from the walls. At the same time, the surface atoms are being pulled towards
the interior of the Hg by its high surface tension, so the level drops. These combined
forces produce a convex meniscus. This is the principle behind the barometer.
The stronger the intermolecular forces possessed by a molecule, the
higher is the surface tension of the substance.

Activity 2:
Directions: Fill in the blanks with the words GREATER or LOWER.

1. The stronger the forces between the particles, the _____________ the
melting point.
2. The stronger the forces between the particles, the _____________ the
vapor pressure.
3. The stronger the forces between the particles, the ______________ the
viscosity.
4. CH4 has a _______________ surface tension than H2O.
5. SiO2 has a _______________ boiling point than SO2.
6. HCl has a _______________ boiling point than I 2.
7. C2H6 has a _______________ vapor pressure than C 4H10.
8. CH3CH2OH has a _______________ boiling point than CH3CH2CH3.
9. CH3CH2OH has a _________________ viscosity than CH3COCH3
10. H2O has a ____________ intermolecular force than CO2.

Activity: World of Water
Directions: Water is made from two gases that are flammable but together they make
a substance that extinguishes flame. These two elements, hydrogen, and oxygen,
when bonded together allowed life on earth to flourish. The ability of water to form
hydrogen bonds presents many interesting properties which are useful to life.

Create an output, whether a (1) poster, (2) video presentation, (3) essay, or (4) collage,
or anything that you can propose to your teacher showing what you have researched
on the following topic options about the amazing world of water. Choose one topic
and relate intermolecular forces of attraction.
I. Water and the Human Body
II. The triple point of water
III. Water and its role in agriculture
IV. Water and the “universal solvent” claim
V. Water and religion and myths
VI. The shape of water and the beauty of snow
VII. Water and its high specific heat capacity

29
 MODULE 4

This module will provide you the knowledge, skills and understanding of
intermolecular forces of attraction.
Explain how the structures of biological macromolecules such as
carbohydrates, lipids, nucleic acid, and proteins determine their properties
and functions.
At the end of this lesson, you are expected to:
1. Recall the different types of biomolecules from previous Science lessons.
2. Relate the structure of biomolecules to the intermolecular forces present in
the biological macromolecule.
3. Cite the importance of these intermolecular forces in the properties and
functions of the biomolecules.

Lesson
Biological Macromolecules
4

Carbohydrates
Carbohydrates can be represented by the stoichiometric formula (CH 2O)n
where n is the number of carbons in the molecule. Therefore, the ratio of carbon to
hydrogen to oxygen in the compound is 1:2:1. Carbohydrates can be classified into
three: monosaccharides, disaccharides, and polysaccharides.
Carbohydrates act as energy storage or food reserves in plants and animals.
This property of carbohydrates is due to many carbon-hydrogen bonds that exists in
the molecule. Breaking down carbon-hydrogen bonds easily releases energy faster.
Because of the abundance of polar -OH groups in the molecule, they are highly polar.
This makes carbohydrates soluble in many body fluids, such as blood, which is 70%
water. This makes carbohydrates easily available to the body.

30
 From: https://alevelbiology.co.uk/wp-content/uploads/2019/11/Structure-and-Function-of-
Carbohydrates_1.png

Carbohydrates can be represented either via Fischer or Haworth projections.
The illustration above is an example of a Fischer projection of a carbohydrate. We
can classify carbohydrates as to the functional group that it possesses, if it is an
aldose or ketose. It is an aldose if it contains an aldehyde. It is a ketose if it contains
a ketone. It can be easily seen in the structure. An aldehyde is a terminal functional
group (R-C=O -H) while a ketone is not a terminal functional
group (R-C=O-R).
When the linear structure (Fischer projection) closes, it
produces a Haworth projection of the molecule, in this case,
glucose molecule. This is the cyclic structure of a carbohydrate
which you usually see in books.
Carbohydrates can also be classified by the number of
molecules (saccharides) it has either monosaccharide (one),
disaccharide (two), or polysaccharide (many).
Monosaccharide (one saccharide)
Glucose used in dextrose, blood sugar; the form utilized by
the human body

Galactose found in milk and milk products

Fructose found in fruits and honey

Disaccharides (two saccharides)

Maltose glucose + glucose found in malt
Sucrose glucose + fructose found in regular table sugar,
sugarcane, and sugar beet
Lactose glucose + galactose found in milk and milk products
Polysaccharides (many saccharides)

Amylose storage form of glucose in plants (starch)

Amylopectin storage form of glucose in plants (starch)

Glycogen storage form of glucose animal; stored in the liver and
muscles

31
 Cellulose structural material in plants--cell wall in wood, wood fiber
cannot be digested by humans

You may notice that glucose, fructose and galactose have the same chemical
formula, C6H12O6. However, they have different functions. It is because they may
have the similar chemical formula but different chemical structure. This is what we
call isomers. Glucose and galactose are really stereoisomers – same order, same
aldose, but different arrangement in space, while fructose is a structural isomer of
glucose and galactose. Their difference is that glucose and galactose are aldoses,
while fructose is a ketose.
Disaccharides form by dehydration reaction which eliminates water
molecule in the combination of two monosaccharides. The bond that is formed
between two monosaccharides is called a glycosidic bond/linkage.
Long chains of monosaccharides result in polysaccharides. Below are the
structures of amylose and amylopectin. The structures of amylose and amylopectin
affects food chemistry. For example, rice with high amounts of amylopectin will be
very sticky once it is cooked. If the rice grains is high in amylose, it will be fully
separated once cooked.
If we have excess starch in our body, our body stores it in forms of glycogen
so that if we lack energy, there is an immediate source of energy stored. Look at the
illustrations below. Can you think of the reason why glycogen is branched and how
will it help the fast release of energy? What do you think is the reason why cellulose
is very strong?
Lipids
A fat molecule consists of two main components: glycerol and fatty acids.
Glycerol is an alcohol with three carbons, five hydrogens, and three hydroxyl (OH)
groups. Fatty acids have a long chain of hydrocarbons with a carboxyl group attached
and may have 4-36 carbons; however, most of them have 12-18. In a fat molecule,
the fatty acids are attached to each of the three carbons of the glycerol molecule with
an ester bond through the oxygen atom. The bond formed is called ester bonds and
the process is esterification (condensation reaction).
There are different classifications of lipids: triglyceride, phospholipid, wax,
and steroid. The lipid family is one of the most varied in terms of structure, but they
share the common property of being insoluble in water.
Fat and oil are the most common examples of lipids. They are under
triglycerides because they are composed of glycerol and three fatty acids.
Fat refers to solid triglyceride usually from animal sources such as meat, milk,
butter, margarine, eggs, and cheese. Oil refers to liquid triglycerides from plant
sources. Examples are olive oil, corn oil, sunflower oil, and soybean oil. Animal fats
contain high percentages of saturated fatty acids while plant oils are mostly
unsaturated fatty acids.
1. Saturated fats have two carbons attached to each carbon (except the
one at the end). Saturated fats are unhealthy fats like butter. They are usually solid
at room temperature. In blood chemistry, they are called LDL or low-density
lipoprotein.
2. Unsaturated fats contains a double bond. They are missing at least one
hydrogen and are curl in shape. The unsaturated fats are healthy and include oils.
In blood chemistry, they are under HDL or high-density lipoprotein.

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 They are insoluble in water because of their
lack of many polar and hydrogen bonding
functional groups. When placed in water, lipid
molecules cling together, exposing their polar
groups to their surrounding molecules while their
nonpolar groups stay within the interior of their
lipid cluster. Because of this property as well, lipids
are at best an effective cell membrane component.
Proteins
Proteins are composed of four elements,
namely: carbon, hydrogen, oxygen, and nitrogen.
Sulfur and other metals are sometimes also found
in proteins. If carbohydrates are made up of
saccharides, proteins are made up of amino acids. There are twenty amino acids
that exists in living organisms. Nine of these amino acids are essential. These are
histidine, isoleucine, leucine, lysine, methionine, phenylalanine, threonine,
tryptophan, and valine. It means that it cannot be made by our body and must come
from food.
Amino acids bond to other amino acids
via peptide bonds or linkages.
The 20 amino acids that make up
proteins have side groups with varying
properties. Hence, the number and sequence of
amino acids affect the properties and functions
of a particular protein. For example,
hemoglobin, the protein found in red blood cells
as is used to carry oxygen has 574 unique
amino acid sequences. If one of the proteins is
wrong in the sequence, the function
malfunctions. Insulin, on the other hand, has
51 amino acid sequences.
Protein structures are very complex, and researchers have only very recently
been able to determine the structure of complete proteins down easily and quickly to
the atomic level. (The techniques used date back to the 1950s, but until recently they
were very slow and laborious to use, so complete protein structures were very slow
to be solved.) Early structural biochemists conceptually divided protein structures
into four levels to make it easier to get a handle on the complexity of the overall
structures. To determine how the protein gets its final shape or conformation, we
need to understand these four levels of protein structure: primary, secondary,
tertiary, and quaternary.
Because of different intermolecular attractions that happen in the tertiary
level of protein structures, the functions of the proteins also change. The picture
below shows the different intermolecular forces that may happen in the tertiary
protein structure.

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 Primary structure is the amino acid sequence.
Secondary structure is local interactions between
stretches of a polypeptide chain and includes α-helix
and β-pleated sheet structures. Tertiary structure is
the overall the three-dimension folding driven largely
by interactions between R groups. Quaternary
structures is the orientation and arrangement of
subunits in a multi-subunit protein.
Because of its structure, proteins have various
functions. Below is a table to summarize it and some
of its examples.
Type Examples Functions
Digestive Amylase, lipase, pepsin, Help in digestion of food by
Enzymes trypsin catabolizing nutrients into monomeric
units
Transport Hemoglobin, albumin Carry substances in the blood or
lymph throughout the body
Structural Actin, tubulin, keratin Construct different structures, like the
cytoskeleton
Hormones Insulin, thyroxine Coordinate the activity of different body
systems
Defense Immunoglobulins Protect the body from foreign
pathogens
Contractile Actin, myosin Effect muscle contraction
Storage Legume storage proteins, Provide nourishment in early
egg white (albumin) development of the embryo and the
seedling
Two special and common types of proteins are enzymes and
hormones. Enzymes, which are produced by living cells, are catalysts in biochemical
reactions (like digestion) and are usually complex or conjugated proteins. Each
enzyme is specific for the substrate (a reactant that binds to an enzyme) it acts on.
The enzyme may help in breakdown, rearrangement, or synthesis reactions.
Enzymes that break down their substrates are called catabolic enzymes, enzymes
that build more complex molecules from their substrates are called anabolic
enzymes, and enzymes that affect the rate of reaction are called catalytic enzymes. It
should be noted that all enzymes increase the rate of reaction and, therefore, are
considered to be organic catalysts. An example of an enzyme is salivary amylase,
which hydrolyzes its substrate amylose, a component of starch.
Hormones are chemical-signaling molecules, usually small proteins, or
steroids, secreted by endocrine cells that act to control or regulate specific
physiological processes, including growth, development, metabolism, and
reproduction. For example, insulin is a protein hormone that helps to regulate the
blood glucose level.
Proteins have different shapes and molecular weights; some proteins are
globular in shape whereas others are fibrous in nature. For example, hemoglobin is
a globular protein, but collagen, found in our skin, is a fibrous protein. Protein shape
is critical to its function, and this shape is maintained by many different types of
chemical bonds. Changes in temperature, pH, and exposure to chemicals may lead
to permanent changes in the shape of the protein, leading to loss of function, known
as denaturation.

Nucleic Acids

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 Nucleic acids play an essential role in the storage, transfer, and expression
of genetic information. Nucleic acid was discovered by a 24-year-old Swiss physician
named Friedrich Miescher in 1868. He was puzzled that an unknown substance in
white blood cells did not resemble carbohydrates, proteins, or lipids. He was able to
isolate the substance from the nucleus and initially called it nuclein. He eventually
was able to break down nuclein into protein and nucleic acids. He found out that
nucleic acids contain carbon, hydrogen, oxygen, nitrogen, and phosphorus
The most common examples of nucleic acids are DNA (deoxyribonucleic acid)
and RNA (ribonucleic acid). DNA is a nucleic acid that carries the genetic code of
organisms. It is fondly termed as the blueprint of life. RNA, on another hand, carries
the information from the DNA to the cellular factories for the synthesis of proteins.
If carbohydrates are composed of saccharide units, proteins of amino acids, and
lipids of fatty acids, nucleic acids are composed of nucleotides. Nucleic acids are
also known as polynucleotides. Nucleotides are made up of a nitrogeneous base, a
five-carbon sugar, and a phosphate group.
The nitrogeneous base can be a pyrimidine or purine. Purines include adenine
and guanine, while pyrimidines are cytosine, thymine, and uracil.
This plays an important part in the zipping of the DNA since a purine base
pair with a specific pyrimidine base through hydrogen bonding. Adenine bonds with
thymine with two hydrogen bonds, and guanine with cytosine with three hydrogen
bonds. It is important that they are strong but NOT permanent.
The double helix structure of the DNA protects the nonpolar nitrogenous
bases in the molecules by orienting them in the middle. The polar phosphate groups
are exposed so that the DNA will be soluble in the aqueous polar environment. This
protects the information stored in the DNA ensuring that the DNA sequence stays
intact by keeping the DNA structure stable. Furthermore, the helix is held together
by hydrogen bonds that forms the two strands of the DNA. This allows to form a
stable double helix and thus be able to protect the important genetic information
that makes up the body. The nucleotides are joined together using phosphodiester
bonds that makes the backbone of the DNA.

Source:
https://www.researchgate.net/profile/A_Turut/publication/283467276/figure/fig1/AS:613983497232405@1523396481947/Double-helix-
structure-of-DNA.png

Activity 1: Macromolecule Comparison Table
Directions: Complete the table with correct information based on your lesson
above.

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 Biological Function/s Monomer Bonds Present Examples
Macromolecule (subunit)

Carbohydrates

Lipids

Proteins

Nucleic Acids

Activity – The Biological Macromolecules in My Food
Modified from: https://lhsblogs.typepad.com/files/macromolecules-in-your-food.pdf
The Nutrition Facts Label tells you what nutrients (components of food your
body needs to grow and stay healthy) and how much of those nutrients are in found
in one serving. The Nutrition Facts label can help you make choices about the food
you eat. The Nutrition Facts label is on the outside of most food packages but isn't
on most fresh foods (like fruits and vegetables). Below is an example of a Nutrition
Facts label and explanations of the information found on the label.
Find the food label of something you have eaten (or would consider eating) and
complete the following information.
1. What are the main ingredients of this food?
2. Identify the total grams of:
a. Carbohydrates: _______________
b. Fats: ____________
c. Proteins: _______________
3. What surprised you as you read the nutrition facts for this food item?
Do the steps to at least three food labels.

MODULE 5

This module was designed and written with you in mind. It is here to help you to look
deeper into chemical reactions. The scope of this module permits it to be used in
many different learning situations. The language used recognizes the diverse
vocabulary level of students. The lessons are arranged to follow the standard
sequence of the course. But the order in which you read them can be changed to
correspond with the textbook you are now using.
The module is devoted in a single lesson, namely:
Lesson 5 – Rates of Chemical Reactions
After going through this module, you are expected to:
1. describe how chemical reactions occur;
2. explain the Collision Theory and it’s premises;
3. illustrate and interpret energy diagrams;
4. explain the different factors that affect the rate of reaction.

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 Lesson
Rates of Reaction
5

Chemical Reactions Occur
One evidence that a chemical reaction has occurred is the production of other
substances as shown by their properties which are different from those of the original
substances. Chemical reactions happen because molecules interact with each other
and collides with each other effectively to form a new product. This is called the
collision theory.

Collision Theory
The collision theory explains how a chemical reaction takes place. According to this
theory, two conditions must be satisfied for a chemical reaction to occur:
1) Particles of reactants must collide with one another in correct orientation;
and
2) Colliding particles must have sufficient energy.
No reaction can take place between two particles if they are far apart. They
must come in contact so that they may be able to break bonds, exchange atoms, and
form new bonds. Remember that chemical reactions involve bond breaking and bond
forming in the intramolecular level, that is inside the molecule. Therefore, right
amounts of energy and right orientation is needed.
Let us take this illustration as an example:

Source: https://mrtremblaycambridge.weebly.com/uploads/9/7/8/8/9788395/___5001988_orig.jpg

Nitrous oxide (NO) and ozone (O3) reacts with each other. If the orientation
of the molecules is incorrect, the collision will be ineffective. If there is an ineffective
collision, the reaction will not proceed. However, if the orientation of the molecules
is correct (meaning, they are in the right positions), the collision will be effective, and
there will be new products, NO2 and O2.
Let us have another illustration to show you the importance of the sufficient
amount of energy for the reaction to proceed.

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 Source: https://saintschemistry10.weebly.com/uploads/5/1/9/3/51932861/gw500h283_orig.jpg

In the first situation, the two different molecules are in the correct orientation.
However, the reactants are moving too slow. When molecules move too slow, it means
that their energies are not enough. Related to this is their kinetic energy. If there is
less kinetic energy, molecules move slower. If there is not enough energy, the
reactants will just bounce, and no reaction will happen. The energy needed for a
reaction to proceed is known as its activation energy.

Energy Diagrams
Most reactions involving neutral molecules cannot take place at all until they
have acquired the energy needed to stretch, bend, or otherwise distort one or more
bonds. This critical energy is known as the activation energy of the reaction.
Activation energy diagrams of the kind shown below plot the total energy input
to a reaction system as it proceeds from reactants to products. The x-axis shows the
direction of the reaction or the time it takes for the reaction to take place, and the y-
axis shows the energy needed for the reaction to proceed.

Source: https://upload.wikimedia.org/wikipedia/commons/6/6a/212_Enzymes-01.jpg

Let us analyze the first energy diagram. All molecules have inherent energy.
We call that energy potential energy. That is the reason why the reactants do not
start with zero energy. Remember, energy is neither created nor destroyed. So, when
we want to combine two reactants, we need to activate the reactants for them to form
new bonds and to break their old bonds. We call that energy activation energy. The
difference between the energy of the reactants versus the energy of the product is
called enthalpy. In the strictest chemistry sense, enthalpy is the sum of the internal
energy and the product of pressure and volume. We can see here that the energy of
the reactants is higher than the energy of the products. Therefore, is energy released
or is energy absorbed by the product? Energy is released. We call these reactions
exothermic reactions. The prefix exo- means release.

38
 Source: https://upload.wikimedia.org/wikipedia/commons/3/3a/Activation_Energy-c3bc.png

The diagram above now shows the reaction of H2 and Cl2 to form HCl. Again,
it requires correct orientation and the enough energy for the reaction to proceed. Is
the energy of the reactants less or more than the energy of the products? The energy
of the products is more than the energy of the reactants. Therefore, energy is
absorbed by the products. We now call these reactions endothermic reactions.
Shown below is a comparison chart between endothermic and exothermic
reactions.

Comparison Chart
BASIS FOR
ENDOTHERMIC REACTIONS EXOTHERMIC REACTIONS
COMPARISON

Meaning Chemical reactions Chemical reactions where
involving the use of energy the energy is released or
at the time of dissociation evolved in the form of
to form a new chemical heat is known as the
bond is known as the exothermic reaction.
endothermic reaction.

Energy The endothermic process The exothermic process
requires energy in the form evolves or releases in the
of heat. form of heat.

Enthalpy ΔH is positive, as heat is ΔH is negative, as heat is
(ΔH) absorbed. evolved.

Examples 1. Conversion of ice into 1. Formation of ice from
water vapor through water.
boiling, melting or 2. Burning of coal
evaporation. (combustion).
2. Breaking of the gas 3. The reaction between
molecules. water and the strong
3. Production of anhydrous acid.
salt from hydrate.

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Factors Affecting Rate of Reaction

A. Concentration
According to the collision theory, there must be collision between reacting
particles so that a reaction can occur.
An increase in the concentration of the reactant means that there will be
more particles colliding with each other in each time interval, thereby increasing the
chances that a chemical reaction occurs. Therefore, an increase in the
concentration of reactants causes an increase in the rate of the reaction.

In the illustration above, if there are more particles of the reactants inside a container, there
is more chance that they will collide with each other successfully. Concentration of each
reactant can be expressed through percent by volume, percent by mass, molarity, molality, and
other units. It can also be related to the reactants mass or volume.

B. Pressure
Increasing the pressure inside a container without changing the amount of
substance inside decreases the volume of the substance (by virtue of the gas laws).
The molecules will have less space to move and are more likely to collide successfully.
Pressure is expressed in pascals, atm, or mmHg. The effect of pressure in reaction
rates is very evident in gases as it follows laws such as the Dalton’s Law of Partial
Pressures.

C. Temperature
Temperature is directly proportional to kinetic energy. An increase in
temperature results in an increase in the kinetic energy of the reacting particles.
The increased speed of the particles causes a greater proportion of these
collisions to takes place in a given time. So, for example, with the reactants at 0 oC
and at 100oC, what temperature will the reaction proceed faster? At 100 oC as it
supplies activation energy quickly for the reaction to proceed. As a rule of thumb,
rate of reactions roughly doubles or triples for every 10 Co rise in temperature.

Source: https://cnx.org/resources/99129ce8ae5f998f706b70f2ed583002b106868e/CG12C3_004.png

40
D. Particle Size/Surface Area
Particle size has something to do with the rate of reaction. Sugar has two forms,
there is powdered sugar and there are sugar cubes. When you do coffee, which do
you think will have the faster dissolution? The powdered sugar or the sugar cubes?
The powdered sugar will dissolve faster.
Making the particle size of the sugar smaller increases the surface area exposed
which consequently results in an increase in contact area. Similarly, a reaction
between two immiscible liquids can only take place at the interface between them.
This interface can be increased by violent stirring which will create more areas for
interaction and, therefore, lead to an appreciable increase in the rate of reaction.
Another example, kindling wood burns faster than a whole log of wood. This is
because there is a larger surface area in contact with oxygen in kindling wood rather
than in a log of wood. Kerosene or gaas that is exposed over a wider area will burn
faster than the same amount of kerosene that is just confined in a drum. The particle
size and the surface area have a large effect on the rate of reaction.

Source: https://www.pathwayz.org/Node/Image/url/aHR0cHM6Ly9pLmltZ3VyLmNvbS9aejZnUmE5LnBuZz8x

E. Presence of a Catalyst
A catalyst is usually a substance that, when added to a reaction mixture,
increases the rate of the reaction but is itself unchanged after the reaction is
completed. However, there also substance that slow down reactions.
They are often referred to as inhibitors.
Let us analyze the following energy diagram for a reaction with and without
a catalyst.

Source:

https://upload.wikimedia.org/wikipedia/commons/f/fe/Carbonic_anhydrase_reaction_in_tissue.svg

What happens to the activation energy when a catalyst is present in the
reaction? The activation energy is lower. Therefore, the presence of a catalyst

41
speeds up a chemical reaction by lowering its activation energy. In this example,
the catalyst is the enzyme carbonic anhydrase. Enzymes in our body acts as
catalysts to speed up chemical reactions.

Activity 1: Reaction Rates
Directions: The following statements describe the factors that affect the rate of
chemical reactions. Use the word bank below to complete the statements.
WORDBANK
catalyst heat concentration
energy collision surface area
temperature rate of reaction