PPT – Unit 1 - Chemical Changes PowerPoint presentation

About This Presentation

Title:

Unit 1 - Chemical Changes

Description:

Slide 1 – PowerPoint PPT presentation

Number of Views:39

Avg rating:3.0/5.0

Slides: 60

Provided by: Staf1294

Category:

more less

Transcript and Presenter's Notes

Title: Unit 1 - Chemical Changes

1
Unit 1 - Chemical Changes and Structure
2
Reaction Rates
3
Reaction Rates

During the course of a chemical reaction,
reactants are being converted into products.
Measurement of the rate of reaction involves
measuring the change in the amount of a
reactant or product in a certain time.
The rate of reaction changes as it progresses,
being relatively fast at the start and slowing
towards the end.
What is being measured is the average rate over
the time interval chosen.
Reactions can be followed by measuring changes in
concentration, mass and volume.

4
Nat 5

Where property mass/volume/concentration
The above is used when there is no change in
mass/volume/concentration measured, for example
during a colour change reaction.

Higher
5
Collision Theory

A chemical reaction can only occur if there is a
successful collision between reactant molecules.
From national 5 we know that we can speed up a
chemical reaction by
Decreasing particle size (increasing surface
area)
Increasing concentration (of reactant)
Increasing temperature
Adding a catalyst

6
Collision Theory Particle Size

The smaller the particle size, the higher the
surface area.
The higher the surface area, the greater the
number of collisions that can occur at any one
time.
The greater the number of collisions, the faster
the reaction.
Therefore the smaller the particle size, the
faster the reaction rate.

7
Collision Theory Concentration

The higher the concentration, the higher the
number of particles.
The higher the number of particles, the greater
the chance of collisions that can occur.
The greater the number of collisions, the faster
the reaction.
Therefore the higher the concentration, the
faster the reaction rate.

8
Collision Theory Temperature

The higher the temperature, the higher the energy
the particles have.
The higher the energy, the faster the particles
move.
The faster the particles move, the greater the
chance that they can collide with sufficient
energy (activation energy) to be successful.
The greater the number of collisions, the faster
the reaction.
Therefore the higher the temperature, the faster
the reaction rate.

9
Collision Theory Catalyst

A catalyst speeds up a chemical reaction by
lowering the activation energy. (i.e. catalyst
provides another easier route)
The lower the activation energy, the greater the
chance of successful collisions.
The more collisions in a period of time, the
faster the reaction rate.

10
Catalysts

A catalyst is a substance which speeds up a
chemical reaction without getting used up or
changed itself.
There are two main categories of catalyst
a) Heterogeneous
b) Homogenous.

11
Heterogeneous Catalysts

Heterogeneous catalysts have active sites on
their surface.
Reactant molecules form weak bonds with the
surface in a
process called adsorption.
At the same time bonds with the adsorbed reactant
molecules are weakened.
The reactant molecules are also held at a
favourable angle
for a collision with another reactant molecule to
occur.
The product molecules then leave the active site
in a stage
called desorption. The active site is then
available again.

12
surface
Active site
Desorption product molecules formed.
13

Unfortunately unwanted substances can often be
adsorbed onto the active sites thus making them
unavailable for the normal reactants. (Example
lead in petrol.)
When this happens the catalyst is said to be
poisoned.
Sometimes it is not possible to regenerate a
poisoned catalyst and it must be
replaced/renewed.
This adds to industrys costs so every effort is
made to remove any impurities from reactants that
might poison a catalyst.

14
Reactant 1
Reactant 2
Poison blocking active site
Youll need 3 colours when drawing this diagram
(underneath - if possible the previous
catalyst note)
15
Homogeneous Catalysts

A catalyst that is in the same state as the
reactants is
said to be a homogeneous catalyst.
The catalyst forms an intermediate compound with
one of
the reactants. (this intermediate compound later
decomposes to reform the catalyst.)
For example (using Reactants A and B)

Reactant A Catalyst Intermediate Interme
diate Reactant B Product
Catalyst
16
Potential Energy Diagrams
See jotter for labelled diagrams

Labels include
Exothermic or Endothermic
Activated complex
Enthalpy change
Reaction pathway
Potential Energy (KJ)
Activation Energy

17
Bonding, Structure and Properties of Elements
He
S
Fe
C
18
Summary of Bonding types in first 20 elements.
19

Inter means in between.
In other words an INTERmolecular bonds means
bonds in
between the molecules.
Intra means within.
In other words an INTRAmolecular bond means bonds
within the molecule.

20
Types of Bonding in elements

There are 3 types
Metallic Bonding (intramolecular)
Covalent Bonding (intramolecular)
Van der Waals/London Forces (intermolecular)

21
Metallic Bonding

Metallic bonding unsurprisingly only appears
in metal elements.
Metallic bonding occurs between (positively
charged) metal ions and delocalised outer shell
electrons.
delocalised means the electrons are common to
all of the ions (i.e. they move from one to
another)

The movement of delocalised electrons allow
metal elements
to conduct electricity

23
Covalent Bonding

Covalent bonding occurs between two non metal
atoms.
Covalent bonds are held together through the
attraction between the positively charged nucleus
of one atom and the negatively charged outer
electrons of the other atom.
Outer electrons are shared in covalent bonding.

whiteboard example
24
Van der Waals Bonding

Van der Waals bonding is weak bonding which
occurs BETWEEN molecules.
London forces are temporary dipole to temporary
dipole attractions.
Temporary dipoles occur when electrons lie
slightly closer to one atom than the other. This
means for a short time one of the atoms is
slightly negative and the other is slightly
positive (i.e. electrons not shared equally)
London forces (and other intermolecular forces)
are useful when explaining patterns in the
periodic table e.g. melting/boiling points.

25
Bonding in Specific Groups

Groups 1, 2 and 3
All elements in groups 1, 2 and 3 have strong
metallic bonds holding them together.
Metallic bonds allows metals to be shaped (i.e.
malleable and ductile)
Metals have high melting/boiling pts due to
strong metallic bonds
Boron is the only exception as it has very
complex bonding. B12 is almost as hard as
diamond. This suggests a covalent network
structure.

26
The 3 Structures of Carbon (group 4)

Each atom covalently bonds
to 4 other atoms.
This means covalent bonds must
be broken to melt/ boil very
high m.pt/b.pt values.
No free electrons no conduction.
Tunnels between atoms allow
light through transparent
structure.

Diamond
(covalent network)
27

Each atom forms 3 covalent bonds and its last
valence electron becomes delocalised.
As the delocalised electrons are only held weakly
they can flow i.e. graphite conducts electricity.
The delocalised orbitals sit between the layers -
as a result there are 3 strong covalent bonds
WITHIN the layers but only weak interaction
BETWEEN the layers.
Due to these weak interactions, graphite is flaky
as the layers can be easily separated.
Graphite layers are offset (i.e. not above each
other) - light cant travel through it meaning it
is not transparent.

Graphite
(covalent network)
28

3. Buckminsterfullerene (aka Bucky Ball)

The fullerenes, despite being large molecules,
are discrete covalent molecules.
The smallest of fullerenes is a molecule known as
Buckminsterfullerene (C60).
This is a spherical molecule containing 5 and 6
membered carbon rings.
The properties are still being researched so the
full applications are still unknown.

'Bucky Ball'
(covalent molecule)
29

Group 5 (nitrogen and phosphorus)

Nitrogen atoms form diatomic molecules with a
triple covalent bond.
This means that nitrogen only has London forces
between the molecules.
London forces are easily broken and as a result
nitrogen has a low boiling pt. This is why
nitrogen is a gas at room temperature.
Phosphorus forms tetrahedral P4 molecules which
are larger than N2 molecules and as a result it
has stronger London forces between its molecules.
This stronger attraction means phosphorus has a
higher boiling pt and is a solid at room temp.

Group 6 (oxygen and sulphur)

Oxygen atoms form diatomic molecules with a
double covalent bond.
This means that oxygen only has London forces
interaction between the molecules.
London forces are easily broken and as a result
oxygen has a low boiling pt. Hence oxygen is gas
_at_ room temp.
Sulphur forms 8 membered rings. The London forces
between the molecules are strong enough in
sulphur to make it solid at room temperature.

Group 7 (the halogens)
The halogens form diatomic molecules (i.e. they
bond with themselves)
As with oxygen and nitrogen this results in the
halogens only having London forces with each
other molecule.
Fluorine and chlorine are very volatile (and
therefore reactive) gases due to these weak
intermolecular forces.
Group 8 (the noble gases)
As the noble gases have a stable outer electron
shell they do not form bonds. As a result they
remain monoatomic.

32
(No Transcript)
33
Explaining the Melting and Boiling pts Trend In
small discrete covalent molecules the melting and
boiling points are low. This is because only
weak intermolecular London forces have to be
overcome when boiling or melting. The strong
covalent bonds are left unaffected. In the
covalent network solids (carbon, silicon and
boron) strong covalent bonds MUST be broken when
melting or boiling. Breaking these bonds requires
a lot more energy and therefore we get very high
values. In the metal groups (1, 2, 3) strong
metallic bonds MUST be overcome thus they have
high melting/boiling points.
34
Summary of Bonding types in first 20 elements.
Except Buckminsterfullerenes !
H
He
Li
Be
B
C
N
O
F
Ne
Mg
Al
Si
P
S
Cl
Ar
Na
Ca
K
35
Bonding, Structure and Properties of Compounds
36
Types of Bonding in compounds

There are 4 main types
Ionic Bonding intramolecular
Covalent Network Bonding intramolecular
Polar/Non Polar Covalent Bonding - intramolecular
Intermolecular (Van der Waals)
Hydrogen bonding (present in H2O, NH3 and HF)
Permanent dipole Permanent dipole interactions
London forces Temporary dipole interactions

Strongest to Weakest
37
Ionic Bonding

Ionic bonding is an electrostatic attraction
between the positive ions and negative ions.
Ionic bonding is related to the
electronegativities of elements. The greater the
difference in e.n the less likely the elements
are to share outer electrons. (electronegativity
definition and trends are found in later section
of jotter.)
Instead the element with the higher e.n value
will gain the electrons to form a negative ion
and the element with lower e.n value will lose
the electrons to form a positive ion.
Due to the trends of electronegativity, the
elements that are far apart from one another in
the periodic table form ionic bonds. (normally
metal and non metal.) Caesium fluoride is the
compound with the greatest ionic character.

38
Structure
diagram

Ionic compounds do not form molecules. Instead
the positive and negative ions come together to
form lattice structures.
When the lattice forms, energy is released. This
is known as lattice energy or enthalpy.
The overall charge of the lattice must be zero
and therefore this affects the number of each
ions we have present.
In sodium chloride (NaCl) there is an equal
number of Na and Cl- ions.
In calcium fluoride (CaF2) there are twice as
many F- ions than Ca2

39
Covalent Compounds

There are 3 types of covalent bonding in
compounds (all involving combinations of non
metals)
Covalent network structures.
Polar covalent molecules
Non Polar covalent molecules

40
Covalent Network

These covalent network compounds have the same
properties as covalent network elements.
Both SiC and SiO2 have very high melting pts. as
melting requires breaking strong covalent bonds.
Silicon carbide (structurally similar to diamond)
has many uses due to its strength, durability
and low cost.
Silicon carbide is often referred to as
carborundum

42
Polar Covalent Bonding

Most covalent compounds are made from atoms with
slightly different electronegativity (e.n.)
This difference is not significant enough for one
of the atoms to fully remove an electron from the
other. (Approx difference of between 0.5 and 1.6)
As a result the atom (element) with the higher
e.n. holds the electron slightly closer to itself
and therefore becomes slightly negative (?-)
The atom with the lesser e.n. is therefore
slightly positive (?) as the electron is sitting
further away from it.
Covalent bonds with unequal electron sharing are
called polar covalent bonds.

43
Non Polar Covalent Bonding

Non polar (or pure) covalent bonding normally
occurs
when
electrons are equally shared between the two
different atoms. i.e. equal electronegativity.
E.g. Phosphorus Hydride
the compound structure is symmetrical and
therefore charges are overall balanced.
E.g. CH4 (methane) and CO2 (carbon dioxide)

Both polar and non polar?
Its possible for non polar covalent molecules
to have individual polar bonds.
For example Carbon Tetrachloride (CCl4)

diagram from whiteboard
45
Non Polar
?
?
46

Summary of electronegativity values bonding
In general
If the electronegativity difference (usually
called ?EN) is less than 0.5, then the bond is
non polar (pure) covalent.
If the ?EN is between 0.5 and 1.6, the bond is
considered polar covalent
If the ?EN is greater than 2.0, then the bond is
ionic.

47
Properties of Polar/ Non Polar Covalent Bonds

Boiling Points
Polar covalent molecules have higher boiling
points than non polar covalent molecules with a
similar mass.
This is because the intermolecular forces are
stronger (changing from London forces to
permanent permanent dipole interactions.)
Permanent dipole to dipole interaction is caused
via the constant attraction between the ? atoms
and ?- atoms of neighbouring molecules.

diagrams from white board
48

Solvent Action
like substances dissolve in like substances
This means that polar molecules will dissolve in
polar solutions but not in non polar solutions
and vice versa.
This is due to the attraction between ? and ?-
atoms of the water and the polar substance.
Ionic compounds dissolve in polar solutions in a
similar way due to the interaction between the
ions and the ? and ?- atoms.
Ions surrounded by a layer of water molecules
held by electrostatic attraction are said to be
hydrated.

Behaviour in electric field
Copy figure 4.8 on page 49

Viscosity (thickness/ability to pour) Summarise
textbook notes on page 54 (2/3 sentences
max) Miscibility (ability to mix) Summarise
textbook notes on page 57 (2/3 sentences max)
50
Physical properties of some hydrides
Boiling Points
51
O H
F H
N H

The above bonds are very polar due to the large
difference in the electronegativity values.
This interaction is called hydrogen bonding.
Hydrogen bonding occurs in any molecule that
contains any of the above bonds but mainly in
hydrogen fluoride (HF), water (H2O) and ammonia
(NH3). These intermolecular forces affect the
properties of these compounds.
Hydrogen bonding is stronger than both London
forces and permanent dipole to dipole
interactions but weaker than covalent bonding.

52
Density of Water
Water is unusual as its solid form (ice) is less
dense than its liquid form (water). This means
that ice floats on water whereas most other
solids sink in their own liquid forms. This
phenomenon is due to the structure and bonding
which takes place between the water
molecules. As water molecules cool, they
contract. However, at 4oC they begin to expand.
This is because of hydrogen bonds between the
water molecules. This decreases the density of
ice (greater volume/same mass) compared to that
of the liquid water. Ice floating is vital to
real life i.e. fish/marine life surviving
under frozen lakes etc (https//www.youtube.com/wa
tch?vT4GCShGvw-M)
53
Trends in the Periodic Table
54

Density (measured in g/cm3)
Across a period (starting from group 1) the
density increases towards the centre (group 4)
and then decreases.
Density tends to increase down a group (as atomic
number increases.)

Atomic size
Atomic size (or covalent atomic radius) is half
the distance between the nuclei of two bonded
atoms.
Single bond lengths between atoms of different
elements can be found by adding their individual
covalent radii.
e.g. the covalent radii of hydrogen and chlorine
are 37 and 99 pm so the bond length in HCl is 37
99 pm 136 pm
There are two clear trends in the periodic table
Going across a period covalent radii decreases.
This is because
Going down a group covalent radii increases. This
is because

Good to know but not essential...
the nuclear charge increases but the number of
electron shells stays the same i.e. the outer
electrons are held more tightly, making the atom
smaller.
the number of electron shells increases and
therefore the inner (full) electron shells shield
the outer electrons from the nuclear charge.
(known as shielding effect) i.e. the outer
electron are held less tightly, making the atom
bigger.
56
First Ionisation Energy

Definition
First ionisation energy is the energy required to
remove one mole of electrons from an element in
gaseous state. (example at top of page 11 in data
book no excuses!)
Trends
Across a period increases due to an increased
nuclear charge holding the outer electrons more
closely (smaller atoms.) This means you need MORE
energy to remove a mole of electrons.
Down a group decreases due to the shielding
effect (bigger atoms.) This means the outer
electrons are further away from the nucleus and
therefore this attraction is less, thus it is
easier (less energy) to remove one mole of
electrons.

57
Other types of ionisation questions

Calculation (whiteboard examples)

The first ionisation energy of lithium
520kJmol-1 but its second ionisation energy value
7298kJmol-1.
Why is there such a big difference between the
two
values?
Lithium achieves a stable outer electron shell
(octet) when it loses one electron. Therefore
first ionisation energy is small. The second
electron would therefore be removed from an
stable octet which is unfavourable and requires a
lot of energy.

58
Electronegativity

Electronegativity is a measure of the tendency of
an
atom to attract electrons. (think pulling power)
Electronegativity is measured on the Pauling
scale.
Trends
Electronegativity increases across a period.
Electronegativity decreases down a group.
(Hint Fluorine is the highest value)

Melting and Boiling Points
Generally, the stronger the bond between atoms,
the higher the energy required to break that
bond. Melting/boiling points are varied and don't
generally form a trend across a period however
Metals generally possess a high melting point.
Most non-metals possess low melting points.
Group 4 have the highest values.
Metal group example
In group 1 (alkali metals), the melting/boiling
pts decrease as the atomic number increases. This
is because there is an decrease in the attraction
between the particles. (refer to bonding)
Non metal group example
In group 7 (halogens) the melting/boiling pts
increase as the atomic number increases. This is
because there is an increase in the attraction
between the particles. (refer to bonding)