New OCR Gateway specification from September
2016 Higher tier: grades 9 to 4:
In this and subsequent posts I’m simply going to explain and illustrate each learning objective as they come up in the topics in the new GCSE specification.
I’m giving you my notes from each lesson.
You can really get ahead of your class if you follow this blog and all the posts that will appear here about the new GCSEs over the coming months.
This rejigging of the specification is just that: there is nothing really new here it has all been with us for the past half century at least.
And remember all that’s written in italics is for the higher tier paper only.
The way the ions arrange themselves depends on their size but a common arrangement is for there to be six positive ions around each negative ion and six negative ions around each positive ion.
4 bonds give a tetrahedral molecule like methane.
All three are shown in this illustration below:
These inter–atomic bonds are very strong.
These inter–atomic
bonds are very strong.
High density polythene (HDPE) is more crystalline than low density polythene (LDPE).
In this and subsequent posts I’m simply going to explain and illustrate each learning objective as they come up in the topics in the new GCSE specification.
I’m giving you my notes from each lesson.
You can really get ahead of your class if you follow this blog and all the posts that will appear here about the new GCSEs over the coming months.
This rejigging of the specification is just that: there is nothing really new here it has all been with us for the past half century at least.
And remember all that’s written in italics is for the higher tier paper only.
C2
Elements, Mixtures and Compounds
C2.2 Bonding
C2.2 Bonding
C2.2d
describe and compare the nature and arrangement of chemical bonds in:
i.
Ionic
compounds
In ionic compounds
bonds exist between electrically charged particles called ions.
Positive ions
(cations) electrostatically attract negative ions (anions).
The attraction is that
of positive charge for negative charge, an electrostatic attraction.
The way the ions arrange themselves depends on their size but a common arrangement is for there to be six positive ions around each negative ion and six negative ions around each positive ion.
In the diagram below,
of sodium chloride, sticks stand for ionic or electrostatic bonds.
Count the sticks to
confirm the six—six arrangement of bonds and ions.
ii.
simple molecules
Substances like
chlorine gas, water , ammonia and methane exist as simple molecules or groups
of atoms.
Electrons shared in
pairs join the atoms together in these molecules.
These are pairs of
outer shell electrons.
These electrons hold
both atoms positive nuclei together.
These bonds repel each
other because they are formed from negatively charged electrons.
The repulsion results
in simple molecules having simple shapes.
2 bonds give an
angular molecule like water
3 bonds give a pyramidal molecule like ammonia
3 bonds give a pyramidal molecule like ammonia
4 bonds give a tetrahedral molecule like methane.
All three are shown in this illustration below:
iii.
giant covalent structures
Typical giant covalent
structures are diamond, graphite, nano–tubes and grapheme sheets.
a) Diamond
Four bonds connect
each carbon atom to four others in a tetrahedral arrangement.
These inter–atomic bonds are very strong.
The ball and stick
model below shows this tetrahedral arrangement of atoms.
The arrangement is
repeated continuously throughout a diamond crystal.
b) Graphite
Three bonds connect
each carbon atom to three others in a sheet of atoms arranged in hexagons.
But the sheets bond
weakly to each other so that the sheets can easily slide over each other.
As with diamond the
arrangement is repeated through a crystal of graphite.
The giant structure is
evident in this picture below:
c) Nano tubes
Nano-tubes are tubes
of rolled up graphite sheets.
Each carbon atom is
bonded to three others using three strong bonds.
The carbon atoms are
arranged in hexagons.
d) Graphene
Graphene is a single
sheet of graphite.
A one atom thick layer as in the diagram below.
The carbon atoms are
arranged in hexagons and each has three bonds connecting it to three
others.
iv.
polymers
A typical polymer is
polythene.
Polythene is a
molecule formed from long string of — CH2 —groups maybe about 1000
in a long line.
Polythene is often
represented by a long line.
There are very strong
single bonds between the carbon atoms in the molecule.
There are much, much
weaker bonds between the polymer chains.
The chains can fold
together to form areas of plastic that are more crystalline than others which
are more amorphous.
A way of showing this
difference is shown below.
High density polythene (HDPE) is more crystalline than low density polythene (LDPE).
v.
metals
Atoms in metals are attached to each other using
multi-directional bonds.
Metal atoms have outer shells of electrons that
combine with each other to form a sea of loose (or delocalized) electrons that
can move from atom to atom.
Best to show this idea using the kind of diagram
below.
The atoms are arranged close packed like the reds in
snooker.
You could be asked to draw the diagram above.
C2.2e
explain chemical bonding in terms of electrostatic forces and the transfer or
sharing of electrons
i)
Ionic bonding
In
ionic compounds, bonds exist between electrically charged particles called
ions.
Ions form when the metal atom loses its outer shell electrons and they are transferred to the non–metal atom and complete its outer shell.
The result is that both positive and negative ions have noble gas electron arrangements with full outer shells.
Positive ions (cations) electrostatically attract negative ions (anions).
Ions form when the metal atom loses its outer shell electrons and they are transferred to the non–metal atom and complete its outer shell.
The result is that both positive and negative ions have noble gas electron arrangements with full outer shells.
Positive ions (cations) electrostatically attract negative ions (anions).
The
attraction is that of positive charge for negative charge, an electrostatic
attraction.
The
way the ions arrange themselves depends on their size but a common arrangement
is for there to be six positive ions around each negative ion and six negative
ions around each positive ion.
ii)
Covalent bonding
Substances
like chlorine gas, water , ammonia and methane exist as simple molecules or
groups of atoms.
Electrons
shared in pairs join the atoms together in these molecules as in this example of the dot and cross diagram for water.
These
are pairs of outer shell electrons.
These
electrons hold both atoms positive nuclei together.
You can watch a good Youtube video here about
ionic bonding (September 2016)
And on Youtube here is the
quirkiest video about covalent bonding (September 2016)
C2.2f
construct dot and cross diagrams for simple covalent and binary ionic
substances
Let’s
keep all this simple.
These
are the examples of substances you’ll probably have to be able to construct.
Simple
covalent molecules probably means Chlorine, Oxygen, Water, Ammonia, Methane,
Carbon Dioxide
Here
are the dot and cross diagrams for each one:
Chlorine
Oxygen
Water
Ammonia
Methane
Carbon
Dioxide
Binary
ionic substances means substances made from a metal and a non metal and
probably refers to sodium chloride, magnesium oxide, sodium oxide and calcium
chloride.
Sodium
chloride
Magnesium
oxide
Sodium
oxide
Calcium
chloride
C2.2g
describe the limitations of particular representations and models to include
dot and cross diagrams, ball and stick models and two- and three-dimensional
representations.
No model can capture
the fact that at all temperatures the atoms and ions in substances are
vibrating non-stop even though the particles are bonded to others.
Dot and cross diagrams
do not tell us anything about the shape of the molecule or the arrangement of
the ions in an ionic crystal.
Ball and stick models
falsely assume that particles are solid and have no attraction for other
particles beyond those to which they are attached.
Ball and stick models
forget that an atom or ion is bigger than its nucleus and that the electrons
around the atom fill the space around the ball and stick: these models are
called space–filling models.
Compare the ball and
stick model with the slightly more accurate space–filled model of methane bottom right.
You can see in this illustration how difficult it is to show 3D in 2D where the methane displayed formula has two C—H bonds as thick lines, one bond as a wedge meant to be pointing out of the screen and one dotted line as a bond meant to be pointing behind the screen.
You can see in this illustration how difficult it is to show 3D in 2D where the methane displayed formula has two C—H bonds as thick lines, one bond as a wedge meant to be pointing out of the screen and one dotted line as a bond meant to be pointing behind the screen.
C2.2h
explain how the reactions of elements are related to the arrangement of
electrons in their atoms and hence to their atomic number
Elements with up to
three electrons in their outer shells are metals and they react to lose those
electrons to leave a full outer shell.
These metals have
atomic numbers that put them in Groups 1 to 3.
Their atomic numbers (number
of protons) remain the same on reaction and that means that losing up to three
electrons their particles become positively charged ions or cations as we see in the illustration below the magnesium atom loses two electrons so it now has 10 electrons and 12 protons an overall electrical charge of 2+.
Elements in Groups 5,
6 or 7 gain electrons on reaction with other elements so as to fill their outer
shells.
Their atomic numbers
(number of protons) also remain the same on reaction and that means that their
particles become negatively charged ions (anions) on reaction as we can see in the diagram above where the oxygen atom gains 2 electrons to have 10 electrons and 8 protons, an overall charge of 2–.
C2.2i
explain in terms of atomic number how Mendeleev’s arrangement was refined into
the modern periodic table
Mendeleev’s
arrangement was based on atomic mass and properties of the elements.
Mendeleev
correctly predicted on the basis of its properties the discovery of germanium
which he called eka–silicon.
But
Mendeleev’s Periodic Table had Beryllium in the wrong place between carbon and
nitrogen where there was no space!
Atomic mass at the time was determined using the valency of the element get the valency wrong and the atomic mass was out.
Atomic mass at the time was determined using the valency of the element get the valency wrong and the atomic mass was out.
Mendeleev gave beryllium a valency of 2 instead of 3 and beryllium slipped into its
right place between lithium and boron.
Iodine
and tellurium could have been in the wrong places because tellurium’s atomic
weight is greater than that of iodine.
But
an examination of the properties of iodine placed it correctly in the group
with chlorine etc..
It
became clear much later that if instead the elements were ordered according to
their atomic number (number of nuclear protons) then the anomalies were
resolved.
Today
in a modern Periodic Table the elements are arranged in order of increasing
atomic number.
The
history
of the Periodic Table is well written at this level here (September 2016)
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