2024 Chemistry Main PPT PDF

Summary

This document is a presentation on chemistry, covering the topic of matter and its study, and details concepts like atomic structure, electronic configurations, and chemical bonds.

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CHEMISTRY
THE STUDY OF MATTER
 TOPIC OVERVIEW

01 02 03 04 05
Atomic Electronic Ionic Covalent Metallic
Structure Configurati Bonding Bonding Bonding
on
 RECAP Y8: ELEMENTS
 Elements are substances
made up of only one type of
atom
 There are 118 known
elements on the periodic
table
 Each element is given a
symbol that represents their
name:
 H for hydrogen
 Pb for lead
 RECAP Y8: ARRANGEMENT OF ATOMS

Atoms can exist as
either:
 Single atoms
 Molecules
(groups of
atoms)
 Crystal lattices
(grid-like
structure)
… and this year you will finally find out why!
ATOMIC
STRUCTURE
 HISTORY OF THE ATOMIC MODEL

John Dalton
 Atoms are indivisible and indestructible
 An element is made up of atoms that are
identical in size, mass and other properties
 Different elements had atoms of differing size
and mass
 ‘Bowling ball’ model
 HISTORY OF THE ATOMIC MODEL

JJ Thomson
 Discovered the electron while working with
cathode rays
 Electrons are negatively charged and 2000
times lighter than the smallest known atom, the
hydrogen atom
 If atoms are neutral, then the negative
electrons must be embedded in a ball of
positive charge
 “Plum pudding” model
 HISTORY OF THE ATOMIC MODEL

Ernest Rutherford
 Discovered that atoms are mostly empty
space with a small, positive nucleus
 Negative electrons occupied this empty space
 “Nuclear model”
 HISTORY OF THE ATOMIC MODEL

Niels Bohr
 Refined Rutherford’s model by saying that
electrons orbit around the nucleus along certain
pathways
 Like the solar system, where planets are held in
orbit by the Sun’s gravity
 But in the atom, negative electrons are held in
orbit by the electrostatic attraction to the positive
nucleus
 “Planetary model”
HISTORY OF THE ATOMIC MODEL
 ATOMIC STRUCTURE
 The atom is made of three subatomic
particles:
1. Protons (+ charge)
2. Neutrons (neutral charge)
3. Electrons (- charge)
 Protons and neutrons are found in the
nucleus. They are relatively heavy.
 Electrons orbit the nucleus. They are
very light.
 ATOMIC STRUCTURE
What role do
 protons,
 neutrons and
 electrons

play in determining the
 type,
 mass,
 stability and
 charge of the atom?
  What determines the type of atom?

The number
 What of protons
determines the mass of an
atom?
THE ROLE OF
PROTONS, The number of protons & neutrons
 What determines the net charge of
NEUTRONS &
an atom?
ELECTRONS The ratio of protons to electrons
 What determines the stability of an
atom?
The ratio of neutrons to protons
 ATOMIC STRUCTURE

PROTON NEUTRON ELECTRON

LOCATION

MASS

CHARGE

ROLE
 ATOMIC STRUCTURE

PROTON NEUTRON ELECTRON

LOCATION Nucleus Nucleus Orbits the
nucleus
MASS 1 1 Negligible
(0.0005)
CHARGE +1 0 -1

ROLE Determines the Required for Responsible for
identity of atom stability of reactivity
nucleus
 ATOMIC STRUCTURE & THE PERIODIC TABLE

The periodic table is
organised to give us Atomic
information about the number
atomic structure of
elements. Symbol
 Atomic number =
Name
number of protons
 Mass number =
number of protons +
why neutrons
does the mass number have decimals??? Mass number
 ISOTOPES

Isotopes are atoms of the same
element (same number of protons)
that have a different number of
neutrons.
E.g. the element Carbon has 3
known isotopes:
 Carbon-12: 6 protons + 6
neutrons
 Carbon-13: 6 protons + 7
neutrons
 Carbon-14: 6 protons + 8
neutrons
 ISOTOPES

The mass number on the periodic
table is a calculated average of
all known isotopes of an element –
that’s why it is not a whole
number! 98.9% 1.1% 4 valence electrons, so both
are unwilling to give away electrons
2. Instead, they ‘share’ a pair of electrons, forming a
covalent bond
3. No electrons leave their original atoms, so the atoms
remain neutral (no ions are formed)
EXAMPLE: CHLORINE GAS

 Chlorine gas is a covalent
molecule with two chlorine – –
atoms, Cl2 – – – – – –
– – – – – –
 A neutral chlorine atom has
– – Cl – – Cl – –
17 electrons, arranged 2, 8, 7
– – – – – –
 Each chlorine atom needs – – – –
– –
one more electron to – –
achieve a full outer shell (2,
8, 8)
EXAMPLE: CHLORINE GAS

– –
– – –
–
 To make it easier to
visualise, we are only – Cl Cl –
going to look at the
valence shell – – – –
– –
EXAMPLE: CHLORINE GAS

 Each atom will ‘share’ an electron, – –
forming a pair of shared electrons – –

 The pair of electrons is included in the – –
–
outer shell of both atoms at once, giving Cl –
Cl
both atoms a full outer shell –
–

 Both chlorine atoms are now covalently – – –
–

bonded by a single pair of shared
electrons
 EXAMPLE: CHLORINE GAS

– –
– –

 The chemical formula for a molecule –
– –
Cl Cl
chlorine gas is Cl2 – two chlorine atoms –
–
bonded together –
–
 A single covalent bond (one pair of – – –

shared electrons) can be represented by
a straight line between both atoms
EXAMPLE: OXYGEN GAS

 A neutral oxygen atom has 8 – –
electrons, arranged 2, 6 – – – – – –

 Each oxygen atom needs two – O O –

more electron to achieve a full – – – –
– –
outer shell
(2, 8)
EXAMPLE: OXYGEN GAS

– – – –

 To make it easier to visualise,
– O – – O –
we are only going to look at – –
the valence shell – –
EXAMPLE: OXYGEN GAS

 Each atom will ‘share’ two electrons,
forming a two pairs of shared
– – – –
electrons
–
 The pairs of electrons are included in the –
outer shell of both atoms at once, giving O – O
–
both atoms a full outer shell
– – – –
 Both oxygen atoms are now covalently
bonded by two pairs of shared electrons
EXAMPLE: OXYGEN GAS

– –

 The chemical formula for a molecule – – –
–
oxygen gas is O2 – two oxygen atoms O – O
bonded together – – –
– –
 A double covalent bond (two pair of
shared electrons) can be represented by
a two straight lines between both
atoms
EXAMPLE: METHANE GAS

A neutral carbon atom has 6
electrons, arranged 2, 4
 Carbon needs four more –
– –
electron to achieve 2, 8
– C – H
A neutral hydrogen atom has 1 –
valence electron –
 Hydrogen needs one more
electron to achieve 2 (first In what ratio will these two
shell is full at 2 e-) elements react?
EXAMPLE: METHANE GAS

–

H

 To make it easier to visualise,
–
we are only going to look at –
–
the valence shell
H – C – H
 The ratio is
one carbon : four hydrogen –

–

H
EXAMPLE: METHANE GAS

 Carbon becomes the centre atom and H
will ‘share’ its electrons, forming a pair – –
of shared electrons with each
hydrogen atom – –
H –
C – H
 Each hydrogen atom is now covalently
bonded to the carbon atom by a single – –
pair of shared electrons
H
EXAMPLE: METHANE GAS

H
– –

 The chemical formula of methane gas is – –
CH4 H –
C – H

 Each covalent bond (one pair of shared – –
electrons) can be represented by a
H
straight line between carbon and
hydrogen
 COVALENT BONDING – WATER

Draw the number of valence Draw how electrons are
electrons for each element: shared in this covalent
compound:

In what ratio will
O H
these elements
react?
 COVALENT BONDING – AMMONIA GAS

Draw the number of valence Draw how electrons are
electrons for each element: shared in this covalent
compound:

In what ratio will
N H these elements
react?
 COVALENT BONDING – CARBON DIOXIDE

Draw the number of valence Draw how electrons are
electrons for each element: shared in this covalent
compound:

In what ratio will
C O these elements
react?
METALLIC
BONDING
METALLIC BONDING

Metallic bonding is a type of chemical bonding that takes
place between two metals
1. Metal atoms usually have