IGCSE Chemistry - Topic 1 - States of Matter PDF

Summary

These notes provide an overview of the states of matter (solids, liquids, and gases) in chemistry. The document details the key properties of each state and the changes that occur between them, such as melting, freezing, evaporating, and boiling. The notes also include a table summarizing the differences.

Full Transcript

IGCSE Chemistry – Topic 1
Mrs. Larisa Thomas

STATES OF MATTER
PROPERTIES OF
SOLIDS, LIQUIDS
GASES
 SOLIDS
Solids have a fixed volume and shape

They have a high density

The atoms vibrate in position but can’t change
location

The particles are packed very closely together in
a fixed and regular pattern
This regular pattern is called a lattice
 LIQUIDS

Liquids have a fixed volume but adopt the shape
of the container

They are generally less dense than solids
(except water) but much denser than gases

The particles move and slide past each other
This is why liquids adopt the shape of the container
and why they can flow freely
 GASES
Gases don’t have a fixed volume and take up the shape
of the container
They have very low density
There is a lot of space between the particles so gases
can be compressed into a smaller volume
Particles are far apart and move randomly and quickly
in all directions
They collide with each other and the sides of a container
This is how pressure is created inside a can of gas
State Solid Liquid Gas

Particle Particles close together: Particles close together:
Particles far apart
Separation tightly packed loosely packed

Arrangement of
Regular pattern - lattice Randomly arranged Randomly arranged
Particles

Motion of Vibrate around a fixed Move or slide around each Move quickly in all directions
Particles position other (straight lines)

Energy of
Low kinetic energy Medium kinetic energy High kinetic energy
Particles

Density High Medium Low
Not fixed – Fluid shape Not fixed – Fluid shape
Shape Fixed shape
Takes shape of container Takes shape of container
Not fixed – expands to fill
Volume Fixed volume Fixed volume
container

2D Diagram
SOLID LIQUID GAS
CHANGES OF STATE
 MELTING
Melting is when a solid changes into a liquid
Requires an increase in temperature by supplying heat energy which is
transformed into kinetic energy, allowing the particles to vibrate more vigorously
Occurs at a specific temperature known as the melting point (m.p.)

FREEZING
Freezing is when a liquid changes into a solid
This is the reverse of melting and occurs at the same temperature
The melting and freezing point of a pure substance is the same

Requires a significant decrease in temperature (loss of heat energy) and
occurs at a specific temperature known as the freezing point
 EVAPORATING
When a liquid changes into a gas over a range of temperatures
Evaporation occurs only at the surface of liquids where high energy particles
can escape from the liquid's surface at low temperatures (below the b.p.)
The larger the surface area and the warmer the surface of the liquid, the
quicker a liquid can evaporate

BOILING
Boiling is when a liquid changes into a gas
Heating causes bubbles of gas to form below the surface of a liquid (liquid
particles escape from the surface and within the liquid)
Occurs at a specific temperature known as the boiling point (b.p.)
 CONDENSING

When a gas changes into a liquid
on cooling and it takes place over
a range of temperatures

When a gas is cooled its particles
lose energy and when they bump
into each other they lack the energy
to bounce away again, instead they
group together to form a liquid Changes of State
 What is the state?
With information about the melting and boiling points of a substance, one can
identify the state the substance is in at a specific temperature

If the given temperature is below the melting point (freezing point) → the
substance will be a solid at that temperature

If the given temperature is between the melting point and boiling point→ the
substance will be a liquid at that temperature

If the given temperature is above the boiling point→ the substance will be a
gas at that temperature
 Melting Boiling
point point

SOLID LIQUID GAS

Between melting and
Below melting point boiling point Above boiling point
 The Kinetic Particle Theory

The Kinetic Particle Theory states the following

All matter is made up of very small particles

The particles are in constant random motion → They have kinetic energy

There are spaces between the particles → Intermolecular spaces

There are attractive forces between the particles → Intermolecular forces
 State Changes - Kinetic Theory
MELTING → A solid is heated and the heat energy supplied is transformed into kinetic
energy. Increased kinetic energy causes stronger vibrations until the particles have
enough energy to weaken the intermolecular forces holding them in a regular
arrangement. The intermolecular spaces will increase as particles break away from
the lattice arrangement to form a liquid.

FREEZING → As a liquid is cooled down, the kinetic energy of the particles decrease,
and they start moving slower. At a certain temperature, their motion becomes slow
enough for the forces of attraction to be able to hold the particles together in a regular
arrangement of a solid. As the intermolecular forces become stronger, the
intermolecular spaces become smaller.
BOILING → A liquid is heated, and the heat energy supplied is transformed into
kinetic energy. An increase in kinetic energy causes the particles to move faster and
further until the particles move fast enough to overcome (break all) the
intermolecular forces holding them together. The intermolecular spaces will
increase as particles break away from the liquid arrangement to form a gas.

CONDENSING → As a gas is cooled, the kinetic energy of the particles decrease,
and they start moving slower. At a certain temperature, the gas particles will slow
down enough for the attractive forces to become strong enough to hold them together
in a liquid arrangement. As the intermolecular forces become stronger, the
intermolecular spaces become smaller.
 State Changes & Kinetic Theory - Summary
When substances are heated, the particles absorb heat (thermal) energy which is
converted into kinetic energy
An increase in kinetic energy in a solid causes the particles to vibrate more and as
the temperature increases, they vibrate so much that the solid expands until the
structure breaks and the solid melts
On further heating, the particles in the now liquid substance also absorbs heat energy,
which is converted into kinetic energy, causing the particles to move more and faster
The liquid expands more and some particles at the surface gain enough energy to
overcome the intermolecular forces and evaporate
When the boiling point temperature is reached, all the particles gain enough energy to
escape, and the liquids boils
 HEATING AND
COOLING CURVES
 State Changes on Graphs
Changes in state can be shown on graphs called heating curves and cooling curves.
These curves show how changes in temperature affect changes of state.
 A heating curve shows the change of state of a
Heating Curve substance from solid to gas when it is heated
 Interpreting a Heating Curve
Heating a solid results in its temperature rising over the time of heating but the graph
shows two periods during which the temperature remains constant
The temperature is constant during the phase changes → melting and vaporisation
In the regions where the temperature rises:
The heat energy added is transformed into kinetic energy so temperature
increases
Increased kinetic energy causes the particles to move faster and interact less strongly
The intermolecular spaces increase as the particles begin to move apart

In the regions where the temperature is constant:
The heat energy added is used to overcome the intermolecular forces
The heat energy causes changes in potential energy NOT kinetic energy
This results in the temperature staying constant until the phase change is complete
 Plateau
=
Phase change
=
Potential energy
change
 A cooling curve shows the change of state of a
Cooling Curve substance from gas to solid when it is cooled
 Interpreting a Cooling Curve
Cooling a gas results in its temperature falling over the time of cooling
The temperature is constant during the two phase changes → condensing and freezing
In the regions where the temperature falls:
Kinetic energy is transformed into heat energy that is removed so temperature
decreases
Decreased kinetic energy causes the particles to move slower and interact stronger
The intermolecular spaces decrease as the particles begin to move closer together

In the regions where the temperature is constant:
The heat energy removed comes from energy released when forming new
intermolecular forces
The heat energy comes from changes in potential energy NOT kinetic energy
The temperature stays constant until the phase change is complete
 Pure VS Impure Substances
Pure Substance → A substance that consists of only one type of element or compound
Impure Substance → A substance that consists of more than one type of element
and/or compound not chemically bonded
Mixtures (pure substances physically mixed with impurities) are impure substances
Impurities causes the melting point of an impure substance to be lower than the pure
substance and causes it to melt over a range of temperatures
Impurities causes the boiling point of an impure substance to be higher than the pure
substance and causes it to boil over a range of temperatures

Pure substances have specific and fixed melting and boiling points
Phase changes on a heating or cooling curve are horizontal/flat lines

Impure substances melt and boil over a range of temperatures
Phase changes on a heating or cooling curve are slope lines with a gradient
Pure Substances Heating Curve

A pure substance
boils at a specific
and constant
temperature

A pure substance
melts at a specific
and constant
temperature
Impure Substances Heating Curve

An impure
substance boils at a
higher temperature
and over a range of
temperatures

An impure
substance melts at a
lower temperature
and over a range of
temperatures
VOLUME OF GASES
 Effect of Temperature & Pressure on
the VOLUME of a Gas
Inversely
Changing the external pressure on a sample of gas Proportional

An increase in pressure produces a decrease in volume → Gas is compressed
A decrease in pressure produces an increase in volume → Gas expands
Directly
Changing the temperature of a sample of gas Proportional

An increase in temperature produces an increase in volume → Gas expands
A decrease in temperature produces a decrease in volume → Gas is compressed

The large intermolecular spaces in gases explain why the volume is easily
changed by changes in temperature and pressure
Effect of Temperature on the Volume of a Gas
Kinetic Theory
Increase in temperature → The kinetic energy of the gas particles
increase; they move faster and there is less chance of interaction between
them as the intermolecular forces become almost negligent. They can
move further apart to occupy a greater volume.

Decrease in temperature → The kinetic energy of the gas particles
decrease; they move slower, and they are more likely to interact with each
other as the intermolecular forces have a greater effect. They will move
closer together to occupy a smaller volume.
 Effect of Pressure on the Volume of a Gas
Kinetic Theory
Increase in pressure→ The gas particles are pushed closer together and are
more likely to interact with each other as the intermolecular forces have a
greater effect. They will move closer together to occupy a smaller
space/volume.

Decrease in pressure→ The gas particles are not pushed together and are
less likely to interact with each other as the intermolecular forces will have less
of an effect. They will move further apart and occupy a greater space/volume.
 Gas Pressure

Gas particles are in constant
and random motion

The pressure that a gas creates
inside a closed container is
produced by the gas particles hitting
the inside walls of the container
 Effect of Temperature and Volume
on Gas Pressure
IINCREASE in TEMPERATURE → The heat energy supplied is transformed
into kinetic energy. This increases the kinetic energy of the gas particles, so
they move faster and collide with the walls of the container more
frequently. The pressure will increase.

DECREASE in VOLUME → If the container is made smaller, the same amount
of gas particles will have less space available to move in and will collide with
the walls of the container more frequently. The pressure will increase.
Decreasing the volume of a container increases the gas pressure
DIFFUSION
 Diffusion
The movement of particles from an area of higher concentration to an area of lower
concentration, down a concentration gradient, until equilibrium is reached

Equilibrium means that eventually the concentration of particles will be equal
as they spread out evenly to occupy all the available space
This is the process by which different gases or liquids mix and is due to the
random motion of their particles
Diffusion can only happen in fluids (liquids and gases) because they have large
enough intermolecular spaces for the particles to move around and spread out
Diffusion cannot happen in solids because the intermolecular spaces are very
small and the particles only vibrate, they do not move around to spread out evenly
Diffusion of potassium manganate(VII),
KMnO4 , in water. After a few hours, the
concentration of KMnO4 is the same
throughout the solution
 Diffusion Rate & Molecular Mass
Diffusion occurs much faster in gases than in liquids as gaseous particles move
much quicker than liquid particles

At the same temperature, different gases do not diffuse at the same rate

This is due to the difference in their relative molecular masses

Particles with a lower relative molecular mass is lighter, can move faster and
further and therefore will diffuse at a faster rate

Particles with a higher relative molecular mass is heavier, they move slower
and therefore will diffuse at a slower rate
 This can be demonstrated in the reaction between ammonia (NH3) and
hydrogen chloride gas (HCl) inside a long glass tube
Where the two gases meet, a white smoke of ammonium chloride (NH4Cl) forms
This does not occur in the middle of the tube, but much closer to the end with
the hydrogen chloride
Hydrogen chloride has a relative molecular mass of 36.5 and ammonia of 17
The ammonia molecules are lighter, move faster and thus diffuse faster
 Diffusion Rate & Temperature
Diffusion is a passive process, which means that it happens on its own and
no energy input is required

Particles of the same substance has the same molecular mass but will
diffuse at different rates if the temperature differs

For the same substance, the rate of diffusion is faster at a higher
temperature as the particles will have more kinetic energy and move faster

For the same substance, the rate of diffusion is slower at a lower
temperature as the particles will have less kinetic energy and move slower
Topic Summary
ATOMS, ELEMENTS
AND COMPOUNDS
IGCSE Chemistry – Topic 2
Mrs. Larisa Thomas
 ELEMENTS,
COMPOUNDS
AND
MIXTURES
 Atoms
All matter is made of atoms. Very long ago, a Greek philosopher called
Democritus said that all matter is made up of tiny pieces. He suggested that
if you take a substance and keep cutting it into smaller pieces, you will end
up with a piece that cannot be cut anymore or cannot get any smaller.

He called these smallest pieces of matter atoms, because the word “atom”
means “cannot be divided”.

Atom → The smallest particle of a substance,
that cannot be broken down chemically.
 Substances
Atoms are the building blocks of substances.
All substances can be classified into one of these three types:
Elements
Compounds
Mixtures

Element
A pure substance made up of only one type of atom, each containing
the same number of protons, and it cannot be split into simpler substances
There are 118 elements found on the Periodic Table
E.g. hydrogen and magnesium
Compound
A pure substance made up of two or more elements chemically combined
There is an unlimited number of compounds
Compounds cannot be separated into their elements by physical means
E.g. copper(II) sulfate (CuSO4), calcium carbonate (CaCO3), carbon dioxide (CO2)

Mixture
An impure substance made up of two or more substances
(elements and/or compounds) that are not chemically combined
Mixtures can be separated by physical methods such as filtration or evaporation
E.g. sand and water, oil and water, sulfur powder and iron filings
 Substance Explanation Particle Model Particle Model

Consists of only one type of
Element
atom (may be diatomic)

Consists of two or more
Compound different elements (atoms)
chemically bonded

Consists of two or more
Mixture of elements different elements NOT
chemically bonded

Consists of two or more
Mixture of
different compounds NOT
compounds chemically bonded

Consists of two or more
Mixture of elements different elements and
and compounds compounds NOT
chemically bonded
 ATOMS
&
ATOMIC STRUCTURE
 Atoms are the building blocks of matter
Each atom is made of subatomic particles General Atomic
called protons, neutrons and electrons
The protons and neutrons are located at
Structure
the centre of the atom, called the nucleus
The electrons move very fast around the
nucleus in orbital paths called shells
The mass of the electron is so small it can
be ignored; which means the mass of an
atom is contained within the nucleus
where the protons and neutrons are located
The number of subatomic particles and
shells in an atom varies for every element
 Atomic Structure and Mass
Atomic structure can thus be described as:
A central nucleus containing protons and
neutrons surrounded by electrons in shells

Atoms are so small that we cannot compare
their masses in conventional units like grams
A unit called the relative atomic mass is
used
This is also used to measure the mass of the
subatomic particles
 Subatomic Particles
Subatomic particles are often compared and identified by means of their
relative mass measured in relative atomic mass units and electric charge
as either having a positive, negative or neutral (no) charge

Particle Relative mass Charge

Proton 1 1+

Neutron 1 0
1
Electron OR 0 1-
1840
 Atomic Notation
The atomic number and mass number of an element
can be shown using atomic notation
Proton/Atomic Number (Z)
The number of protons in the nucleus of an atom (symbol Z)
It determines the position of the element on the Periodic Table

Nucleon/Mass Number (A)
The number of protons and neutrons in the nucleus of an atom (symbol A)
Protons and neutrons can collectively be called nucleons
The Periodic Table shows elements with their atomic/proton number at the top
and relative atomic mass at the bottom - there is a difference between relative
atomic mass and mass number, but for your exam, you can use the relative
atomic mass as the mass number (except for chlorine)
 Calculating the number of
protons, neutrons and electrons
Protons
The atomic number of an atom or ion determines which element it is
All atoms or ions of the same element have the same number of protons
E.g., Li has an atomic number of 3, so all atoms/ions of Li will have 3 protons
Number of protons = Atomic (proton) number
The number of protons of an unknown element can be calculated by using
its mass number and number of neutrons:
Number of protons = mass number – number of neutrons
Electrons for Atoms
Atoms have an overall neutral charge because the positive charge on the
protons and negative charge on the electrons balance (cancel out)
This means that an atom has the same number of protons and electrons
Number of electrons = Number of protons = Atomic (proton) number

Neutrons
The mass and atomic numbers are used to find the number of neutrons in
atoms or ions
The mass number shows the total number of protons and neutrons, so to get
the number of neutrons only, you need to subtract the number of protons
Number of neutrons = mass number – atomic (proton) number
Example
Determine the number of protons, electrons and neutrons in an atom
of unknown element X with atomic number 29 and mass number 63.

Protons: Number of protons = the atomic number
63
Number of protons = 29

Electrons: Atoms are neutral
Number of electrons = number of protons
29 𝑋
Number of electrons = 29

Neutrons: Number of neutrons = mass number – number of protons
Number of neutrons = 63 – 29
Number of neutrons = 34
Example
Using the periodic table, calculate the number of protons, neutrons and
electrons in an atom of nitrogen
Atomic
7 number
Number of protons = atomic number = 7 N
nitrogen
Number of electrons = number of protons = 7 Atomic
14 mass

Number of neutrons = atomic mass – atomic number
= 14 - 7
=7
Example
An atom of a specific element contains 9 protons,
9 electrons and 10 neutrons. An atom of which
9
element is this?
F
fluorine
The atomic number determines which element it
19
is. The atom has 9 protons, so the element is
fluorine because fluorine has an atomic number
of 9 on the periodic table.
ELECTRONIC
STRUCTURE
 Electron Shell Diagrams Drawing the
electronic
Electrons orbit the nucleus in shells (energy levels) structure

Electrons start filling the shell closest to the nucleus
When a shell is full, the additional electrons start filling the next shell
Different shells can hold a different number of electrons before being full:
The first shell can hold 2 electrons
The second shell can hold 8 electrons
The third shell can hold 8 electrons (simplified for this course)

The outermost shell of an atom is called the valence shell, and an atom is
much more stable if it can manage to completely fill this shell with electrons
The electrons on the outermost shell are called valency electrons
Electrons can be represented as either dots ( ) or crosses (x)
Electron Shell Diagrams & The Periodic Table
The electron shell diagram for an atom of any element can be drawn by using
information from the Periodic Table
The Periodic Table is arranged into 7 periods (→) and 8 groups (↓)
The period number that an element is found in, determines how many electron
shells an atom for that element will have
The group number that an element is found in, determines how many valency
electrons an atom for that element will have
Once you have filled the inner shells with their maximum number of electrons,
draw the correct number of electrons on the outermost shell
To double check, make sure the total number of electrons is the same as the
atomic (proton) number for the element
 Example: Group IV (4) elements have
Shows the number atoms with 4 electrons in the outer
of valency electrons shell & Group VI (6) elements have
atoms with 6 valency electrons
Shows the
number of
I II GROUPS III IV V VI VII O
electron
shells
1
2
PERIODS 3
4
Example: 5
Elements in period
2 have 2 electron 6
shells & elements
in period 3 have 3 7
electron shells
 Writing the
Electronic Configuration electronic
structure

The
arrangement of electrons in shells can also be explained using
numbers instead of electron shell diagrams
Thisspecial notation called the electronic configuration/electronic
structure/electronic distribution
The
number of electrons in each shell, starting from the first shell and
moving out, can be written down, separated by commas
Example → Carbon has 6 electrons, 2 in the first shell and 4 in the
second shell
Its electronic configuration is 2,4
Electron Configuration
& The Periodic Table
The number of notations in
the electronic configuration
shows the number of electron
shells the atom has and the
period that element is in
The last notation shows the
number of valency electrons
the atom has, showing the
group that element is in
Example
Draw and write the electronic
structure of magnesium.

Mg is in Period 3, so it has 3
electrons shells
The first shell is filled with two
electrons and the second with eight
Mg is in Group 2, so it has 2 valency
electrons in the third shell
The written form of this
The atomic number of Mg is 12 so electronic structure is 2,8,2
Mg has 12 electrons in total
 IONS
&
IONIC STRUCTURE
 Ions
Ion → An electrically charged atom or group of
atoms formed by the loss or gain of electrons.
This loss or gain of electrons are to obtain a full outer shell of electrons
The electronic structure of ions will be the same as that of a noble gas
Negative ions are called anions and form when atoms gain electrons
They have more electrons (-) than protons (+)
Non-metals gain electrons from other atoms to become anions

Positive ions are called cations and form when atoms lose electrons
They have more protons (+) than electrons (-)
Metals lose electrons to other atoms to become cations
 𝑻𝒉𝒆 𝒄𝒉𝒂𝒓𝒈𝒆 𝒐𝒏 𝒂𝒏 𝒊𝒐𝒏 𝒊𝒔
Charge on Ions 𝒊𝒏𝒅𝒊𝒄𝒂𝒕𝒆𝒅 𝒂𝒔 𝒂 𝒔𝒖𝒑𝒆𝒓𝒔𝒄𝒓𝒊𝒑𝒕
𝒂𝒇𝒕𝒆𝒓 𝒕𝒉𝒆 𝒔𝒚𝒎𝒃𝒐𝒍 𝒆. 𝒈. 𝑴𝒈𝟐+

Atoms have no charge because they have an equal number of protons (+) and
electrons (-), while ions have a positive or negative charge because they do not
have an equal number of protons and electrons
When atoms gain electrons, they form anions with more electrons than protons
The size of the charge depends on how many electrons are gained
Oxygen (Group 6) has 6 electrons on the outer shell and will gain 2 electrons
to obtain a full outer shell of 8 electrons → An oxygen ion will have a 2- charge
When atoms lose electrons, they form cations with less electrons than protons
The size of the charge depends on how many electrons are lost
Magnesium (Group 2) will lose its outer shell with 2 electrons for its previous
full shell to become its outer shell → A magnesium ion will have a 2+ charge
 Ionic Charge & The Periodic Table
There is a link between group numbers and the charge on ions
as the number of valency electrons an atom has determines the
number of electrons it will lose or gain to form an ion

4+
1+ 2+ 3+ 4- 3- 2- 1-
I II GROUPS III IV V VI VII O
 Electronic Configuration of Ions
Electronic configurations can also be written for ions
A sodium atom has 11 electrons: 2 in the first shell, 8 in the second shell
and 1 in the third shell
Electronic configuration → Na 2,8,1

A sodium ion has lost its one outer electron and outer shell, therefore
has 10 electrons: 2 in the first shell and 8 in the second shell
Electronic configuration → Na+ 2,8

Read carefully whether you are asked to give the electronic structure of
atoms or ions in the exam and remember to show the charge if you are
working with ions
 FORMATION
OF A CATION

CATions are
The mass and atomic numbers don’t
𝟐𝟑 change as the number of protons and 𝟐𝟑 +
PAWsitive
𝟏𝟏𝑵𝒂 neutrons don’t change. The + charge 𝟏𝟏 𝑵𝒂
shows the loss an electron!
 FORMATION
OF AN ANION

The mass and atomic numbers don’t
𝟑𝟒 change as the number of protons and 𝟑𝟒 −
𝟏𝟕𝑪𝒍 neutrons don’t change. The - charge 𝟏𝟕𝑪𝒍
shows the gain of an electron!
The number protons, neutrons and electrons
Protons and Neutrons
To get the number of protons and neutrons for an ion is the same as for an atom
Number of protons = Atomic (proton) number
Number of neutrons = mass number – atomic (proton) number

Electrons for Ions
Ions have an overall positive or negative charge because ions do not have the
same number of protons and electrons
Number of electrons in anion (-) = number of protons + size of charge
Number of electrons in cation (+) = number of protons - size of charge
 Polyatomic Ions
A group of bonded atoms that carry a net charge because the total number
of electrons in the group is not equal to the total number of protons

Polyatomic ion Formula Charge Formula and Charge

Ammonium NH4 + NH4+

Hydrogen carbonate HCO3 - HCO3-

Hydroxide OH - OH-

Nitrate NO3 - NO3-

Carbonate CO3 2- CO32-

Sulfate SO4 2- SO42-

Phosphate PO4 3- PO43-
ISOTOPES
 Isotopes
Different atoms of the same element that contain the same number
of protons but a different number of neutrons
Due to the number of protons being the same but the number of neutrons
being different, isotopes will have the same atomic number but different
mass numbers
The symbol for an isotope is the chemical symbol (or word) followed by a
dash and then the mass number
C-14 or carbon-14, also written as 146𝐶 or 14𝐶 is the isotope of carbon with a
mass number of 14, 6 protons and 8 neutrons
Isotopes of Hydrogen
 Isotopes Share Chemical Properties
Isotopes of the same element have the same chemical properties because
they have the same number of electrons / electronic configuration
The number of electrons, specifically those on the outer shell, determines the
chemistry of an atom
The difference between isotopes is the number of neutrons, which are neutral
particles within the nucleus that add mass only
The difference in mass between isotopes affects the physical properties,
such as density, boiling point and melting point
Isotopes are identical in appearance and reaction, so a sample of C-14 would
look and react no different to C-12
 Relative Atomic Mass

Atoms are so tiny that we can’t measure their masses in units like grams,
so a unit called the relative atomic mass (Ar) is used
One relative atomic mass unit is 1/12th the mass of a carbon-12 atom
All other elements are measured in comparison to the mass of a C-12
atom and since these are ratios, the relative atomic mass has no units
E.g., hydrogen has a relative atomic mass of 1, meaning that 12 atoms of
hydrogen would have the same mass as 1 atom of carbon
The Ar for each element appears on the Periodic Table and is an average
mass of all the isotopes of that element, rounded off to a whole number
 Calculating Relative Atomic Mass

As the relative atomic mass is the average mass of all the isotopes of an
element, it takes into account how many of each isotope is present
The relative atomic mass of an element is calculated from the mass
number and relative abundances (%) of all its isotopes
To calculate the relative atomic mass, the equation below is used where
the top line is the sum of all the different isotopes of a particular element

𝜮 (𝒊𝒔𝒐𝒕𝒐𝒑𝒆 𝒂𝒃𝒖𝒏𝒅𝒂𝒏𝒄𝒆 × 𝒊𝒔𝒐𝒕𝒐𝒑𝒆 𝒎𝒂𝒔𝒔 𝒏𝒖𝒎𝒃𝒆𝒓)
𝑨𝒓 =
𝟏𝟎𝟎
Example
IONIC BONDS
 ionic compound

Ionic Bonding
Ionic Bond → A strong electrostatic attraction
between oppositely charged ions electrostatic attraction
(ionic bond)
Ionic compounds form when metals react with non-metals
The metal atoms lose their valency electrons to form cations (+), and the
non-metal atoms gain these electrons to form anions (-)
Electrons are transferred from metal atoms to non-metal atoms
The positive and negative ions are held together by strong electrostatic forces
of attraction between opposite charges
This force is known as an ionic bond, and they hold ionic compounds together
 These diagrams show the arrangement
of the electrons in an ionic compound
Dot-and-cross Electrons are shown as dots and
Diagrams crosses:
In a dot and cross diagram for ionic
compounds:
The electrons for one element/atom is
shown with dots and the electrons for
a different element is shown with
crosses
The charge of the ion is spread evenly
which is shown by using large square
brackets
The charge on each ion is written at
the top right-hand corner
 Ionic Bonds between Group 1
and Group 7 Elements
Group 1 metals lose their one valency electron to obtain a full outer shell
They form positive ions with a charge of 1+

Group 7 non-metals gain this one electron to obtain a full outer shell
They form negative ions with a charge of 1–

One electron is transferred from the outer shell of the Group 1 metal
atom to the outer shell of the Group 7 non-metal atom to form ions
The oppositely charged Group 1 cation and Group 7 anion is then
attracted to one another and held together by electrostatic forces
 Example: Sodium
reacts with chlorine to
form sodium chloride
One valency electron is transferred
from the sodium atom to the
chlorine atom
This forms a sodium cation with a
1+ charge and a chloride anion with
1- charge
The oppositely charged ions are
held together by electrostatic forces
of attraction
DOT-AND-CROSS DIAGRAM
OF SODIUM CHLORIDE
COVALENT BONDS
 covalent compound: molecule

Covalent Bonding
Covalent Bond → A bond formed when a pair
of electrons is shared between two atoms,
leading to noble gas electronic configurations covalent bond

Covalent compounds are formed when pairs of electrons
are shared between atoms for each atom obtain a full outer shell of electrons
Only non-metal elements participate in covalent bonding
Covalent substances may consist of small molecules or giant molecules
When two or more atoms are covalently bonded together, we describe them
as ‘molecules’
 These diagrams show the arrangement of
Dot-and-cross the electrons in a molecule
Electrons are shown as dots and crosses:
Diagrams In a dot and cross diagram for covalent
compounds:
The electrons for one atom/element is
shown with dots and the electrons for
the other atom is shown with crosses
The electron shells of each atom in the
molecule overlap and the shared
electrons are shown in this area
The electron shell for each atom must
be full, counting the shared electrons for
each atom
 FORMATION OF
A COVALENT BOND
SIMPLE COVALENT
MOLECULES
HYDROGEN
H2
CHLORINE
Cl2
WATER
H2O
METHANE
CH4
AMMONIA
NH3
HYDROGEN CHLORIDE
HCl
CHEMISTRY OF THE
ENVIRONMENT
IGCSE Chemistry – Topic 10
Mrs. L Thomas
WATER
 Chemical Tests for Water
Using Anhydrous Cobalt Chloride
Blue anhydrous cobalt (II) chloride turns pink on the addition of water
This test is usually done using cobalt chloride paper

anhydrous cobalt (II) chloride + water ⇌ hydrated cobalt (II) chloride
CoCl2(s) + 6 H2O(l) ⇌ CoCl2∙6H2O(s)

Anhydrous → Hydrated
Blue → Pink
 Chemical Tests for Water
Using Anhydrous Copper Sulfate
White anhydrous copper (II) sulfate turns blue on the addition of water
This test is usually done using copper sulfate powder/crystals

anhydrous copper (II) sulfate + water ⇌ hydrated copper (II) sulfate
CuSO4(s) + 5 H2O(l) ⇌ CuSO4∙ 5H2O(s)

Anhydrous → Hydrated
White → Blue
 Purity of Water – Physical Tests
Testing for the purity of water can be done with physical tests
Pure substances melt and boil at specific and sharp temperatures
Water has a boiling point of 100 °C and a melting point of 0 °C
Mixtures/Impure substances have a range of melting and boiling points as
they consist of different substances that melt or boil at different temperatures
Melting and boiling points data can be used to determine the purity of water
Impurities tend to increase the boiling point of water, so impure water will
start boiling at temperatures above 100 °C
Impurities tend to decrease the melting point of water, so impure water will
start melting at temperatures below 0 °C
 Distilled Water
Distilled water is water that has been heated to form a vapour, and then
condensed back to a liquid

It contains very few chemical impurities

Distilled water is used in practical chemistry because of its high purity

Tap water contains more impurities which could interfere with chemical
reactions so is typically not used in practicals
 Water from Natural Sources
We use water in many aspects of our everyday life:
Domestic uses: drinking, cooking, gardening and general sanitation
Agricultural uses: drink for animals and watering crops
Industrial uses: as a solvent and coolant and to generate electricity

Natural sources of water include lakes, rivers and underground water
sources (groundwater)
A rock that stores water is known as an aquifer
 Substances in Water from Natural Sources
Water from natural sources may contain a variety of different substances,
including:
❖ Dissolved oxygen
❖ Metal compounds
Some of these substances
❖ Plastics are naturally occurring
but many are a direct
❖ Sewage
result of human activities
❖ Harmful microbes
❖ Nitrates from fertilisers
❖ Phosphates from fertilisers and detergents

Many of these substances enter water sources when rain falls and washes
them into lakes, rivers or groundwater
 Beneficial Substances in Water
Some of the substances found in natural water sources are beneficial and others
may have harmful effects

Beneficial substances include:
❖ Dissolved oxygen - essential for aquatic life

❖ Metal compounds - some provide essential minerals which are necessary
for life, such as calcium and magnesium
 Harmful Substances in Water
Potentially harmful substances include:
❖ Metal compounds - some are toxic like aluminium and lead

❖ Some plastics - these may harm aquatic life in many ways, e.g., getting
trapped in plastic waste, dying of starvation as their stomach fill with plastic

❖ Sewage - contains harmful microbes which can cause disease

❖ Nitrate & phosphates - these can promote the growth of aquatic plants
which leads to the deoxygenation of water. Ultimately, this can cause
damage to aquatic life in a process called eutrophication
 Water Treatment
Untreated water is taken from rivers, reservoirs or underground water sources
(groundwater) and is treated to make it safe for use as domestic water
Untreated water contains soluble and insoluble impurities
Insoluble impurities: soil, pieces of plants and other organic matter
Soluble impurities: dissolved calcium, metallic compounds and inorganic pollutants

Three main parts in the treatment of domestic water
Sedimentation & Filtration → Removes solids
Use of carbon → Removes tastes and odours
Chlorination → Kills microbes
 Water Treatment Process
Water is pumped into sedimentation tanks and is allowed to stand for a few hours
In a process called sedimentation; mud, sand and other particles will fall to the
bottom of the tank due to gravity and form a layer of sediment
Filtration is used to remove smaller particles by passing the water through layers of
sand and gravel filters that trap solid particles
Water can also be passed through carbon (in the form of charcoal) to remove tastes
and odours
Bacteria and other unwanted microorganisms are too small to be trapped by the filters.
Chlorination, the careful addition of chlorine to the water supply, is used to kill them
Cholera and typhoid are examples of bacterial diseases which can arise from the
consumption of untreated water
SUMMARY
FERTILISERS
 Fertilisers
Ammonium salts and nitrates are commonly used as fertilisers

NPK fertilisers provide the elements nitrogen, phosphorus and potassium for
improved plant growth

Different fertilisers contain different amounts of fertiliser compounds, so each contains
different proportions of nitrogen, potassium and phosphorous
 N,P,K Fertilisers
Fertilisers that contain nitrogen (N), potassium (K) and phosphorus (P)
Nitrogen makes chlorophyll and protein and promotes healthy leaves
Potassium promotes growth and healthy fruit and flowers
Phosphorus promotes healthy roots

Fertiliser compounds contain the following water-soluble ions:
Ammonium ions, NH4+, and nitrate ions, NO3-, are sources of soluble nitrogen
Phosphate ions, PO43-, are a source of soluble phosphorus
Most potassium compounds dissolve in water to produce potassium ions, K+

Common fertiliser compounds include:
Ammonium nitrate, NH4NO3
Ammonium phosphate, (NH4)3PO4
Potassium sulfate, K2SO4
AIR QUALITY
AND CLIMATE
 The Composition of Air

The chart shows the approximate
percentages by volume of the Mixture of noble gases
and carbon dioxide
main gases in clean, dry air

78% Nitrogen
21% Oxygen
1% Mixture of Noble Gases and
Carbon Dioxide
 Uses of Air
The gases available in the air have many important applications

The noble gases are used in many applications, e.g., helium is used to fill balloons,
argon is used in tungsten light bulbs, krypton is used in lasers for eye surgery

Oxygen is used in steel making, welding and breathing apparatus

Nitrogen is used in food packaging, the production of ammonia and in the
production of silicon chips

Oxygen and nitrogen are separated from the air by fractional distillation
 Air Pollution
In addition to the gases present naturally in our atmosphere, other gases are
present due to human activities and are classed as air pollutants

CARBON DIOXIDE
Sources: complete combustion of carbon-containing fuels such as fossil
fuels, e.g., the complete combustion of methane:
CH4 + O2 → CO2 + 2H2O
Adverse effects: higher levels of carbon
dioxide can increase global warming,
which leads to climate change
 CARBON MONOXIDE
Sources: incomplete combustion of carbon-containing fuels such as fossil
fuels, e.g., incomplete combustion of gasoline:
C8H18 + 9 O2 → 5 CO + 2 CO2 + 9 H2O
Adverse effects: toxic gas as combining with haemoglobin in the blood and
prevents it from carrying oxygen
PARTICULATES
Sources: incomplete combustion of carbon-containing fuels such as fossil
fuels can also produce particulates of carbon (soot), e.g., the incomplete
combustion of methane can produce CO and C:
2 CH4 + 3 O2→ 2 CO + 4 H2O
CH4 + O2→ C + 2 H2O
Adverse effects: increased risk of respiratory problems and cancer
 METHANE
Sources: waste gases from digestion in animals, decomposition of
vegetation and bacterial action in swamps, rice paddy fields and landfill sites
Adverse effects: higher levels of methane leading to increase global warming
and climate change
OXIDES OF NITROGEN
Sources: reaction of nitrogen with oxygen in the presence of high
temperatures, e.g., in car engines, high-temperature furnaces and lightning
Adverse effects:
Produces photochemical smog
Dissolves in rain to form acid rain which causes damage to aquatic organisms
and corrosion to metal structures/buildings/statues made of carbonate rocks
Causes respiratory problems and irritates the lungs, throat and eyes
 SULFUR DIOXIDE
Sources: combustion
of fossil fuels containing
sulfur compounds.
Power stations are a
major source.
Adverse effects:
dissolves in rain to
form acid rain with
similar effects as the
acid rain caused by
oxides of nitrogen.
 How Greenhouse Gases Cause Global Warming
The Sun emits energy in the form of radiation that enters the Earth’s atmosphere
Most thermal energy is absorbed and re-emitted back from the Earth’s surface → The
thermal energy passes through the atmosphere, and some is emitted straight into space
Some thermal energy is absorbed by greenhouse gases such as carbon
dioxide and methane and is then reflected and emitted in all directions
This reduces thermal energy loss to space and traps it within the Earth’s atmosphere
This process is known as the greenhouse effect
As the concentration of greenhouse gases in the atmosphere increases due to human
activity, more thermal energy is trapped within the Earth's atmosphere causing the Earth’s
average temperature to rise (global warming)
This process is called the enhanced greenhouse effect
Consequences of Global Warming
Climate change due to the increase
in Earth’s temperature
This can lead to a loss of habitat
Water levels will rise as glaciers
melt, causing flooding in low-lying
countries
Extinction of species due to the
destruction of natural habitats
Migration of species as they move
to areas that are more habitable
Spread of diseases caused by
warmer climate
 Reducing the Effects of
Environmental Issues
CLIMATE CHANGE
The production of greenhouse gases needs to be reduced drastically to avoid
or at least slow climate change
CO2 emissions can be reduced by increasing the use of hydrogen and
renewable energy such as solar or wind energy to decrease the use of
fossil fuels
Reduce livestock farming to decrease the methane emissions produced
from digestion in animals
Planting more trees to remove more carbon dioxide from the atmosphere
 ACID RAIN – SULFUR DIOXIDE
Emissions of sulfur dioxide can be reduced by either:
Using low-sulfur fuels
Flue gas desulfurisation → this involves reacting the sulfur dioxide emitted
from burning fuels with calcium oxide to remove it from the gas

ACID RAIN - OXIDES OF NITROGEN
NO and NO2 are formed when nitrogen and oxygen react under high pressure
and temperatures in internal combustion engines and blast furnaces
Exhaust gases also contain unburned hydrocarbons and carbon monoxide
Cars are fitted with catalytic converters which form a part of their exhaust
systems and act to render these vehicle exhaust gases harmless
 Catalytic Converters
They contain a series of transition metal catalysts like platinum and
rhodium in a honeycomb structure which increases the reaction surface area
A series of redox reactions occurs which neutralises the pollutant gases
Carbon monoxide is oxidised to carbon dioxide:
2 CO + O2 → 2 CO2
Oxides of nitrogen are reduced to nitrogen gas:
2 NO → N2 + O2
2 NO2 → N2 + 2 O2
A single reaction can summarise the reactions within a catalytic convertor:
2 NO + 2 CO → N2 + 2 CO2
 Catalytic
Converters
 Photosynthesis
Photosynthesis is the reaction between water and carbon dioxide to produce
glucose and oxygen in the presence of chlorophyll, using energy from light
Chlorophyll (in chloroplast) and energy from light are required for this reaction

The word equation for photosynthesis is:

Reactants
carbon dioxide
water

The balanced symbol equation for photosynthesis is: Products
glucose
oxygen
Summary