Grade 9 Chemistry Textbook PDF

Summary

This Ethiopian grade 9 chemistry textbook introduces fundamental chemistry concepts and principles. It covers the definition of chemistry, its relationship with other subjects including physics, biology, and the importance of chemistry in various applications. It discusses chemistry's role in everyday life, such as agriculture, medicine, food production, and construction. The book also includes examples, activities, and review exercises.

Full Transcript

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CHEMISTRY

CHEMISTRY
STUDENT TEXTBOOK
GRADE 9
CHEMISTRY
STUDENT TEXTBOOK
GRADE 9

STUDENT TEXTBOOK GRADE 9
Agriculture

Building
Bonding Construction Chemistry Medicine

Food
Production

Measurments
CHEMISTRY
Textbook

FEDERAL DEMOCRATIC REPUBLIC OF ETHIOPIA FEDERAL DEMOCRATIC REPUBLIC OF ETHIOPIA
MINISTRY OF EDUCATION MINISTRY OF EDUCATION
Ethiofetena.com Ethiopian No 1 Educational Website
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CHEMISTRY
STUDENT TEXTBOOK
GRADE 9
Writers:
Sisay Tadesse (Ph.D.)
Tegene Tesfaye (Ph.D.)
Editors:
Tesfaye Semela (Ph.D.) (Curriculum Editor)
Kenenisa Beresa (M.A.) (Language Editor)
Ahmed Awel (M.Sc.) (Content Editor)
Illustrator:
Abinet Tilahun (M.Sc.)
Designer:
Konno B. Hirbaye (M.Sc.)
Evaluators:
Legesse Adane (Ph.D.) (Reviewer)
Nega Gichile (B.Sc., M.A.) (Evaluator)
Sefiw Melesse (M.Sc.) (Evaluator)
Tolessa Mergo (B.Sc., M.Sc.) (Evaluator)

Federal Democratic Republic of Ethiopia Hawassa University
Ministry of Education
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First Published August 2023 by the Federal Democratic Republic of Ethiopia ,
Ministry of Education, under the General Education Quality Improvement Program for
Equity (GEQIP-E) supported by the World Bank, UK’s Department for International
Development/DFID-now merged with the Foreign, Common wealth and Development
Office/FCDO, Finland Ministry for Foreign Affairs, the Royal Norwegian Embassy,
United Nations Children’s Fund/UNICEF), the Global Partnership for Education (GPE),
and Danish Ministry of Foreign Affairs, through a Multi Donor Trust Fund.

© 2023 by the Federal Democratic Republic of Ethiopia, Ministry of Education. All
rights reserved. The moral rights of the author have been asserted. No part of this
textbook reproduced, copied in a retrieval system or transmitted in any form or by
any means including electronic, mechanical, magnetic, photocopying, recording or
otherwise, without the prior written permission of the Ministry of Education or licensing
in accordance with the Federal Democratic Republic of Ethiopia as expressed in the
Federal Negarit Gazeta, Proclamation No. 410/2004 - Copyright and Neighboring
Rights Protection.

The Ministry of Education wishes to thank the many individuals, groups and other
bodies involved – directly or indirectly – in publishing this Textbook. Special thanks
are due to Hawassa University for their huge contribution in the development of this
textbook in collaboration with Addis Ababa University, Bahir Dar University and
Jimma University.

Copyrighted materials used by permission of their owners. If you are the owner of
copyrighted material not cited or improperly cited, please contact the Ministry of
Education, Head Office, Arat Kilo, (P.O.Box 1367), Addis Ababa Ethiopia.

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ISBN: 978-9999 0 - 0 -016-1
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CONTENTS
1
Unit : CHEMISTRY AND ITS IMPORTANCE 1
1.1 Definition and Scope of Chemistry 2
1.2 Relationship between Chemistry and Other
Natural Sciences 6
1.3 The Role Chemistry Plays in Production and in
the Society 8
1.4 Some Common Chemical Industries in
Ethiopia 12
Unit Summary 15
Review Exercise 16

Unit 2
: MEASUREMENTS AND SCIENTIFIC METHODS 18
2.1 Measurements and Units in Chemistry 19
2.2 Chemistry as Experimental Science 35
Unit Summary 47
Review Exercise 48

Unit 3 : STRUCTURE OF THE ATOM 50
3.1 Historical Development of the Atomic
Theories of Matter 51
3.2 Fundamental Laws of Chemical Reactions 56
3.3 Atomic Theory 64
3.4 Discoveries of Fundamental Subatomic
Particles and the Atomic Nucleus 69
3.5 Composition of an Atom and the Isotopes 85
Unit Summary 101
Review Exercise 105

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Unit 4
: PERIODIC CLASSIFICATION OF ELEMENTS 109
4.1 Historical Development of Periodic
Classification of the Elements 110
4.2 Mendleev’s Classification of the Elements 113
4.3 The Modern Periodic Table 116
4.4 The Major Trends in the Periodic Table 125
Unit Summary 137
Review Exercise 138

Unit 5
: CHEMICAL BONDING 140
5.1 Chemical Bonding 141
5.2 Ionic Bonding 143
5.3 Covalent Bonding 154
5.4 Metallic Bonding 167
Unit Summary 171
Review Exercise 173

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U NI T 
CHEMISTRY AND ITS IMPORTANCE

Unit Outcomes

After completing the unit, you will be able to
 define chemistry;
 describe its’ scope;
 discuss the relationships between chemistry with physics, biology, medicine
geology and other subjects;
 describe the application of chemistry in the field of agriculture, medicine,
food production and building construction;
 name some common chemical industries in Ethiopia and their Product.

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Chemistry Grade 9

Make groups and discuss on the following questions and
present your discussion points to the class.
1. What do you think that the following materials are
made of?
Start-up Activity  the air you breath,
 the water you drink,
 the cloth you wear, and
 the food you eat?
2. Why is everything in this world changing from time
to time?
3. Is it important to know the materials from which
everything is made up of? Why?
4. Mention some of the materials you are using
commonly. Did you know who manufactured them?

Since chemistry is so fundamental to our world, it plays a role in everyone’s lives and
touches almost every aspect of our existence in some way. Chemistry is essential for
meeting our basic needs such as food, clothing, shelter, health, energy, clean air, water,
and soil. The question is how?

In this unit, the definition and the scope of chemistry, the relationship between chemistry
and other natural sciences, the role it plays in production and in the society, and some
common chemical industries in Ethiopia and their products are presented thoroughly.

1.1 Definition and Scope of Chemistry
In this section two aspects of chemistry are going to be dealt with. The first is definition
of chemistry, which will be followed by the scope of chemistry. We shall begin by
defining chemistry first.

1.1.1 Definition of Chemistry

At the end of this section, you will be able to define chemistry.

Students, form a group of three or four and discuss the
question given below. Present your discussion points to the
class when asked by your teacher.
1. Did you know what the composition of the salt you are
adding to your meal is?

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Chemistry and its Importance

2. What do you think will happen to the sugar crystals
when you add a teaspoon of it in a cup of tea and
stir it?
3. How can you distinguish table salt from sugar?
4. What happens to the wood when you burn it?
Activity 1.1
Chemistry is the science that deals with the properties, composition, and structure
of substances (elements and compounds), the transformations they undergo, and the
energy that is released or absorbed during these processes.

A substance is a particular kind of matter with uniform properties. Example, gold,
silver, water, soap, table salt, etc (Figure 1.1).

Matter is a physical substance, that which occupies space and possesses rest mass.
Example, book, pencil, television, stool, etc.

The property of a substance is its attribute, quality, or characteristic. Every substance,
in the universe in which we live, has its own properties by which we can distinguish it
from other substances. This is because every substance has its own unique composition
and structure. Example, water is a substance that has no color, taste, and shape.

Composition is the nature of something’s ingredients or constituents; how a whole
or mixture is made up. Example, table salt is chemically composed of the elements
sodium and chlorine. The stainless-steel spoons are solid solution (alloy) of chromium,
carbon and other elements.

The arrangement and relationships between the parts or elements of something
complex is known as its structure. Example, the school buildings are made up of roof,
ceiling, doors, windows, walls, and floor arranged in a certain order. The arrangement
of each of these parts are known as the structure of the school building.

Salt Sulphur Gold Silver
Figure 1.1 Substances around us.

Every substance in our environment is continuously changing from time to time due to
both external and internal forces. Due to this change, it transforms from one form into
the other. The transformation of a substance is a marked change in form, nature, or
appearance. These transformations are accompanied by energy changes.

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Exercise 1.1
1. Define the term chemistry.
2. Explain the meaning of the following phrases.
 property of a substance
 composition of a substance
 structure of a substance
 transformation of a substance

1.1.2 Scope of Chemistry
At the end of this section, you will be able to explain the scope of chemistry.

Students, form groups of three or four. Discuss the
following questions and present your discussion points to
the class.
1. How do you clean: your cloth when it gets dirt, the
dishes after eating meal, and your hand?
2. How does the butcher in your town measure the weight
of beef before selling it?
3. Do you know how the clothes and shoes you wear, the
tyres of automobiles, the different medicines you take
when you are ill, and the glasses in the windows of
your house are made?
4. What happens to the food in your body, after you
ate it?
Activity 1.2
The study of modern chemistry has many branches, but can generally be broken down
into five main disciplines, or areas of study:
i. Physical chemistry: It is the study of macroscopic properties, atomic properties,
and phenomena in chemical systems. A physical chemist may study such things as
the rates of chemical reactions, the energy transfers that occur in reactions, or the
physical structure of materials at the molecular level.
ii. Organic chemistry: It is the study of substances containing carbon. Carbon is one
of the most abundant elements on Earth and is capable of forming a tremendously
vast number of chemicals (over twenty million so far). Most of the chemicals found
in all living organisms are based on carbon.

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Chemistry and its Importance
iii. Inorganic chemistry: It is the study of substances that are not primarily based
on carbon. Inorganic chemicals are commonly found in rocks and minerals. One
current important area of inorganic chemistry deals with the design and properties
of materials involved in energy and information technology.
iv. Analytical chemistry: It is the study of the composition of matter. It focuses on
separating, identifying, and quantifying chemicals in samples of matter. An
analytical chemist may use complex instruments to analyze an unknown material
in order to determine its various components.
v. Biochemistry: It is the study of chemical processes that occur in living things. It may
cover anything from basic cellular processes up to understanding disease states so
that better treatments can be developed.

All of the aforementioned disciplines of Chemistry are highly engaged in taking
measurements, making observations, and using them to come to conclusions. Chemistry
is about looking for patterns in the way substances behave. Because living and non-
living things are made of matter Chemistry affects all aspects of life and most natural
events. The scope of Chemistry can be extended to explaining the natural world,
preparing people for career opportunities, and producing informed patriot citizens.

The scope of chemistry includes agriculture, medicine food production, and building
construction (Figure 1.2).

Figure 1.2 Some chemical products.

Chemistry, however, is not only involved in providing useful substances in the
areas of development and technology, but it can also result in very dangerous
substances that can negatively affect human being’s life and the environment
(eg. fluorochlorohydrocarbons, oxides of nitrogen, carbon, and sulphur).

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Exercise 1.2
Provide correct answer for the following questions.
1. List down examples of chemicals or chemical products that are used in the
following areas:
 Agriculture
 Medicine
 Food production
 Building construction

Hint: Refer Figure 1.2 above.
2. Search on the internet, and write down some of the problems caused by
dangerous chemicals affecting the environment.
3. Which of the problems you find in question #2 above are observed in your
locality?
4. What do you think is the solution to the problem(s)? Remember that you are
an Ethiopian citizen, and have the responsibility of protecting the nation from
the problems caused due to chemical substances.

1.2 The Relationship Between Chemistry and Other Natural Sciences
At the end of this section, you will be able to discuss the relationship of chemistry
with physics, biology, medicine, geology and other subjects.

Students, form groups of three or four, and discuss the
following questions. Then, present your discussion points to
the class, when asked by your teacher.
1. List down the subjects that are categorized under
natural science.
2. In biology class you may studied about photosynthesis.
Is it possible to explain photosynthesis without having
the knowledge of a chemical reaction? Reason out
Activity 1.3 why?

Chemistry is one branch of science. Science is the process by which we learn about
the natural universe by observing, testing, and then generating models that explain
our observations. Because the physical universe is so vast, there are many different
branches of science ( Figure 1.3). Thus, biology is the study of living things, and geology
is the study of rocks and the earth. Physics is the branch of science concerned with the
nature and properties of matter and energy.

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Chemistry and its Importance

Figure 1.3 The relationships between natural sciences and chemistry.

Although we divide science into different fields, there is much overlap among them.
For example, some biologists and chemists work in both fields so much that their
work is called Biochemistry. Biochemistry is the study of the chemical processes
occurring in living matter. To give you a specific example, there are chemists who
are working on the isolation, characterization and biological activities of compounds
from medicinal plants. Similarly, Geology and Chemistry overlap in the field called
Geochemistry. Geochemistry is defined as the study of the processes that control
the abundance, composition, and distribution of chemical compounds and isotopes
in geologic environments. Chemistry and Physics overlap in the areas of atomic and
small molecule properties. Both of them deal with matter and energy.

Physical chemistry is the branch of chemistry concerned with the application of the
techniques and theories of physics to the study of chemical systems. Chemical physics is
a sub discipline of chemistry and physics that investigates physicochemical phenomena
using techniques from atomic and molecular physics and condensed matter physics. It is
the branch of physics that studies chemical processes from the point of view of physics.
Chemistry and Medicine are related in the area of Medicinal chemistry.

Figure 1.3 shows how many of the individual fields of science are related. At some
level, all of these fields depend on the matter as they all involve ‘stuff’. Because of
this, chemistry has been called the ‘central science’ linking them all together.

Exercise 1.3
Provide correct answer the following questions.
1. What aspects of nature are studied in
 Physics?  Geochemistry?
 Biology?  Biochemistry?
 Geology?  Physical chemistry?
2. What are the regions of an overlap between
 Chemistry and biology?  Chemistry and geology?
 Chemistry and physics?

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1.3 The Role Chemistry Plays in Production and in the Society

At the end of this section, you will be able to describe the application of chemistry in
the field of agriculture, medicine, food production and building construction.

Students, form groups of two or three and discuss the
questions below. Present your discussion points to the class
when asked by your teacher.
1. What are the common types of fertilizers the Ethiopian
farmers employ to increase their crop productivity?
2. Give some examples of household materials that are
used for cleaning, baking ‘diffo dabbo’, disinfecting
salad, preserving raw meat, and hair treatment.
3. What types of medications (traditional and modern)
are used to treat the various diseases you know?
4. What are the common types of fuels that are sold in
the gas stations?
Activity 1.4
There are many instances in your everyday life that involves the knowledge of
chemistry, its applications, and its rules. Let us look at some of them one by one.

A. Agriculture
The study of chemistry has brought the world with chemical fertilizers such as calcium
super phosphate, urea, ammonium sulphate, and sodium nitrate. These chemicals
have assisted greatly in increasing the yield of fruits, vegetables, and other crops
(Figure 1.4). Chemistry has been effective in the manufacture of pesticides, which
have lessened the crop damage. Depending on the targeted pest, pesticides include
fungicides, herbicides, and insecticides. Thus, we can supply to the ever-growing
demand for food. Chemistry has also an important role in the manufacturing of better-
quality plastic pipes for irrigation, and is commonly used in farming. This has massively
increased irrigation resulting in a better climate in which the crops grow.

B. Food Production
Other than its great contribution in the production of different agricultural products,
chemistry has led to the discovery of different kinds of food preservatives. These
chemicals have greatly assisted to preserve food products for a longer period. It has
given methods to test the presence of adulterants which ensure the supply of pure
foodstuff. Consumers have benefited from new technologies that have increased their
food’s availability, appearance, nutritional contents and flavor. A local example of
food processing and keeping it for a longer period of time is the preservation of raw
meat.

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Chemistry and its Importance

Figure 1.4 Agricultural products.

Students, form groups of two or three and discuss the
questions below. Present your discussion points to the class
when asked by your teacher.
1. What are the common pests that damage crops in
your locality?
2. What are the common herbs that reduce the production
of food in your locality?
3. What are the commercial and traditional pesticides
and herbicides used by the local farmers?
Activity 1.5

C. Medicine
Chemistry has provided mankind with a large number of life-saving medicines. We
could find a cure for dysentery and pneumonia as a result of the discovery of Sulphur
drugs and penicillin. Besides this, life-saving drugs like cisplatin and Taxol are effective
for cancer therapy, and AZT is used for AIDS victims. Although AZT does not cure HIV-
AIDS, it fights the multiplication of the virus thereby prolonging the life of the victim.
HIV-AIDS as we know is a pandemic that has no curative medication. We need to
prevent ourselves from this killer disease by being Abstain, Be faithful or reduce the
number of your sex partners, and/or use a Condom.

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Chemistry Grade 9

Common Drugs Chemistry Provided

Disinfectants Analgesics Anesthetics Antibiotics Antiseptics Tranquilizers

 Disinfectants: Are used to kill the microbe present in toilets, floors, and drains.
The sanitizers we use for Covid-19 belong to this group.
 Analgesics: An analgesic or painkiller is any member of the group of drugs used
to achieve analgesia, relief from pain.
 Anesthetics: Has made medical operations more and more effective via relieving
pain.
 Antibiotics: Are used to control infection and cure diseases.
 Antiseptics: Are used to contamination of the wounds by bacteria.
 Tranquillizers: To reduce tension and bring about calm and peace to patients
suffering from mental diseases.

Students, form groups of two or three and discuss the
questions below. Present your discussion points to the
class when asked by your teacher.
1. Search on the Internet or from other sources
and find examples of analgesics, antibiotics,
tranquilizers, antiseptics, disinfectants, anesthetics,
and insecticides.
2. Describe the composition and preparation of hand
disinfectant or hand sanitizer.
Activity 1.6

D. Building Construction Materials
By providing building resources such as glass, steel and cement, chemistry helps in the
construction of safer houses and multi-story structures. It also helps in the construction
of long-lasting and durable dams and bridges. The best example here could be
the Grand Ethiopian Renaissance Dam (GERD) which is under construction in the
Benishangul-Gumuz Region (Figure 1.5). The GERD is a 6,450 MW hydro power
project nearing completion on the Blue Nile in Ethiopia, located about 30 km upstream
of the border with Sudan. It will be the largest hydro power project in Africa.

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Chemistry and its Importance

Figure 1.5 The Grand Ethiopian Renaissance Dam, Benishangul Gumuz Region, Ethiopia.

Figure 1.6 The role of chemistry in different sectors.

Exercise 1.4
Provide correct answer for the following questions.
1. List down the role of chemistry in your locality. Draw a spider diagram of
your own.
2. What problems, do you think, will be observed in the livelihood of the
community in which you are living in the absence of enough knowledge of
chemistry?
3. In your opinion, what further roles can chemistry play?

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Chemistry Grade 9
1.4 Some Common Chemical Industries in Ethiopia
At the end of this section, you will be able to name some common chemical industries
found in Ethiopia and their products.

Students, make groups of how two or three and do
the following activities. Present your answers to the
class when asked by your teacher.
1. List down some of the house hold chemicals?
2. Do you know which industry is producing them?
3. List down the common chemical industries
(enterprises) found in your locality or in the vicinity
of your town. Which chemicals or chemical products
are they producing?
Activity 1.7
An industry is defined as an economic activity concerned with the processing of raw
materials and the manufacture of goods in factories. It can also be interpreted as
a group of companies that are linked based on their primary business activities.
Individual companies are generally categorized into an industry based on their
largest sources of revenue. The Ethiopian government is highly engaged in expanding
industries in the past two decades. As part of this expansion several industrial parks
have been under construction (Figure 1.7).

Figure 1.7 One of the industrial parks found in Ethiopia.

The chemical industries comprise the companies that manufacture inorganic- and
organic-industrial chemicals, explosives, fragrances, agrochemicals, polymers and

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Chemistry and its Importance
rubber, ceramic products, petrochemicals, oleochemicals (oils, fats, and waxes), and
flavors. Central to the world economy, it converts natural resources (oil, natural gas,
air, water, metals, and minerals) into diverse products. They are further categorized
into industrial inorganic chemicals; plastics, materials, and synthetics; drugs; soap,
cleaners, and toilet goods; paints and allied products; industrial organic chemicals;
agricultural chemicals; and miscellaneous chemical products.
The chemical products mean products manufactured, processed, sold, or distributed
by the company that are chemical substances, or that contained chemical substances.
Three general classes of products are (1) basic chemicals such as alkalis, acids, organic
chemicals, and salts (2) chemical products to be used in further manufactures such as
plastic materials, synthetic fibers, pigments, and dry colors, and (3) finished chemical
products to be used for ultimate consumption such as cosmetics, drugs, and soaps; or
to be used as materials or supplies in other industries such as fertilizers, paints, and
explosives.

Currently, there are several medium and large-scale chemical and chemical products
industries (enterprises) in Ethiopia (Table 1.1). These enterprises produce chemicals
like aluminum sulphate, caustic soda, soda ash, carbon dioxide, bleaching chemicals,
magnesium oxide, pesticides, and chemical products like soap and detergent, cement,
paints, building materials, cosmetics, plastic, natural gum, candle, glass, sugar, tyre,
pulp and paper, pharmaceuticals and tobacco.

Table 1.1 Some of the large and medium scale chemical enterprises in Ethiopia.
No. Name of the Enterprise City Product
1 Chorra Gas & Chemical A.A Plastic, chemicals, petroleum products
products
2 Chorra Gas & Chemical A.A Aluminum sulphate and sulphuric acid
products
3 Ziway Caustic Soda Ziway Sodium hydroxide
factory
4 Abijata Soda Ash Bulbula Trona (Na3H(CO3)2.2H2O)
Factory
5 Repi Soap & Detergent A.A Soap and detergent
P.L.C
6 Adola Magnesium Adolla Magnesium oxide
Oxide Factory
7 Adami Tulu Pesticide Adami-Tulu Formulates malathion, endosulfan,
Processing Plant diazinon, fenitrothion and dimethoate
8 Nefas Silk Paints A.A Paints, varnishes, antirusts and glues
factory

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No. Name of the Enterprise City Product
9 Modern Building A.A Cement and cement products,
Industries ceramics, paints, sanitary ware,
adhesives, glues, plastic rubber,
terrazzo tiles, cultured marble
10 Kadisco Chemical A.A Paints, coatings and adhesives
Industry
11 Tadesse Filatea PLC Woliso Soap, detergent, corrugated iron,
nail, infant milk formula
12 Etab Laundry Soap Hawassa Soap and detergent
Factory
13 Get-Eshet Detergent Bishoftu Detergent products and Leather
Manufacturing and chemical inputs
Packing P.L.C
14 Ethio-Asia Industries S.C A.A Soap and detergent
15 Y.B Cosmetics Sheger city Cosmetics and perfume
16 Mekab PLC (Cosmetics) A.A Hair oil, shampoo, conditioner, body
oil, vaseline, body lotion, detergents
and plastic mouldings
17 BEKAS Chemicals PLC A.A Detergents, cosmetic products,
plastic packing materials, industrial
surfactants and putty
18 Arbaminch Textile Arbaminch Textile and fabric products
Share compary
19 Teamco Soap Factory Burayu Soap and detergent
Note: A.A stands for Addis Ababa.

Other chemical product industries in Ethiopia.
 Cement (Mugher, Diredawa, Mesobo, Derba, Midroc, Dangote)
 Sugar (Metehara, Wonji, Finchaa, Omokuraz)
 Paper and pulp (Wonji)
 Pharmaceuticals (Addis, Ethiopia, Adigrat)
 Tyre (Horizon Addis Tyre)

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Chemistry and its Importance

Exercise 1.5
Provide the correct answer for the following questions.
1. List the common names together with the chemical names, formula, and use
of 10 household chemicals.
2. Browse the Internet or use other sources and find out 10 other household
chemicals that are commonly used in different homes with their corresponding
molecular formula, chemical names, and use.
3. List at least 15 chemical industries that are found in Ethiopia.

Project work 1.1
An industrial trip to the local industries
In this project, you will be able to visit a local chemical industry and present your
observations to the class in group.
Students, your teacher will arrange an industrial tour so that you will practically
observe the raw materials, the chemical processes involved, and the finished products
in the industries that are located in your vicinity. You are required to write a report
and present it to the class in group.

Key Terms of the Unit
 Analgesics  Composition  Metallurgy
 Antibiotics  Disinfectants  Property
 Anesthetics  Energy  Structure
 Antiseptics  Industry  Substance
 Chemistry  Insecticides  Tranquilizers
 Chemical products  Matter
 Chemical industry
Unit Summary
Chemistry is the science that deals with the properties, compositions, and structures
of substances, the transformations they undergo, and the energy that is released or
absorbed during these processes.

The study of modern chemistry has many branches, but can generally be broken down
into five main disciplines, or areas of study: Organic chemistry, Inorganic chemistry,
Physical chemistry, Analytic chemistry and Biochemistry. The scope of chemistry includes
agriculture, medicine, food production, and building construction. Because living and
non-living things are made up of matter, chemistry affects all aspects of life, and most
natural events. The scope of chemistry can also be extended to explaining the natural
world, preparing people for career opportunities, and producing informed patriot
citizens.
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Chemistry Grade 9
Chemistry is the central science in the natural sciences. Being one of the basic sciences
Chemistry is related to other natural sciences like Biology, Physics, Geology, Medicine,
and Mathematics. Chemistry and Biology are related by the metabolic processes
occurring inside living matter known as Biochemistry. Chemistry and Geology are
related by the processes that control the abundance, composition, and distribution of
chemical compounds and isotopes inside the crust of the earth known as Geochemistry.
A sub-discipline of chemistry and physics that investigates physicochemical phenomena
using techniques from atomic and molecular physics and condensed matter physics
is known as Chemical physics. Chemistry and Medicine are related by a discipline
that encloses the design, development, and synthesis of pharmaceutical drugs called
Medicinal chemistry.

Since Chemistry is so fundamental to our world, it plays a role in everyone’s lives
and touches almost every aspect of our existence in some way. Chemistry is essential
for meeting our basic needs such as food, clothing, shelter, health, energy, and clean
air, water, and soil. Chemistry, however, can also affect our environment negatively
through production of toxic substances. The release of theses toxic substances into the
environment results in climate change, the prime issue the world is facing currently.
It is, therefore, high time to seek for solution to this problem by using our chemical
knowledge.

Chemistry plays a significant role in the advancement and growth of several industries.
There are several chemical and chemical products industries that produce a number
of chemicals and chemical products. One way of categorizing them is into industrial
inorganic chemicals; plastics, materials, and synthetics; drugs; soap, cleaners, and
toilet goods; paints and allied products; industrial organic chemicals; agricultural
chemicals; and miscellaneous chemical products.

The Ethiopian government is working hard in establishing Industrial Zones throughout
the nation. Currently, there are several medium and large-scale chemical and chemical
products industries (enterprises) in Ethiopia. These enterprises produce chemicals like
aluminum sulphate, caustic soda, soda ash, carbon dioxide, bleaching chemicals,
magnesium oxide, pesticides; and chemical products like soap and detergent, cement,
paints, building materials, cosmetics, plastic, natural gum, candle, glass, sugar, tyre,
pulp and paper, pharmaceuticals and tobacco.
Review Exercise
Part I: Basic Level Questions.
Identify each of the following statements as ‘True’ or ‘False’. Give your reason(s) for
false statements.
1. Chemistry is a science that deals with the study of the way living things behave.
2. Every substance in the universe, in which we live, has its own properties by which
we can distinguish it from other substances.

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Chemistry and its Importance
3. The transformation of a substance is a marked change in form, nature, or
appearance.
4. The study of chemistry involves only microscopic information.
5. Organic chemistry is the study of chemicals that are not based on carbon.

Part II: Intermediary Level Questions.
Fill in the blank spaces.
6. The property of a substance is its ___________ , ___________ or ____________.
7. ___________ is the nature of something’s ingredients or constituents; the way in
which a whole or mixture is made up.
8. The arrangement of and relations between the parts or elements of something
complex is known as its ___________.
9. ___________ is a power derived from the utilization of physical or chemical
resources, especially to provide light and heat.
10. ___________ is the study of macroscopic properties, atomic properties, and
phenomena in chemical systems.
11. ___________ is the study of the composition of matter.

Part III: Challenge Level Questions.
Provide appropriate answers to the following questions.
12. Define the terms industry, chemical industry, and chemical products.
13. What are the roles chemistry played in production and society?
14. How does chemistry play a role in increasing comfort, pleasure, and luxuries?
15. Mention at least 10 chemical industries found in Ethiopia and their chemical
products.
16. Which branch of chemistry has the highest scope? Why?
17. What are the five fields of chemistry?
18. What will be the future efforts of chemistry?
19. What jobs can you do with chemistry?

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U NI T 
MEASUREMENTS AND SCIENTIFIC METHODS

Unit Outcomes

After completing the unit, you will be able to
 use proper SI units;
 identify the causes of uncertainty in measurement;
 express the result of any calculation involving experimental data to the
appropriate number of decimal places or significant figures;
 apply scientific methods in solving problems;
 demonstrate an understanding of experimental skills in chemistry;
 demonstrate a knowledge of basic laboratory apparatuses and safety
rules;
 describe scientific inquiry skills along this unit: observing, inferring,
predicting, comparing & contrasting, communicating, analyzing,
classifying, applying, theorizing, measuring, asking question, developing
hypothesis, designing experiment, interpreting data, drawing conclusion,
making generalizations and problem solving.
Ethiofetena.com Ethiopian No 1 Educational Website

Measurements and Scientific Methods
2.1 Measurements and Units in Chemistry
Learning competencies
At the end of this section, you should be able to
 list the seven SI units and their prefixes;
 describe the seven SI units and their prefixes;
 write the names and symbols of derived SI units;
 use the factor label method for solving problems and making conversion of SI
units;
 describe uncertainty of measurement;
 identify the digits that are certain and the ones that are uncertain given a
number representing measurement;
 identify causes of uncertainty in measurement;
 define precision and accuracy;
 estimate the precision possible for any instrument they use in the laboratory;
 explain systematic and random errors;
 analyze given data in terms of precision and accuracy;
 define significant figures;
 determine the number of significant figures in a calculated result;
 use the scientific notation in writing very large or very small numbers.

Conduct the following activity and present your finding to
the class.
1. In group, discuss and list down different traditional
ways of measuring mass of solid and liquid substances
Start-up Activity sold in the market places in your area.
2. Mention indigenous methods of measurements
(length, mass, time, volume)

Measurement is the comparison of a physical quantity to be measured with a unit of
measurement that is, with a fixed standard of measurement. On a centimeter scale, the
centimeter unit is the standard of comparison. In traditional markets people buy and
sell goods by estimating their size in traditional way or use traditional measurement
method. Figure 2.1 shows traditional market and people exchanging goods by
estimating their size using indigenous methods of measurements.

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Chemistry Grade 9

Figure 2.1 Traditional market.

The study of chemistry depends heavily on measurement. For instance, chemists
use measurements to compare the properties of different substances and to assess
changes resulting from an experiment. A number of common devices enable us to make
simple measurements of a substance’s properties: The meter stick measures length; the
burette, the pipette, the graduated cylinder, and the volumetric flask measure volume
(see Figure 2.2); the balance measures mass; the thermometer measures temperature.

The instruments illustrated on Figure 2.2 provide measurements of macroscopic
properties, which can be determined directly. Microscopic properties, on the atomic
or molecular scale, must be determined by an indirect method. A measured quantity
is usually written as a number with an appropriate unit. To say the distance between
Addis Ababa and Hawassa by car along a certain route is 275 is meaningless. We
must specify that the distance is 275 kilometers. In science, units are essential to state
measurements correctly.

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Measurements and Scientific Methods

Figure 2.2 Some common measuring devices found in a chemistry laboratory.

Conduct the following activity and present your finding to
the class.
a. Using thermometer with oC and oF scale measure your
body temperature. Compare the results in oC with the
result in oF.
b. What is the distance between Addis Ababa and your
town (village) in kilometers?
c. Which basic SI units are appropriate to express the:
i. average room temperature, and
ii. time duration for the earth to have one rotation
A ctivity 2.1 around its axis?

2.1.1 SI Units (The International System of Units)
For many years, scientists recorded measurements in metric units, which are related
decimally, that is, by powers of 10. In 1960, however, the General Conference of
Weights and Measures, the international authority on units, proposed a revised metric

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Chemistry Grade 9
system called the International System of Units.

Table 2.1 shows the seven SI base units. Measurements that we will utilize frequently in
our study of chemistry include time, mass, volume, density, and temperature.

Table 2.1 SI Base Units.
Base Quantity Name of Unit Symbol
Length Meter m
Mass Kilogram kg
Time Second s
Electrical current Ampere A
Temperature Kelvin K
Amount of substance Mole mol
Luminous intensity Candela cd
Heat and Temperature
Temperature measures the intensity of heat, the “hotness” or “coldness” of a body.
Heat is a form of energy that always flows spontaneously from a hotter body to a
colder body — never in the reverse direction.

Relationships among the three temperature scales are illustrated in Figure 2.4. Between
the freezing point of water and the boiling point of water, there are 100 steps (°C or
Kelvins, respectively) on the Celsius and Kelvin scales. Thus, the “degree” is the same
size on the Celsius and Kelvin scales. But every Kelvin temperature is 273.15 units
above the corresponding Celsius temperature. The relationship between these two
scales is as follows:

K = 0C + 273.15 0C or 0C = K - 273.150
In the SI system, “degrees Kelvin” are abbreviated simply as K rather than °K and
are called kelvins.

Any temperature change has the same numerical value whether expressed on the
Celsius scale or on the Kelvin scale. For example, a change from 25°C to 59°C
represents a change of 34 Celsius degrees. Converting these to the Kelvin scale,
the same change is expressed as (273 + 25) = 298 K to (59 + 273) = 332 K, or a
change of 34 kelvins.

Comparing the Fahrenheit and Celsius scales, we find that the intervals between
the same reference points are 180 Fahrenheit degrees and 100 Celsius degrees,
respectively. Thus, a Fahrenheit degree must be smaller than a Celsius degree. It
takes 180 Fahrenheit degrees to cover the same temperature interval as 100 Celsius
degrees. From this information, we can construct the unit factors for temperature
changes:

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Measurements and Scientific Methods
180 0F or 1.8 0C and 100 0C 1.0 0C
or
100 0C 1.0 0F 180 0F 1.8 0F

But the starting points of the two scales are different, so we cannot convert a
temperature on one scale to a temperature on the other just by multiplying by the unit
factor. In converting from °F to °C, we must subtract 32 Fahrenheit degrees to reach
the zero point on the Celsius scale (Figure 2.3).

 1.8o F   9o F  1.0o C o 5o C o
o
F =  x oC × o  + 32o F =  x oC × o  + 32o F and C
o
=
1.8
(
o
F
x F − 32 )
o
F=
9 o (
F
x F − 32o F )
 1.0 C   5 C 

Figure 2.3 The relationships among the Kelvin, Celsius (centigrade), and Fahrenheit
temperature scales.

Example 2.1: Temperature conversion
When the temperature reaches “100.°F in the shade,” it’s hot. What is this temperature
on the Celsius scale?
Solution
1.0o C o
We use the relationship
= o
C o
1.8 F
( x F − 32o F )

1.0o C 1.0o C
to carry out the desired conversion.
= o
C
1.8o F
(100 o
F − =
32 o
F ) 1.8o F
=
(68o
F ) 38o C

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Exercise 2.1
Temperature Conversion
When the absolute temperature is 400 K, what is the Fahrenheit temperature?

2.1.2 Derived Units
All other SI units of measurement can be derived from base units (called derived units).
Table 2.2 shows some of the common derived units. Once base units have been defined
for a system of measurement, you can derive other units from them. You do this by
using the base units in equations that define other physical quantities. For example,
area is defined as length times width. Therefore,

SI unit of area = (SI unit of length) × (SI unit of width)
From this, SI unit of area is meter × meter, or m2. Similarly, speed is defined as the
rate of change of distance with time; that is, speed = distance/time. Consequently,

SI unit of distance
SI unit of speed =
SI unit of
me

The SI unit of speed is meters per second (that is, meters divided by seconds). The unit
is symbolized m/s or m s-1. The unit of speed is an example of an SI derived unit, which
is a unit derived by combining SI base units. Table 2.2 displays a number of derived
units. Volume and density are discussed in this section.

Volume
Volume is defined as length cubed and has the SI unit of cubic meter (m3). This is too
large a unit for normal laboratory work, so we use either cubic decimeters (dm3) or
cubic centimeters (cm3, also written cc). Traditionally, chemists have used the liter (L),
which is a unit of volume equal to a cubic decimeter. In fact, most laboratory glassware
(Figure 2.2) is calibrated in liters or milliliters (1000 mL = 1 L). Because 1 dm equals
10 cm, a cubic decimeter, or one liter, equals (10 cm)3 = 1000 cm3. Therefore, a
milliliter equals a cubic centimeter. In summary,

1 L = 1 dm3 and 1 mL = 1 cm3.

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Measurements and Scientific Methods
Table 2.2 Derived units.
Quantity Definition of Quantity SI Unit
Area Length squared m2
Volume Length cubed m3
Density Mass per unit volume kg/m3
Speed Distance traveled per unit time m/s
Acceleration Speed changed per unit time m/s2
Force Mass times acceleration of object kg.m/s2 (= newton, N)
Pressure Force per unit area kg/(m.s2)(= pascal,Pa)
Energy Force times distance traveled kg.m2/s2 (= joule,J)

Density
The density of an object is its mass per unit volume. You can express this as

m
d=
v

where d is the density, m is the mass, and V is the volume. Suppose an object has a
mass of 15.0 g and a volume of 10.0 cm3. Therefore, the density will be

15.0 g
d= = 1.50 g/cm3
10.0 cm3

The density of the object is 1.50 g/cm3.
Density is an important characteristic property of a material. Water, for example, has
a density of 1.000 g/cm3 at 4 oC and a density of 0.998 g/cm3 at 20 oC. Lead has
a density of 11.3 g/cm3 at 20 oC.

Density can also be useful in determining whether a substance is pure. Consider a gold
bar whose purity is questioned. The metals likely to be mixed with gold, such as silver
or copper, have lower densities than gold. Therefore, an adulterated (impure) gold
bar can be expected to be far less dense than pure gold.

Example 2.1: Calculating the density of a substance
A colorless liquid, used as a solvent (a liquid that dissolve other substances), is believed
to be one of the following (Table 2.3):

Table 2.3 Density of different liquids.
Substance Density (in g/mL)
n-butyl alcohol 0.810
ethylene glycol 1.114
isopropyl alcohol 0.785
toluene 0.866

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Chemistry Grade 9
To identify the substance, Chaltu determined its density. By pouring a sample of the
liquid into a graduated cylinder, she found that the volume was 35.1 mL. She also
found that the sample weighed 30.5 g. What was the density of the liquid? What was
the substance?
Solution
The solution to this problem lies in finding the density of the unknown substance. Once
the density of the unknown substance is known, you can compare it to the list of known
substances presented in the problem and look for a match. Density is the relationship
of the mass of a substance per volume of that substance. Expressed as an equation,
density is the mass divided by the volume: d = m/V.

You substitute 30.5 g for the mass and35.1 mL for the volume into the equation.

m 30.5 g
d= = = 0.869 g/mL
v 35.1mL

The density of the liquid equals that of toluene (within experimental error).

Answer Check Always be sure to report the density in the units used when performing
the calculation. Density is not always reported in units of g/ml org/cm3, for example;
gases are often reported with the units of g/L.

Exercise 2.2
A piece of metal wire has a volume of 20.2 cm3 and a mass of 159 g. What
is the density of the metal? We know that the metal is manganese, iron, or
nickel, and these have densities of 7.21 g/cm3, 7.87 g/cm3, and 8.90 g/cm3,
respectively. From which metal is the wire made?

2.1.3 Common Prefixes Used in SI Units
The factor expressed as a factor to the power of ten, SI/ metric prefix, the symbol
used and the actual decimal number are tabulated in Table 2.4. They are widely
used and are easy to add to the basic units. Like metric units, SI units are modified in
decimal fashion by a series of prefixes, as shown in Table 2.4. Measurements that we
will utilize frequently in our study of chemistry include time, mass, volume, density, and
temperature.

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Measurements and Scientific Methods
Table 2.4 SI/ Metric Units, Symbols and Numbers.
Factor Prefix Symbol Decimal Example
1012 Tera T 1,000,000,000,000 1 Terameter (Tm)=1×1012 m
109 Giga G 1,000,000,000 1 Gigameter (Gm)= 1×109 m
106 Mega M 1,000,000 1 Megameter (Mm)= 1×106 m
103 Kilo k 1,000 1 kilometer (km)= 1×103 m
102 Hecto h 100 1 hectometer (hm)= 1×102 m
101 Deca da 10 1 decameter (dam)= 1×101 m
10-1 Deci d 0.1 1 decimeter (dm)= 1×10-1 m
10-2 Centi c 0.01 1 centimeter (cm)= 1×10-2 m
10-3 milli- m 0.001 1 millimeter (mm)= 1×10-3 m
10-6 Micro µ 0.000 001 1 micrometer (µm)= 1×10-6 m
10-9 Nano n 0.000 000 001 1 nanometer (nm)= 1×10-9 m
10-12 Pico p 0.000 000 000 001 1 picometer (pm)= 1×10-12 m

Examples of SI prefixes
The SI prefixes/ metric prefixes are easily used as demonstrated by the few simple
examples given below:

 1 Megawatt = 1,000,000 watts
 1 kilogram = 1,000 grams
 1 µF = 1 microFarad = 1/1,000,000 Farad

Along with these the abbreviations or symbols can also be used. For example, kV for
kilovolts, kW for kilowatts, and km for kilometer. The other symbols or abbreviations
can be used in exactly the same manner.

2.1.4 Uncertainty in Measurements
Whenever you measure something, there is always some uncertainty. There are two
categories of uncertainty: systematic and random.
1. Systematic uncertainties are those which consistently cause the value to be too
large or too small. Systematic uncertainties include such things as reaction time,
inaccurate meter sticks, optical parallax and miscalibrated balances. In principle,
systematic uncertainties can be eliminated if you know they exist.
2. Random uncertainties are variations in the measurements that occur without a pre-
dictable pattern. If you make precise measurements, these uncertainties arise from
the estimated part of the measurement. Random uncertainty can be reduced, but
never eliminated. We need a technique to report the contribution.

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Chemistry Grade 9
The uncertainty shall rather be understood as an interval within which the result can be
found with a given probability. Thus, the result will be within the interval but all values
within the interval have the same probability to represent the result.

Except when all the numbers involved are integers (for example, in counting the number
of students in a class), obtaining the exact value of the quantity under investigation
is often impossible. For this reason, it is important to indicate the margin of error in
a measurement by clearly indicating the number of significant figures, which are the
meaningful digits in a measured or calculated quantity. When significant figures are
used, the last digit is understood to be uncertain. For example, we might measure the
volume of a given amount of liquid using a graduated cylinder (see Figure 2.4) with
a scale that gives an uncertainty of 1 mL in the measurement. If the volume is found
to be 6 mL, then the actual volume is in the range of 5 mL to 7 mL. We represent the
volume of the liquid as (6±1) mL. In this case, there is only one significant figure (the
digit 6) that is uncertain by either plus or minus 1 mL. For greater accuracy, we might
use a graduated cylinder that has finer divisions, so that the volume we measure is now
uncertain by only 0.1 mL. If the volume of the liquid is now found to be 6.0 mL, we may
express the quantity as (6.0± 0.1) mL, and the actual value is somewhere between
5.9 mL and 6.1 mL. We can further improve the measuring device and obtain more
significant figures, but in every case, the last digit is always uncertain; the amount of
this uncertainty depends on the particular measuring device we use and the user’s
ability.

Figure 2.4 Uncertainty in volume measurement using a measuring cylinder.

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Measurements and Scientific Methods

Conduct the following activity and present your finding to
the class.
1. Make a chain of paper clips or other objects of
uniform length. Then use a meter stick to measure a
series of lengths on the chain. For example, measure
sections containing one, two, three, etc., clips. Record
your results and share them with your classmates.
2. Using laboratory scale, take several mass reading
for one, two, three objects of uniform size. You can
use any convenient objects you find in the laboratory.
Record your results and discuss them in your group.
Focus especially on the similarities and differences in
your measurement. Did you all find the same reading
for the same object? What do you think are the cause
of the uncertainties, if any? Discuss the results with the
Activity 2.2 rest of the class.

Calculating uncertainties
There are several techniques that will produce an estimate of the uncertainty in the
value of the mean. Since we are expecting students to produce an estimate of the
uncertainty any suitable value that indicates half the range is acceptable.

Example 2.2: A student measures the diameter of a metal canister using a ruler
graduated in mm and records these results:
Diameter/mm
Reading 1 Reading 2 Reading 3 Mean
66 65 61 64

The uncertainty in the mean value (64 mm) can be calculated as follows:

a. Using the half range
The range of readings is 61 mm – 66 mm so half the range is used to determine the
uncertainty.
Uncertainty in the mean diameter = (66 mm – 61 mm)/2 = 2.5 mm
Therefore, the diameter of the metal canister is 64 mm ± 2.5 mm.
Since a ruler graduated in mm could easily be read to ± 0.5 mm, it is acceptable to
quote the uncertainty as ± 2.5 mm for this experiment.

b. Using the reading furthest from the mean
In this case, the measurement of 61 mm is further from the average value than 66 mm
therefore we can use this value to calculate the uncertainty in the mean.
Uncertainty in the mean diameter = 64 mm – 61 mm = 3 mm.

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Chemistry Grade 9
Therefore, the diameter of the metal canister is 64 mm ± 3 mm.

c. Using the resolution of the instrument
This is used if a single reading is taken or if repeated readings have the same value.
This is because there is an uncertainty in the measurement because the instrument used
to take the measurement has its own limitations. If the three readings obtained above
were all 64 mm then the value of the diameter being measured lies somewhere between
63.5 mm and 64.5 mm since a meter rule could easily be read to half a millimeter.
In this case, the uncertainty in the diameter is 0.5 mm. Therefore, the diameter of the
metal canister is 64 mm ± 0.5 mm. This also applies to digital instruments. An ammeter
records currents to 0.1 A. A current of 0.36 A would be displayed as 0.4 A, and a
current of 0.44 A would also be displayed as 0.4 A. The resolution of the instrument
is 0.1 A but the uncertainty in a reading is 0.05 A.

The typical uncertainty of a top loading balance is 0.05 g. How would you report
on weighing of 23.25 g made on this top loading balance? The result should be
reported as 23.25 g ± 0.05 g. Such an item of data means that the correct reading
lies between 23.20 g and 23.30 g.

The uncertainty in a measurement can be expressed in two useful ways:
a. as the absolute uncertainty in the last digit written
b. as the percent uncertainty calculated as follows

absolute uncertainty
% uncertainty = × 100
measurement

% uncertainty = (0.05 g)/( 23.25 g) × 100 = 0.2%
Therefore the answer may be reported as:
Absolute uncertainty: 23.25 g ± 0.05 g
Percent uncertainty: 23.25 g ± 0.2%

Exercise 2.3
Absolute uncertainty and percent uncertainty in a single reading: Use the given
uncertainty to calculate the % uncertainty in each of the following readings and
report the result of measurement in terms of absolute uncertainty and percent
uncertainty:
a. A barometer reading of 723.5 torr. The absolute uncertainty is 0.1 torr
b. 2.75 g weighed on a top loading balance. The absolute uncertainty is 0.05
g
c. 2.7413 g weighed on an analytical balance. The absolute uncertainty is
0.0002 g

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Measurements and Scientific Methods

d. A temperature reading of 75.6 °C on a thermometer graduated to the
nearest degree. The absolute uncertainty is 0.2 °C
e. 18.6 ml measured in 100 ml graduated cylinder. The absolute uncertainty
is 0.4 mL
f. 43.7 ml measured in 100 ml graduated cylinder. The absolute uncertainty
is 0.4 mL

2.1.5 Precision and Accuracy
Measurements may be accurate, meaning that the measured value is the same as the
true value; they may be precise, meaning that multiple measurements give nearly
identical values (i.e., reproducible results); they may be both accurate and precise; or
they may be neither accurate nor precise. The goal of scientists is to obtain measured
values that are both accurate and precise.

If you repeat a particular measurement, you usually do not obtain precisely the same
result, because each measurement is subject to experimental error. The measured
values vary slightly from one another. Suppose you perform a series of identical
measurements of a quantity. The term precision refers to the closeness of the set of
values obtained from identical measurements of a quantity. Accuracy is a related
term; it refers to the closeness of a single measurement to its true value.

Example 2.4: Precision and Accuracy
The archery targets in Figure 2.5 show marks that represent the results of four sets of
measurements.
a. a precise but inaccurate set of measurements.
b. an accurate but imprecise set of measurements.
c. a set of measurements that is both precise and accurate.
d. a set of measurements that is neither precise nor accurate.

Figure 2.5 The distribution of darts on a dart board showing the difference between
precise and accurate.

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Chemistry Grade 9

Form groups, discuss and present your conclusion to
the class
1. Mohammed measured the mass of a sample of
gold using one balance and found 1.896 g. On
a different balance, the same sample was found
to have a mass of 1.125 g. Which measurement
was correct the first or the second measurement?
Careful and repeated measurements made
by Mohammed, including measurements on a
calibrated third balance, showed the sample to
have a mass of 1.895 g. The masses obtained
from the three balances are in the Table 2.5:
Table 2.5 Mass measurement
Balance 1 Balance 2 Balance 3
1.896 g 1.125 g 1.893 g
1.895 g 1.158 g 1.895 g
1.894 g 1.067 g 1.895 g
A ctivity 2.3

Exercise 2.4
a. A 2-carat diamond has a mass of 400.0 mg. When a jeweler repeatedly
weighed a 2-carat diamond, he obtained measurements of 450.0 mg,
459.0 mg, and 463.0 mg. Were the jeweler’s measurements accurate?
Were they precise?
b. A single copper penny was tested three times to determine its composition.
The first analysis gave a composition of 93.2% zinc and 2.8% copper, the
second gave 92.9% zinc and 3.1% copper, and the third gave 93.5% zinc
and 2.5% copper. The actual composition of the penny was 97.6% zinc and
2.4% copper. Were the results accurate? Were they precise?

2.1.6 Significant Figures
We must always be careful in scientific work to write the proper number of significant
figures. In general, it is fairly easy to determine how many significant figures a number
has by using the following rules:
1. Any digit that is not zero is significant. Thus, 845 cm has three significant figures,
1.234 kg has four significant figures, and so on.
2. Zeros between nonzero digits are significant. Thus, 606 m contains three significant

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Measurements and Scientific Methods
figures, 40,501 kg contains five significant figures, and so on.
3. Zeros to the left of the first nonzero digit are not significant. Their purpose is to
indicate the placement of the decimal point. For example, 0.08 L contains one
significant figure, 0.0000349 g contains three significant figures, and so on.
4. If a number is greater than 1, then all the zeros written to the right of the decimal
point count as significant figures. Thus, 2.0 mg has two significant figures, 40.062
mL has five significant figures, and 3.040 dm has four significant figures. If a
number is less than 1, then only the zeros that are at the end of the number and
the zeros that are between nonzero digits are significant. This means that 0.090
kg has two significant figures, 0.3005 L has four significant figures, 0.00420 min
has three significant figures, and so on.
5. For numbers that do not contain decimal points, the trailing zeros (that is, zeros
after the last nonzero digit) may or may not be significant. Thus, 400 cm may have
one significant figure (the digit 4), two significant figures (40), or three significant
figures (400). We cannot know which is correct without more information. By using
scientific notation, however, we avoid this ambiguity. In this particular case, we
can express the number 400 as 4×102 for one significant figure, 4.0×102 for two
significant figures, or 4.00×102 for three significant figures.

A second set of rules specifies how to handle significant figures in calculations.
1. In addition and subtraction, the answer cannot have more digits to the right of the
decimal point than either of the original numbers.
Consider these examples:
89.332
+1.1 ← one digit after the decimal point
90.432 ← round off to 90.4

2.097
-0.12 ← two digits after the decimal point
1.977 ← round off to 1.98
The rounding-off procedure is as follows. To round off a number at a certain point we
simply drop the digits that follow if the first of them is less than 5. Thus, 8.724 rounds
off to 8.72 if we want only two digits after the decimal point. If the first digit following
the point of rounding off is equal to or greater than 5, we add 1 to the preceding
digit. Thus, 8.727 rounds off to 8.73, and 0.425 rounds off to 0.43.
2. In multiplication and division, the number of significant figures in the final product
or quotient is determined by the original number that has the smallest number of
significant figures. The following examples illustrate this rule:

2.8×4.5039=12.61092 → round off to 13
6.85 = 0.0611388789 → round off to 0.0611
112.04

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3. Keep in mind that exact numbers obtained from definitions (such as 1 ft, 12 in,
where 12 is an exact number) or by counting numbers of objects can be considered
to have an infinite number of significant figures.

Example 2.5 Significant figures
Determine the number of significant figures in the following measurements: (a) 394 cm,
(b) 5.03 g (c) 0.714 m, (d) 0.052 kg, (e) 2.720 × 1022 atoms,
(f ) 3000 mL.

Solution: (a)Three, because each digit is a nonzero digit. (b) Three, because zeros
between nonzero digits are significant. (c) Three, because zeros to the left of the first
non zero digit do not count as significant figures. (d) Two. Same reason as in (c). (e)
Four, because the number is greater than one, all the zeros written to the right of the
decimal point count as significant figures. (f) This is an ambiguous case. The number of
significant figures may be four (3.000 × 103), three (3.00 × 103), two (3.0 × 103), or
one (3 × 103). This example illustrates why scientific notation must be used to show the
proper number of significant figures.

Exercise 2.5
Significant figures:
Determine the number of significant figures in each of the following
measurements:
a. 35 mL d. 7.2 × 104 molecules
b. 2008 g e. 830 kg.
c. 0.0580 m 3

Exercise 2.6
1. Arithmetic operations: Carry out the following arithmetic operations to the
correct number of significant figures:
a. 11,254.1 g + 0.1983 g d. 0.0154 kg ÷ 88.3 mL
b. 66.59 L – 3.113 L e. 2.64 × 103 cm + 3.27 × 102
c. 8.16 m × 5.1355 cm.
2. Significant Figures (Addition and Subtraction)
a. Add 37.24 mL and 10.3 mL.
b. Subtract 21.2342 g from 27.87 g.
3. Significant Figures (Multiplication)
What is the area of a rectangle 1.23 cm wide and 12.34 cm long?

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Measurements and Scientific Methods
2.1.7 Scientific Notation and Decimal Places
We use scientific notation when we deal with very large and very small
numbers. For example, 197 grams of gold contains approximately
602,000,000,000,000,000,000,000 gold atoms.

The mass of one gold atom is approximately 0.000 000 000 000 000 000 000 327
gram. In using such large and small numbers, it is inconvenient to write down all the
zeros. In scientific (exponential) notation, we place one nonzero digit to the left of the
decimal.

602,000,000,000,000,000,000,000 = 6.02×1023

23 places to the left, therefore exponent of 10 is 23
0.000 000 000 000 000 000 000 327 =3.27×10-22

22 places to the right, therefore exponent of 10 is -22.
The reverse process converts numbers from exponential to decimal form.

Example 2.6 Unit Conversions
The Ångstrom (Å) is a unit of length, 1×10-10 m,that provides a convenient scale on which
to express the radii of atoms. Radii of atoms are often expressed in nanometers. The
radius of a phosphorus atom is 1.10 Å. What is the distance expressed in centimeters
and nanometers?

Plan
We use the equalities 1 Å= 1×10-10m, 1 cm = 1×10-2 m, and 1nm = 1× 10-9 m to
construct the unit factors that convert 1.10 Å to the desired units.
Solution: Let x be the length in cm unit and y the length in nm.
1 x 10-10 m x 1cm
x cm = 1.10 0A x 10A 1 x 10-2 m = 1.10 x 10 cm
-8

1 x 10-10 m x 1nm
y nm= 1.10 0A x 10A 1 x 10-9 m = 1.10 x 10 nm
-1

Exercise 2.7
Volume Calculation
Assuming a phosphorus atom is spherical; calculate its volume in Å3, cm3, and
4
nm3. The formula for the volume of a sphere is V = 3 πr
3
Refer to Example
above.

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2.2 Chemistry as Experimental Science
Learning competencies
At the end of this section, you should be able to
 define scientific method;
 describe the major steps of the scientific method;
 use scientific methods in solving problems;
 demonstrate some experimental skills in chemistry;
 describe the procedures of writing laboratory report.

Chemistry is largely an experimental science, and a great deal of knowledge comes
from laboratory research. In addition, however, today’s chemist may use a computer
to study the microscopic structure and chemical properties of substances or employ
sophisticated electronic equipment to analyze pollutants from auto emissions or toxic
substances in a soil. Many frontiers in biology and medicine are currently being
explored at the level of atoms and molecules the structural units on which the study of
chemistry is based.

Chemists participate in the development of new drugs and in agricultural research.
What’s more, they are seeking solutions to the problem of environmental pollution
along with replacements for energy sources. And most industries, whatever their
products, have a basis in chemistry. For example, chemists developed polymers (very
large molecules) that manufacturers use to make a wide variety of goods, including
clothing, cooking utensils, artificial organs, and toys.

Chemistry is evidence based. All chemical statements are based on experiment.
Chemistry is part of the body of modern science. It shares the experimental method
of all sciences. It improves in time also using new discoveries and concepts from other
sciences. In turn, it provides both theoretical and experimental tools to different
sciences. Biology and Geology cannot be studied without a thorough understanding
of chemical phenomena. Indeed, because of its diverse applications, chemistry is often
called the “central science.”
2.2.1 The Scientific Method

Conduct the following activity and present your
finding to the class.
a. Collect a plastic bag filled with different items
provided by your teacher.
b. Decide on the question you would like to answer
about your bag. Write it down. (Do not open the
bag)

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Measurements and Scientific Methods

c. Guess what the answer to your question might
be. Write down. (Do not open the bag)
d. Open your bag and answer the questions.
e. Be sure to count the total number of items.
Now, discuss which part of the activity (a, b, c, d, or e)
introduces the scientific terminology: hypothesis, data
A ctivity 2.4 collection, experimentation, etc.

The Scientific method
What is Scientific Method? The Scientific method is a process with the help of which
scientists try to investigate, verify, or construct an accurate and reliable version of
any natural phenomena. They are done by creating an objective framework for
the purpose of scientific inquiry and analyzing the results scientifically to come to a
conclusion which either supports or contradicts the observation made at the beginning.

Scientific Method Steps
The aim of all scientific methods is the same, that is, to analyze the observation made
at the beginning but there are various steps adopted as per the requirement of
any given observation. However, there is a generally accepted sequence of steps of
scientific methods as it is shown in Figure 2.6.

Figure 2.6 The four main steps of the research process in studying chemistry and their
relationships.

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Chemistry Grade 9
i. Observation and formulation of a Question: This is the first step of a scientific
method. In order to start one, an observation has to be made into any
observable aspect or phenomena of the universe and a question needs to be
asked pertaining to that aspect. For example, you can ask, “Why is the sky black
at night? or “Why is air invisible?”
ii. Data Collection and Hypothesis: The next step involved in the scientific method is
to collect all related data and formulate a hypothesis based on the observation.
The hypothesis could be the cause of the phenomena, its effect, or its relation to
any other phenomena.
iii. Testing the Hypothesis: After the hypothesis is made, it needs to be tested
scientifically. Scientists do this by conducting experiments. The aim of these
experiments is to determine whether the hypothesis agrees with or contradicts the
observations made in the real world. The confidence in the hypothesis increases
or decreases based on the result of the experiments.
iv. Analysis and Conclusion: This step involves the use of proper mathematical and
other scientific procedures to determine the results of the experiment. Based on
the analysis, the future course of action can be determined. If the data found
in the analysis is consistent with the hypothesis, it is accepted. If not, then it is
rejected or modified and analyzed again.

It must be remembered that a hypothesis cannot be proved or disproved by doing
one experiment. It needs to be done repeatedly until there are no discrepancies in the
data and the result. When there are no discrepancies and the hypothesis is proved
beyond any doubt, it is accepted as a ‘theory’.
2.2.2 Some Experimental Skills in Chemistry
Laboratory Safety Rules
In the home, the kitchen and bathroom are the sites of most accidents. The chemical
laboratory poses similar hazards and yet it can be no more dangerous than any other
classroom if the following safety rules are always observed. Most of them are based
on simple common sense.
1. Responsible behaviour is essential. The dangers of spilled acids and chemicals
and broken glassware created by thoughtless actions are too great to be
tolerated.
2. Wear approved eye protection at all times in the laboratory and in any area
where chemicals are stored or handled. The only exception is when explicit
instructions to the contrary are given by your teacher.
3. Perform no unauthorized experiments. This includes using only the quantities
instructed, no more. Consult your teacher if you have any doubts about the
instructions in the laboratory manual.
4. Do not smoke in the laboratory at any time. Not only is smoking a fire hazard,
but smoking draws chemicals in laboratory air (both as vapours and as dust)
into the lungs.
5. In case of fire or accident, call the teacher at once. Note the location of fire

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Measurements and Scientific Methods
extinguishers and safety showers now so that you can use them if needed.
6. Report all injuries to your instructor at once. Except for very superficial injuries,
you will be required to get medical treatment for cuts, burns, or fume inhalation.
7. Do not eat or drink anything in the laboratory.
8. Avoid breathing fumes of any kind.
9. Never use mouth suction in filling pipets with chemical reagents. Always use a
suction device.
10. Never work alone in the laboratory. There must be at least one other person
present in the same room. In addition, your teacher should be quickly available.
11. Wear shoes in the laboratory. Bare feet are prohibited because of the danger
from broken glass. Sandals are prohibited because of the hazard from chemical
spills.
12. Confine long hair and loose clothing (such as ties) in the laboratory. They may
either catch fire or be chemically contaminated.
a. A laboratory apron or lab coat provides protection at all times. A lab
apron or lab coat is required when you are wearing easily combustible
clothing (synthetic and light fabrics).
b. It is advisable to wear old clothing to laboratory, because it is both generally
not as loose and flammable as new clothing, and not as expensive to replace.
13. Keep your work area neat at all times. Clean up spills and broken glass
immediately. Clutter not only will slow your work, but it leads to accidents.
Clean up your work space, including wiping the surface and putting away all
chemicals and equipment, at the end of the laboratory period.
14. Be careful when heating liquids; add boiling chips to avoid “bumping”.
Flammable liquids such as ethers, hydrocarbons, alcohols, acetone, and carbon
disulfide must never be heated over an open flame.
15. Always pour acids into water when mixing. Otherwise the acid can spatter,
often quite violently. Pour acid into water.
16. Do not force a rubber stopper onto glass tubing or thermometers. Lubricate the
tubing and the stopper with glycerol or water. Use paper or cloth towelling to
protect your hands. Grasp the glass close to the stopper.
17. Dispose of excess liquid reagents by flushing small quantities down the sink.
Consult the teacher about large quantities. Dispose of solids in crocks. Never
return reagents to the dispensing bottle.
18. Carefully read the experiment and answer the questions in the prelab before
coming to the laboratory. An unprepared student is a hazard to everyone in
the room.
19. Spatters are common in chemistry laboratories. Test tubes being heated or
containing reacting mixtures should never be pointed at anyone. If you observe
this practice in a neighbour, speak to him or her or the teacher, if needed.
20. If you have a cut on your hand, be sure to cover with a bandage or wear
appropriate laboratory gloves.
21. Finally, and most important, think about what you are doing. Plan ahead. Do

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Chemistry Grade 9
not cookbook. If you give no thought to what you are doing, you predispose
yourself to an accident.

The first and foremost rule of any laboratory is to be safe! This may seem obvious, but
people often disregard safety protocols for one reason or another, putting themselves
and those around them in danger. The best thing you can do is to make sure you follow
all safety protocols at all times.

Safety goggles are required wear in all chemistry labs. Not wearing them puts
you in danger of eye irritation and possibly blindness in the case of an accident.
A small droplet of acid could splash out of the container at any time. Better safe
than permanently blinded! Latex gloves should be used when there is a possibility
of corrosive chemicals spilling onto your hands. A lab apron or coat can also prevent
injury in case of spills or splashes.

A beaker is a common container in most labs. It is used for mixing, stirring, and heating
chemicals. Most beakers have spouts on their rims to aid in pouring. They also commonly
have lips around their rims and markings to measure the volume they contain, although
they are not a precise way to measure liquids. Beakers come in a wide range of sizes.
Because of the lip that runs around the rim, a lid for a beaker does not exist. However,
a watch glass can be used to cover the opening to prevent contamination or splashing.
Figure 2.7 shows some of the commonly used laboratory equipments.

Crucible tongs Ring support Bunsen burner Ring stand Scoopula Test tube
brush

Utility clamp Clay triangle Wire gauze Test tube Spatula
holder Test tube
rack

Beaker Elenmeyer Florence Graduated Funnel Evaporating
dish
flask flask cylinder Crucible &
cover

Medicine Watch
Wash bottle Test tube Buret Graduated Volumetric dropper glass
pipet pipet
Figure 2.7 Commonly used Laboratory Equipment.

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Measurements and Scientific Methods

Conduct the following activity and present your finding
to the class.
Laboratory equipment
List down laboratory equipment you know and that are
not shown in Figure 2.7. Describe their use. Which of
A ctivity 2.5 them are used for measurement?

2.2.3 Writing a Laboratory Report
A. The Pre-laboratory Report
Each experiment in this manual includes a pre-laboratory (prelab) report. The prelab
report is to be completed before the experiment is begun in the laboratory. Its p