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Why do atoms form bonds?
Bonds involve the electrons in the outer shells of atoms.
Each shell has a maximum number of electrons that it can
hold. Electrons fill the shells nearest the nucleus first.
1st shell holds a
maximum of 2 electrons
2nd shell holds a
maximum of 8 electrons
3rd shell holds a
maximum of 8 electrons
Filled electron shells are very stable.
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Why do atoms form bonds?
The atoms of noble gases have completely
full outer shells and so are stable.
This makes the noble gases very unreactive
and so they do not usually form bonds.
The atoms of other elements have
incomplete outer electron shells
and so are unstable.
By forming bonds, the atoms of these
elements are able to have filled outer
shells and become stable.
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What is a covalent bond?
Non-metal elements usually just need one or two electrons
to fill their outer shells. So how do they form a bond?
Cl
incomplete
outer shells
Cl
The two non-metal atoms cannot form a bond by transferring
electrons from one to another. Instead, they share electrons.
Cl
Cl
Each atom now
has a full, stable
outer shell.
The shared electrons join the atoms together.
This is called a covalent bond.
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How is a covalent bond drawn?
A covalent bond consists of a shared pair of electrons.
Cl
Cl
covalent bond
Only outer shells of electrons are involved in bonding, so the
inner shells do not always have to be included in diagrams.
Two common ways to represent a covalent bond are:
simplified
dot and
cross
diagram
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Cl
Cl
solid
line
Cl–Cl
Cl
– Cl
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Comparing covalent and ionic bonding
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How are covalent bonds formed?
How do non-metal atoms form covalent bonds?
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Covalent bonding in hydrogen
Many non-metal elements, such as hydrogen, exist as
simple diatomic molecules that contain covalent bonds.
How is a covalent bond formed in hydrogen?
H
H
H
H
Each hydrogen atom needs one more electron in its outer
shell and so each atom shares its single unpaired electron.
This shared pair of electrons forms a covalent bond and so
creates a diatomic molecule of hydrogen.
Some molecules contain double or triple covalent bonds.
How are these are formed?
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What are the types of covalent bonds?
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Can compounds contain covalent bonds?
Covalent bonding can also occur between atoms of different
non-metals to create molecules of covalent compounds.
These covalent bonds can be single, double or triple.
How is a covalent bond formed in hydrogen chloride (HCl,
also represented as H–Cl)?
H
Cl
H
Cl
Hydrogen and chlorine both need one more electron to fill
outer shells. By sharing one electron each, they both have
a stable outer shell and a covalent bond is formed.
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Covalent bonding in water
Compounds can contain more than one covalent bond.
Oxygen (2.6) needs 2 more electrons, but hydrogen [1] only
needs 1 more. How can these three elements be joined by
covalent bonding?
The oxygen atom shares 1
electron with 1 hydrogen
atom, and a second
electron with another
hydrogen atom.
O
H
H
What is the name of the molecule that is formed?
H2O (or H–O–H) is water.
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How is the ratio of atoms calculated?
To calculate the ratio of atoms in a stable covalent compound:
1. Work out how many electrons are needed by each
non-metal element to complete its outer electron shell.
2. Work out the ratio of atoms that will provide enough
shared electrons to fill all the outer shells.
For example, how
many nitrogen and
hydrogen atoms
bond together in an
ammonia molecule?
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N
H
(2.5)
(1)
electrons
needed
3
1
ratio of
atoms
1
3
element
electron
configuration
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Covalent bonding in ammonia
How do nitrogen and hydrogen atoms form covalent bonds
in a molecule of ammonia?
element
electron
configuration
N
H
(2.5)
(1)
electrons
needed
3
1
ratio of
atoms
1
3
H
N
H
H
NH3 or H N H
H
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Covalent bonding in methane
How do carbon and hydrogen atoms form covalent bonds
in a molecule of methane?
element
electron
configuration
C
H
(2.4)
(1)
electrons
needed
4
1
ratio of
atoms
1
4
CH4
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H
H
H
or H C H
H
C
H
H
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Covalent bonding in carbon dioxide
How do carbon and oxygen atoms form covalent bonds in
a molecule of carbon dioxide?
element
electron
configuration
C
O
(2.4)
(2.6)
O
electrons
needed
4
2
ratio of
atoms
1
2
O
C
double bonds
CO2 or O C O
A double bond is when two pairs of electrons are shared.
In carbon dioxide there are two double bonds
– one between each oxygen atom and the carbon atom.
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What are simple covalent structures?
Covalent molecules that contain only a few atoms are
called simple covalent structures.
Most substances that contain simple covalent molecules
have low melting and boiling points and are therefore liquids
or gases at room temperature, e.g. water, oxygen, carbon
dioxide, chlorine and hydrogen. Why?
The covalent bonds within these molecules are strong but
the bonds between molecules are weak and easy to break.
strong bonds
within
molecules
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weak bonds
between
molecules
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What is the structure of a molecular solid?
A few substances that contain simple covalent molecules
are solid at room temperature. These are molecular solids.
Iodine is a molecular solid at room temperature.
Two iodine atoms form a single covalent
bond to become an iodine molecule.
The solid is formed because
millions of iodine molecules
are held together by weak
forces of attraction to create
a 3D molecular lattice.
What properties would you
expect molecular solids to have
with this type of structure?
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weak
forces of
attraction
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What are the properties of molecular solids?
The properties of a molecular solid, such as iodine, are:
 low melting and boiling points;
 usually soft and brittle – they
shatter when hit.
 cannot conduct electricity.
Why do molecular solids have these properties?
The weak forces of attraction between the molecules can
be broken by a small amount of energy. This means that
the molecular solids are soft and brittle and melt and boil at
low temperatures.
Molecular solids are also unable to conduct electricity
because there are no free electrons or ions to carry a charge.
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Covalent bonds – true or false?
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What are giant covalent structures?
In some substances, such as sand, diamond and graphite,
millions of atoms are joined together by covalent bonds.
The covalent bonds in these substances do not form
molecules but vast networks of atoms called giant covalent
structures.
All the bonds are covalent, so giant covalent structures have
very high melting and boiling points, and are usually hard.
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What is the structure of sand?
Sand is mostly made of the mineral quartz, which is silicon
dioxide. It has a giant covalent structure made up of silicon
and oxygen atoms.
Each silicon atom (2.8.4) is bonded to four oxygen atoms,
and each oxygen atom (2.6) is bonded to two silicon atoms.
O
Si
O
O
O
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What are the allotropes of carbon?
Diamond and graphite appear to be very different substances
but what do they have in common?
Both diamond and graphite are made up of carbon atoms.
Different forms of the same element are called allotropes.
These allotropes of carbon have different properties because
the atoms are bonded in different arrangements which create
different giant structures.
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How does structure affect properties?
How do the different structures of diamond and graphite
influence their properties?
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What is the structure of diamond?
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What are the properties of diamond?
In diamond, all the electrons in the outer shell of each
carbon atom (2.4) are involved in forming covalent bonds.
This affects the properties of this allotrope of carbon:
 Diamond is very hard – the
hardest natural substance.
 Diamond has a very high
melting and boiling point
– a lot of energy is needed
to break the covalent bonds.
 Diamond cannot conduct
electricity – there are no
free electrons or ions to
carry a charge.
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What is the structure of graphite?
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What are the properties of graphite?
In graphite, only three of the four electrons in the outer shell
of each carbon atom (2.4) are involved in covalent bonds.
This affects the properties of this allotrope of carbon:
 Graphite is soft and slippery
– layers can easily slide over
each other because the weak
forces of attraction are easily
broken. This is why graphite is
used as a lubricant.
 Graphite conducts electricity
– the only non-metal to do so.
The free electron from each
carbon means that each layer
has delocalized electrons,
which can carry charge.
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Are there other allotropes of carbon?
A third class of carbon compounds have been discovered
in recent years. These are called fullerenes.
Buckminsterfullerene is one type of fullerene. It contains
60 carbon atoms, each of which is bonded to three others
by two single bonds and one double bond.
C
C
C
C
The atoms in this allotrope of carbon form a sphere, like the
shape of a football. The molecules can be called ‘bucky balls’.
They are large but are not classified as giant structures.
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Complete the sentences
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Bonding and structure
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Simple or giant covalent structure?
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How does bonding affect properties?
Does the type of bonding in a substance affect its properties?
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Bonding and structures
The type of bonding in a substance affects the properties of
that substance. Can you fill in the gaps in the table below?
State at room
Type of
Particles in
Bonding
temperature
structure
structure
millions of
giant ionic
metal and
ionic
lattice
non-metal ions
simple
few non-metal
molecular
atoms
covalent
giant covalent millions of nonmetal atoms
lattice
giant metallic
metallic lattice
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millions of
metal ions
solid
usually liquid
or solid
solid
solid (except
mercury – liquid)
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Melting and boiling point: giant structures
Substances with giant structures generally have high
melting and boiling points because all the atoms are
strongly bonded together to form a continuous 3D lattice.
A large amount of energy is needed to break these bonds.
strong covalent
bonds holds
atoms together
strong ionic
bonds holds
ions together
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strong metallic
bonds holds
ions together
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Effect of structure on properties
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The effect of bonding on properties
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Glossary (1/2)
allotrope – A structurally different form of an element with
different physical properties.
covalent bond – A strong bond between two atoms in
which each atom shares one or more electrons with the
other.
covalent compound – A compound containing atoms
joined by covalent bonds.
double bond – A covalent bond in which each atom
shares two of its electrons.
giant structure – A structure containing millions of atoms
or ions bonded together. The structure extends in three
dimensions until all available atoms are used up.
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Glossary (2/2)
molecule – A small group of atoms which are held together
by covalent bonds.
 molecular solid – A solid substance made up of
molecules held together by weak forces of attraction, forming
a lattice.
single bond – A covalent bond in which each atom shares
one of its electrons.
triple bond – A covalent bond in which each atom shares
three of its electrons.
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Anagrams
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Multiple-choice quiz
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