Nuclear Model of the Atom PDF

Summary

This document provides a summary of the nuclear model of the atom including atomic structure, the periodic table, and electron configurations using examples and trends in atomic radii, ionic radii, electronegativity, and ionisation energy.

Full Transcript

Nuclear model of the atom
Electrons (e-)
Atoms are made up of 3 types of particles:
1. Neutrons: have no charge but have mass. Found in the nucleus.
2. Protons: have positive charge and same mass as neutrons. Found in the nucleus.
3. Electrons: have negative charge and a mass 1/1836 that of protons. Found in all the space
surrounding the nucleus.
Nucleus
For a neutral atom
No of protons = No of electrons
1 atomic mass unit= 1.67 x 10-27 kg
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1. Atomic number (Z)
Z = number of protons in nucleus
For a Neutral atom: Also the number of electrons orbiting the nucleus
2. Mass number (A)
A = number of protons + neutrons in the nucleus
No of neutrons = A – Z
Atomic Properties
Let’s consider an example:
1. Z =noofprotons=6
2. No of protons = no of electrons = 6 3. Noofneutrons=A–Z=12–6=6
Mass number Atomic number
No of protons = No of electrons = No of neutrons =
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Atomic number Element symbol
Element name Mass number
1. No of protons =
2. No of electrons =
3. No of neutrons =
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Atomic number Element symbol
Element name Mass number
One more example:
Z = no of protons = 29 = no of electrons A = 63.55 ≈ 64
No of neutrons = A – Z = 64 – 29 = 35
1. No of protons =
2. No of electrons = 29
3. No of neutrons = 35
29
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Things we now know about atoms
An atom contains a very small nucleus composed of protons and neutrons.
Protons and neutrons are much heavier than electrons; most of the mass is in the nucleus.
 Electrons occupy almost all of an atom’s volume.
Atoms of one element differ in properties from atoms of all other elements.
An element consists of only one type of atom.
A macroscopic sample of an element contains an incredibly large number of atoms, all of
which have identical chemical properties.
A compound consists of atoms of two or more elements in a whole-number ratio.
If the nucleus was the size of a blueberry, the atom would be a football stadium.
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Periodic table
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Birth of periodic table
Antoine Lavoisier (1789)
Grouped elements into gases, metals, non-metals and earth elements.
Wolfgang Dobereiner (1829)
grouped atoms into “triads”, groups of similarly behaving atoms For example: Lithium,
sodium and potassium
Dmitri Mendeleev (1869)
Listed elements in order of atomic weights
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Birth of periodic table-Mendeleev
Saw trends in physical and chemical properties based on atomic weight (AR).
Placed elements into rows of increasing mass and columns of similar reactivity.
Gaps appeared, so he predicted the mass and properties of these ‘undiscovered’ elements
Soon afterwards they were actually discovered
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Modern periodic table
Now arranged in order of increasing atomic number (Z)
Vertical columns are called groups
Ø Elements in a group exhibit trends in chemical reactivity.
Horizontal rows are called periods.
Ø A number of trends are found within periods.
There are 4 blocks, based on where the element’s outer
electrons lie.
Ø s block, p block, d block, f block.
Looking at an element’s position can tell you about its chemical and physical properties.
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Groups
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Periods

Transition metals
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Groups of the periodic table
Group 1: Alkali metals
Ø Soft silvery metals, not found in elemental state in nature. Ø Melt at low temperature.
Ø Produce H2 on reaction with water.
Ø Reactivity increases down the group.
Ø Each have a single electron in their outermost shells
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Groups of the periodic table
Group 2: Alkaline earth metals
Ø Soft metals.
Ø Often found in nature as oxides (Calcium oxide, barium oxide) Ø Commonly found in
nature (magnesium and calcium )
Ø Used in radiation therapy (Radium)
Ø Each have two electrons in their outermost shells
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Groups of the periodic table
Group 17: Halogens
Ø Very reactive
Ø Fluorine and chlorine are gases
Ø Bromine is liquid and iodine a solid
Ø Fluoride used in toothpaste, chloride use for disinfection, iodide has several important
functions in the body (thyroid gland)
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Groups of the periodic table
Group 18: Noble gases
Ø Colourless, odourless gases.
Ø Full outer-shell (closed shell) electron-quite unreactive Ø Low temperature cryogenics
(helium)
Ø Absorb and emit electromagnetic radiation (neon lamps)
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d block elements
Transition Elements
Ø Bridge the active groups 1 – 2 and 12 – 18.
Ø Can form compounds in several oxidation states Ø Form highly coloured compounds
Ø Fe, Co, Ni can display ferromagnetism
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f block elements
Lanthanides and Actinides (inner transition elements)
Ø Heavy metals
Ø Can form compounds in several oxidation states
Ø Actinides are radioactive in nature (Nuclear fuel, imaging)
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Trends in the periodic table
1. Atomic radii
2. Ionic radii
3. Electronegativity 4. Ionisation energy
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1. Trends in atomic radii
Atomic radius is the size of an atom of a given element.
increased nuclear charge-> outermost electrons are pulled closer to the nucleus.
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1. Trends in atomic radii
more electron shells -> outermost electrons get further from nucleus.
Atomic radius decreases across the table and increases down the periodic table.
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Atomic radius increases

2. Trends in ionic radius
Net positive/negative charge due to loss/gain of an electron
Ionic radius is the size of an ion for a given element
Metalsbecomesmalleruponionisation(theyloseelectrons) Ca > Ca2+
Non-metals(right)getbigger(theygainelectrons.) O < O2-
Decreases across the table and increases down the periodic table.
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3. Trends in electronegativity
Electronegativity : ability of an atom to attract electrons.
Left of table: valence shells less than half full -> these atoms (metals) tend to lose electrons
(low electronegativity).
Right of table: valence shells more than half full -> these atoms (nonmetals) tend to gain
electrons (high electronegativity).
Down table: number of energy levels (and distance from nucleus to outer orbitals) increase.
Shielding weakens nuclear attraction (ability of atom to attract electrons)
Increases across the periodic table and decreases down the table.
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4. Trends in ionisation energy
Ionisation energy: energy needed to remove one electron from the outermost shell of an
atom.
Electronegative elements and noble gases: don’t want to lose an electron->high ionisation
energies.
Elements with many full inner shells: interact poorly with outermost electrons->low
ionisation energies.
Increases across the periodic table and decreases down the table.

Atomic structure
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Atomic structure and periodicity
Atomic Number gives the number of protons and electrons in an element.
Octet Rule: During a chemical reaction, an element will try to attain the
same number of electrons as the nearest noble gas.
Atoms try to gain, lose or share electrons in order to have the same number of electrons
as a noble gas.
The distribution of electrons within the levels and sublevels—control these chemical and
physical properties.
This is electron configuration
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Quantum numbers
We can describe each electron individually through 4 quantum numbers.
Pauli Exclusion Principle: These are unique and cannot be shared.
Electrons within an atom are confined to a set of energy levels. The ‘address’ of an electron
within the atom is described using the following 4 quantum numbers:
n Principal Energy Level l Subshell
ml Orbital
ms Spin
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1. Principal energy levels (n)
Each Principal Energy Level (or electron shell) has a fixed maximum number of electrons.
The higher the energy level, the more electrons it can hold:
n = 1 n = 2 n = 3 etc...
Holds 2 electrons Holds 8 electrons Holds 18 electrons
n=3
n=2
n=1
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2. Energy subshells (l): secondary quantum number
Ø Also known as Orbital, angular or azimuthal quantum number
ØShells are subdivided into subshells. The number of subshells within each shell is the
principal energy level (n) of that shell:
n = 1 n = 2 n = 3 etc...
has 1 subshell (s)
has 2 subshells (s, p) has 3 subshells (s, p, d)
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3. Atomic orbitals (ml)
The subshells are divided into atomic orbitals. Each atomic orbital can hold 2 electrons. Each
electron in the pair must have opposite spin (spin can be ‘up’ or ‘down’).
s subshells have 1 orbital (2 electrons)
p subshells have 3 orbitals (6 electrons)
d subshells have 5 orbitals (10 electrons)
f subshells have 7 orbitals (14 electrons) etc....
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4. Spin quantum number (ms)
Each electron in a pair must have opposite spin (spin can be ‘up’ or ‘down’).
Clockwise rotation around the axis of the electron
m s = + !"
This is represented by ↑
Anti-clockwise rotation around the axis of the electron
m s = - !"
This is represented by ↓
↑↓
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n=4
n=1
Ø n=1 (1st shell) Ø 1 subshell = s
Ø n=4 (4th shell)
Ø 4 subshells = s, p, d and f
Ø Can hold 32 electrons n=2
n=3
Ø n=2 (2nd shell)
Ø 2 subshells = s and p
Ø Can hold 8 electrons à 2+6
Ø n=3 (3rd shell)
Ø3 subshells = s, p and d
Ø Can hold 18 electrons à 2+6+10
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Electron structure and periodicity
The principal energy level (n) corresponds to the row of the periodic table
n=1
n=2 n=3
n=4 n=5
n=6 n=7
5 pairs/subshell
1 pairs/subshell
3 pairs/subshell
The electrons within subshells pair up into atomic orbitals (ml)
s block 2 electrons
d block 10 electrons
p block 6 electrons
 Each of the two electrons in an orbital have opposite spins (ms)
Subshells (l)
correspond to blocks of the periodic table.
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Shapes of atomic orbitals
↑↓
s
s orbitals
Ø Shaped like a sphere
Ø There is one s orbital within the s
subshell, it can hold 2 electrons
p orbitals
Ø Have two lobes
Ø Shaped like a dumbbell
Ø In the p subshell, there are 3 p orbitals of equal energy
↑↓ ↑↓ ↑↓ 𝑝# 𝑝$ 𝑝%
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Shapes of atomic orbitals
d orbitals (and higher)
Ø Can have complicated shapes
↑↓ ↑↓ ↑↓ ↑↓ ↑↓ 𝑑#$ 𝑑#% 𝑑$% 𝑑#! &$! 𝑑%!
Ø Electron orbitals with same energy orbitals is known as degenerate orbitals Ø p has 3
degenerate orbitals, d has 5
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Electron pairing rules
Hund’s Rule: Whenever 2 or more orbitals of equal energy are available (such as px, py, pz),
the electrons will occupy them singly before pairing up.
↑↓↑ ↑↑↑ 𝑝# 𝑝$ 𝑝% 𝑝# 𝑝$ 𝑝%
A p subshell with 3 electrons will have one electron in each p orbital.
This is explained in terms of energy.
There is a pairing energy for pairing +1/2 and -1/2 electrons. This is a penalty when there
are free orbitals of the same energy.
Wrong!
Correct J
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Electron pairing rules
Pauli’s Exclusion Principle: Each orbital can hold one pair of electrons; but the electrons will
have opposite spins.
↑↑ ↑ ↑ ↑↓ ↑ ↑ 𝑝# 𝑝$ 𝑝% 𝑝# 𝑝$ 𝑝%
A p subshell with 4 electrons will have 3 spin-up electrons and 1 spin- down.
Wrong!
Correct J
 This is a quantum explanation. An electron is described by the quantum numbers (n, l,
ml , ms).
They are unique to one electron and cannot be duplicated.
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The Aufbau principle
Electrons occupy the lowest available energy level, in order to be as close to the nucleus as
possible.
The order in which these orbitals are filled are shown below:
1s
2s 2p
3s 3p
4s 4p 4d
1s 2s 2p 3s 3p 4s 3d 4p 5s 4d 5p 6s
Note that the 4s orbital is filled before the 3d orbital.
3d
4f
5s 5p
6s 6p 6d 7s 7p
5d 5f
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Writing electron configurations
Electronic configuration: The arrangement of electrons within an atom.
Describes how many electrons are present in each orbital of that atom. The electronic
configuration of Hydrogen is given below:
No of electrons within that subshell
Hydrogen: 1 𝑠%
Subshell energy level
Principal
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The n = 1 energy level
The n=1 energy level has only a single s orbital, the 1s orbital.
Hydrogen and Helium are both n = 1 elements. Their electronic
configurations are:
Hydrogen: 1 𝑠% ↑ n=1
Helium: 1 𝑠&
↑↓
1s
2s 2p 3s 3p
4s
5s 5p
6s
7s 7p
3d
4p 4d 4f
5d 5f 6p 6d
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The n = 2 energy level
The n=2 energy level has both s and p subshells; called the 2s and the 2p. Carbon is an n=2
element, its electronic configuration is :
Carbon:1𝑠&2𝑠&2p& 1 𝑠 & 2 𝑠 & 2 𝑝 '% 2 𝑝 (%
↑↓ ↑↓↑ ↑
1s 2𝑠
2𝑝# 2𝑝$ 2𝑝%
1s
2s 2p 3s 3p 4s 4p 5s 5p 6s 6p 7s 7p
6 electrons
3d
4d 4f 5d 5f
6d
n=2
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The n=3 energy level
The n=3 energy level has s, p, and d subshells; called the 3s, the 3p and 3d subshells.
Note: The 3d is only filled after the 4s orbital (3d filled when n=4)!
Sulfur:
1s
2s 2p
1 𝑠& 2𝑠& 2p+ 3s& 3p,
1 𝑠& 2𝑠& 2𝑝'& 2 𝑝(& 2𝑝-& 3𝑠& 3𝑝'& 3𝑝(% 3𝑝-%
n=3
16 electrons
3s
4s
5s 5p 6s
7s 7p
3p 3d
4p 4d 4f
5d 5f 6p 6d
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Electron configuration examples
Hydrogen atom (H): Z = 1 1𝑠
Helium atom (He): Z = 2
1𝑠
Lithium atom(Li): Z = 3 1𝑠 2𝑠 2𝑝
→ it has one electron
↑ H: 1 𝑠% → it has two electrons
↑↓ He:1𝑠& → it has three electrons
↑↓ ↑
2𝑝 2𝑝 2𝑝 #$%
Li: 1 𝑠& 2𝑠% Li: 𝐻𝑒 2𝑠%
1s
2s 2p 3s 3p 4s 4p 5s 5p 6s 6p 7s 7p
3d
4d 4f 5d 5f
6d
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Electron configuration examples
Carbon atom (C): Z = 6 → it has six electrons
1𝑠 2𝑠 2𝑝
↑↓ ↑↓ ↑ ↑
C:1𝑠&2𝑠&2𝑝'% 2𝑝(% & & &
C:1𝑠 2𝑠 2𝑝
2𝑝#
Nitrogen atom(Li): Z = 7 1𝑠 2𝑠 2𝑝
↑↓ ↑↓
2𝑝$ 2𝑝%
→ it has seven electrons
↑↑
2𝑝# 2𝑝$ 2𝑝%
N:1𝑠&2𝑠&2𝑝'% 2𝑝(%2𝑝-% ↑ N: 1 𝑠& 2𝑠&2𝑝.
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Electron configuration examples
Oxygen atom (O): Z = 8 → it has eight electrons
1𝑠 2𝑠 2𝑝
O:1𝑠&2𝑠&2𝑝'& 2𝑝(%2𝑝-% O: 1 𝑠& 2𝑠& 2𝑝,
↑↓ ↑↓
Neon atom(Ne): Z = 10 1𝑠 2𝑠 2𝑝
2𝑝$ 2𝑝%
→ it has ten electrons
Ne: 1 𝑠& 2𝑠& 2𝑝'& 2𝑝(& 2𝑝-&
↑↓ ↑ ↑
2𝑝#
↑↓ ↑↓ ↑↓ ↑↓ ↑↓ Ne: 1 𝑠& 2𝑠& 2𝑝+ 2𝑝# 2𝑝$ 2𝑝%
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Argon atom (Ar): Z = 18 1𝑠 2𝑠 2𝑝
→ it has eighteen electron
1s
2s 2p 3s 3p 4s 4p 5s 5p 6s 6p 7s 7p
↑↓ ↑↓ ↑↓ 2𝑝#
3𝑠 3𝑝
↑↓↑↓ ↑↓ ↑↓↑↓↑↓
3d
4d 4f 5d 5f
6d
Electron configuration examples
2𝑝$ 2𝑝% 3𝑝# 3𝑝$ 3𝑝% Ar: 1 𝑠& 2𝑠& 2p+ 3s& 3p+
Ar:[𝑁𝑒] 3s& 3p+
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The n=3 energy level
Sulfur: 1 𝑠& 2𝑠& 2p+ 3s& 3p,
1 𝑠& 2𝑠& 2𝑝'& 2 𝑝(& 2𝑝-& 3𝑠& 3𝑝'& 3𝑝(% 3𝑝-%
1𝑠 2𝑠 2𝑝 3𝑠 3𝑝
↑↓↑↓↑↓ ↑↓ ↑↓ ↑↓↑↓ ↑ ↑
2𝑝# 2𝑝$ 2𝑝%
3𝑝# 3𝑝$ 3𝑝%
1s
2s 2p 3s 3p 4s 4p 5s 5p 6s 6p 7s 7p
3d
4d 4f 5d 5f
6d
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Question
Q. Write the electronic configuration of Sodium (Z=11).
3𝑠 ↑
1𝑠 2𝑠 2𝑝
↑↓ ↑↓ ↑↓ ↑↓ ↑↓
2𝑝# 2𝑝$ 2𝑝% Na: 1𝑠& 2𝑠& 2p+ 3s%
Na: 𝑁𝑒 3s%
1s
2s 2p 3s 3p 4s 4p 5s 5p 6s 6p 7s 7p
3d
4d 4f 5d 5f
6d
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Electronic configurations of ions
Ions are atoms which have lost or gained electrons. To write the configuration of an ion, we
add or remove enough electrons from the atom to make up the ion’s charge.
Eg.: Li+ has a charge of +1, so its configuration is equal to the configuration of lithium minus
1 electron.
» Li = 1s2, 2s1 (Remove outermost electron) » Li+= 1s2= [He]
A more complex example is O2-:
» O = [He], 2s2, 2px2, 2py1, 2pz1 (add 2 e-) » O2-= [He], 2s2, 2px2, 2py2, 2pz2 = [Ne]
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Quantum numbers
We can describe each electron individually through 4 quantum numbers.
Pauli Exclusion Principle: These are unique and cannot be shared.
Electrons within an atom are confined to a set of energy levels. The ‘address’ of an electron
within the atom is described using the following 4 quantum numbers:
n Principal Energy Level l Subshell
ml Orbital
ms Spin

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1. Principal energy levels (n)
Each Principal Energy Level (or electron shell) has a fixed maximum number of electrons.
The higher the energy level, the more electrons it can hold:
n = 1 n = 2 n = 3 etc...
Holds 2 electrons Holds 8 electrons Holds 18 electrons
n=3
n=2
n=1
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2. Energy subshells (l): secondary quantum number
Also known as Orbital, angular or azimuthal quantum number
Shells are subdivided into subshells. The number of subshells within each shell is the
principal energy level (n) of that shell:
n = 1 n = 2 n = 3 etc...
has 1 subshell (s)
has 2 subshells (s, p) has 3 subshells (s, p, d)
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3. Atomic orbitals (ml)
The subshells are divided into atomic orbitals. Each atomic orbital can hold 2 electrons. Each
electron in the pair must have opposite spin (spin can be ‘up’ or ‘down’).
s subshells have 1 orbital (2 electrons)
p subshells have 3 orbitals (6 electrons)
d subshells have 5 orbitals (10 electrons)
f subshells have 7 orbitals (14 electrons) etc....
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4. Spin quantum number (ms)
Each electron in a pair must have opposite spin (spin can be ‘up’ or ‘down’).
Clockwise rotation around the axis of the electron
ms = + 1 22
↑↓
Anti-clockwise rotation around the axis of the electron
This is represented by ↑
This is represented by ↓
ms = - 1
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n=4
n=1 (1st shell) 1 subshell = s
n=4 (4th shell)
4 subshells = s, p, d and f
Can hold 32 electrons n=2
n=1
n=3
n=2 (2nd shell)
2 subshells = s and p
Can hold 8 electrons → 2+6
n=3 (3rd shell)
3 subshells = s, p and d
Can hold 18 electrons → 2+6+10
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Source: Silderberg, Chapter 8 Electron Configuration and Chemical Periodicity
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The chemical bond
A chemical bond is a connection between a pair of atoms formed by an exchange of their
outermost electrons.
To generate a chemical bond, electrons in the outermost shell may be shared between two
atoms, or transferred from one atom to the other.
If the new arrangement of electrons is more stable than that of the isolated atoms, a
chemical bond is formed.
Chemical reactions:
loss, gain, or rearrangement of valence electrons (not core electrons)
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Ionic vs covalent bonding
An ionic bond is formed by the attraction of oppositely charged ions E.g. Na+ + Cl- →
NaCl
The bonding electrons are localised around the negative ion:
“electron density” i.e. where the electrons are
Na+ Cl-
A covalent bond is formed by sharing electrons between two uncharged atoms
e.g. H+H→ H2
The bonding electrons are shared between the two atoms:
H
H
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Electronegativity and bonding
Electronegativity = Ability of an atom to attract electrons.
When two atoms with a big difference in electronegativity come together; they form an
ionic bond.
When two atoms with a small difference in electronegativity come together, they form a
covalent bond.
H + H → H2
Na+ + Cl- → NaCl
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Ionic vs. covalent bonding
In reality, chemical bonds are very rarely completely ionic or completely covalent! Instead,
there is a spectrum of chemical bonding:
No difference in electronegativity
Covalent bonding
Polar covalent bonding
Big difference in electronegativity
Ionic bonding
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Drawing Lewis structures
A Lewis Structure is a diagram of an element showing its valence electrons (outer shell
electrons) drawn as dots.
H Hydrogen Lewis structure
We represent pairs of electrons in the same orbital as two dots, unpaired electrons are
drawn as isolated, unpaired dots.
Oxygen: 8 electrons
Valence electrons
↑↓ ↑↓ ↑↓ ↑ ↑
O:1𝑠22𝑠22𝑝2 2𝑝12𝑝1 𝑥𝑦𝑧
An unpaired electron
O
A pair of electrons
2 pairs of valence electrons
2 unpaired valence electrons
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Lewis structure – Ionic bonds
1. Lithium has 1 outer electron (wants to lose 1, valence = 1), while Bromine 7 outer
electrons (wants to gain 1, valence =1):
Li Br
The formation of Lithium Bromide can be drawn using Lewis Structures
(we draw a cross to highlight Lithium’s electron):
Lix + Br Li+ xBr-
2. Calcium has 2 valence electrons while chlorine has 7 valence
electrons; the formation of calcium chloride is therefore:
Cl + xCax + Cl
Cl -
Ca2+
-
xCl
x
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LiF
Na2O
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Lewis structures – covalent bonds
Hydrogen has 1 valence electron but needs 2 to fill its outer shell. By sharing their electrons,
two H atoms can fill their outer shells:
H+xH HxH
A pair of electrons between two atoms represents a bond. We can draw a line
instead to represent this bonding electron pair:
H+xH HH
Fluorine has 7 outer electrons. By sharing their electrons, two F atoms can both have 8
electrons in their outer shell to form F2:
FF
F
Fx F Fx xx xx
xx xx +xx xx
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Compounds
Compounds can also be divided into molecular and ionic.
» Molecular compounds have atoms bonded together into molecules
Oxygen Hydrogen
»Ionic compounds consist of ions (positively or negatively charged atoms in groups).
Na+ Cl-
O
xygen
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Ionic compounds-monatomic ions
An ionic compound consists of 2 or more electrically charged atoms (ions) in which the
overall charge is zero
Eg:

MgCl2→Mg2+ + 2Cl-
Monoatomic cations keep the name of the element. If more than 1 cation is possible include
the charge.
Na+ = sodium Cu1+ = copper (I)
Monoatomic anions change their ending to “-ide”.
F- = fluoride Cl- = chloride S- = sulphide
Cu2+ = copper (II) O2- = oxide
Ionic nomenclature: Cations first, anion next
CaS Calcium sulphide CuCl Copper (I) chloride CuCl2 Copper (II) chloride
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Polyatomic Ions
Ionic Compounds can also contain polyatomic ions
Ions which act as discrete units (with an overall charge)
Hydroxide Carbonate Bicarbonate Sulfate Sulfite
Nitrate
Nitrite
OH - CO3 2-
HCO3 2- SO4 2-
SO3 2-
NO3- NO2-
Most polyatomic ions are oxyanions (oxoanions)
Element, usually non-metal, is bonded to 1 or more oxygen atoms
Ion with more O atoms takes the nonmetal root and the suffix -ate. Ion with fewer O atoms
takes the nonmetal root and the suffix -ite.
KNO3 NaNO3 Na2CO3
Potassium Nitrate Sodium Nitrite Sodium Carbonate
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Covalent Compounds
Formed between atoms which differ by little (or not at all) in their tendancy to lose or gain
electrons (electronegativity)
Nucleus of 1 atom attracts valence electrons on another
The shared electron pair is localized between atoms.
Distinct molecules are formed.
Formula is a molecular formula(gives exact number or atoms in each molecule)
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Ionic Compounds
Formed between atoms with large difference in their tendancy to lose or gain electrons
(electronegativity)
Transfer of electron from metal atom to nonmetal
Each atom achieves Noble gas configuration
Interactions form a 3D ionic solid.
Formula is empirical formula (gives ratio of one to another)
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Covalent Bonding
 Each atom in covalent bond “counts” shared electrons as belonging entirely to itself-to
achieve full outer valence
An outer-level electron pair not involved in bonding is called a lone pair
Bonding pairs represented as lines and lone pairs represented as dots
H + xH HxH H H SingleBond
xxxxxx
Fx F Fx
F
F Fx SingleBond +x x x x xxx
xx
xx
Asinglebond(mostcommon)containsonebondingpairofelectrons.
Asinglebondhasa‘bondorder’of1
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Double and triple bonds
Multiplebondspossible(ofteninvolvingC,N,O) ↑↓ ↑↓ ↑↓ ↑ ↑
Z=8
O:1𝑠2 2𝑠2 2𝑝2 2𝑝1 2𝑝1 𝑥𝑦𝑧
xx
O +xOx O xx
xx xO
xx
OO xx
Z=7
4 electrons form 2 bonding pairs->double bond. ↑↓ ↑↓ ↑ ↑ ↑
N:1𝑠22𝑠22𝑝2 2𝑝12𝑝1 𝑥𝑦𝑧
6 electrons form 3 bonding pairs->triple bond
xx
x xx
N +xNx NxNx N Nx xxxxx
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Polyatomic structures
Methane is a polyatomic molecule with molecular formula CH4 C+xHxHxHxH
Total electron pairs available: 8 total valence electrons ÷ 2 = 4 pairs
Place the atom with the lowest ionisation energy in the middle and put other atoms
symmetrically around it. Use electron pairs to form chemical bonds. If octets aren’t full,
make multiple bonds.
Carbon has a share in 8electrons, Hydrogens have a share in 2 electrons
HH x
Hx C xH H C H
4 pairs of electrons
4 C-H single bonds
x
H
H
Any remaining pairs of electrons are placed on the central atom.
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Polyatomic structures - ammonia
Ammonia is a polyatomic molecule with molecular formula NH3 N+xHxHxH
Total electron pairs available: 8 electrons = 4 pairs
We place nitrogen in the centre, and use three electron pairs to make three N-H single
bonds. The unused electron pair is placed on nitrogen to fill up nitrogen’s octet (because we
can’t make multiple bonds).
Nitrogen has a
share in
8electrons, Hx N xH H N H Hydrogens x
4 pairs of electrons
3 C-H single bonds +
1 lone pair on nitrogen
have a share in 2 electrons
H
H
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1. Magnesium oxide
xx xOx xx
xx
Mg2+ xOx 2- xx
Mg
2. Silicon tetrachloride
Si + xCl xCl xCl xCl
Cl
x
Clx SixCl x
Cl Cl
Example
Cl Si Cl Cl
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Moles
Mole: amount of substance that contains as many units as there are atoms in 12 g of carbon
– 12. This number is called the Avogadro’s
23
number (𝑁 ) = 6.022 x 10 molecules or atoms
1 mol of O = 6.022 x 1023 atoms of oxygen
1 mol of H2O = 6.022 x 1023 molecules of water
The mass in grams of one mole of any substance is its molar mass.
𝑛𝑢𝑚𝑏𝑒𝑟 𝑜𝑓 𝑚𝑜𝑙𝑒𝑠(𝑚𝑜𝑙) = 𝑚𝑎𝑠𝑠 (𝑔) 𝑚𝑜𝑙𝑎𝑟 𝑚𝑎𝑠𝑠(𝑛)
No. of atoms/molecules/ions = No. of moles x Avogadro’s constant
𝑛𝑜𝑜𝑓𝑎𝑡𝑜𝑚𝑠=𝑛 × 𝑁 𝐴
𝐴
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Molar mass
Eg: Sodium carbonate Na2CO3
2 x Na + 1 x C + 3 x O
2 x 23 + 1 x 12 + 3 x 16 = 106 g/mol
Calculate the molar mass of ethanol (C2H5OH)
2 x C + 6 x H + 1 x O = 2 x 12 + 1 x 6 + 1 x 16 = 46 g/mol
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Examples
How many moles of Fe are in 5.6 g Fe? How many Fe atoms are contained in the sample?
1 mole of Fe = 56 g
5.6 g Fe = 0.1 mole of Fe.
The number of Fe atoms in the sample is
23 22
0.1 mole x 6.022 x 10 atoms/mole = 6.022 x 10 atoms.
5.6 g of iron is not much iron. However, even this small amount contains a huge number of
iron atoms.
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Drawing Lewis structures
A Lewis Structure is a diagram of an element showing its valence electrons (outer shell
electrons) drawn as dots.
H Hydrogen Lewis structure
We represent pairs of electrons in the same orbital as two dots, unpaired electrons are
drawn as isolated, unpaired dots.
Oxygen: 8 electrons
Valence electrons
↑↓ ↑↓ ↑↓ ↑ ↑
O:1𝑠22𝑠22𝑝2 2𝑝12𝑝1 𝑥𝑦𝑧
An unpaired electron
O
A pair of electrons
2 pairs of valence electrons
2 unpaired valence electrons
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Lewis structure – Ionic bonds
1. Lithium has 1 outer electron (wants to lose 1, valence = 1), while Bromine 7 outer
electrons (wants to gain 1, valence =1):
Li Br
The formation of Lithium Bromide can be drawn using Lewis Structures
(we draw a cross to highlight Lithium’s electron):
Lix + Br Li+ xBr-
2. Calcium has 2 valence electrons while chlorine has 7 valence
electrons; the formation of calcium chloride is therefore:
Cl + xCax + Cl
Cl -
Ca2+
-
xCl
x
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Lewis structures – covalent bonds
Hydrogen has 1 valence electron but needs 2 to fill its outer shell. By sharing their electrons,
two H atoms can fill their outer shells:
H+xH HxH
A pair of electrons between two atoms represents a bond. We can draw a line
instead to represent this bonding electron pair:
H+xH HH
Fluorine has 7 outer electrons. By sharing their electrons, two F atoms can both have 8
electrons in their outer shell to form F2:
FF
F
Fx F Fx xx xx
xx xx +xx xx
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Double and triple bonds
Multiplebondspossible(ofteninvolvingC,N,O) ↑↓ ↑↓ ↑↓ ↑ ↑
Z=8
O:1𝑠2 2𝑠2 2𝑝2 2𝑝1 2𝑝1 𝑥𝑦𝑧
xx
O +xOx O xx
xx xO
xx
OO xx
Z=7
4 electrons form 2 bonding pairs->double bond. ↑↓ ↑↓ ↑ ↑ ↑
N:1𝑠22𝑠22𝑝2 2𝑝12𝑝1 𝑥𝑦𝑧
6 electrons form 3 bonding pairs->triple bond
xx
x xx
N +xNx NxNx N Nx xxxxx
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1. Magnesium oxide
xx xOx xx
xx
Mg2+ xOx 2- xx
Mg
2. Silicon tetrachloride
Si + xCl xCl xCl xCl
Cl
x
Clx SixCl x
Cl Cl
Example
Cl Si Cl Cl
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Polyatomic structures
Methane is a polyatomic molecule with molecular formula CH4 C+xHxHxHxH
Total electron pairs available: 8 total valence electrons ÷ 2 = 4 pairs
Place the atom with the lowest ionisation energy in the middle and put other atoms
symmetrically around it. Use electron pairs to form chemical bonds. If octets aren’t full,
make multiple bonds.
Carbon has a share in 8electrons, Hydrogens have a share in 2 electrons
HH x
Hx C xH H C H
4 pairs of electrons
4 C-H single bonds
x
H
H
Any remaining pairs of electrons are placed on the central atom.
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Valence shell electron pair repulsion theory (VSEPR)
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What shapes are these really?
Molecules are 3 – dimensional
Lewis structures are flat 2D drawings but molecules are 3D.
VSEPR theory uses the electron pairs from Lewis Structures to predict the 3D shapes of
molecules.
A small molecule A large biomolecule DNA
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Why is shape important
Properties are highly dependent upon shape.
We’ll look at polarities caused by different geometries. There are
repercussions of this in almost every property. E.g.:
» Boiling / Melting Points (intermolecular forces)
» Interactions with other materials and substances
» Larger structure/material packing
» Biological receptors / enzymes very geometry specific
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VSEPR theory
VSEPR = Valence Shell Electron-Pair Repulsion
‘To minimize repulsions, each group of valence electrons around a central atom is located in
a way which maximises the distance between the electron pairs.’
H
HCH H
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Simple examples
Linear molecules (one central atom with two other atoms) such as CO2 have bond angle of
180° to maximise the distance between their bonding pairs:
O
C
O
Linear 180 ̊
Trigonal planar molecules (one central atom with three other atoms) such as BF3 have a
bond angle of 120° for the same reason:
F
B
Trigonal Planar 120 ̊
F
F
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Complex example
Phosphorous Pentachloride (PCl5) is one of many molecules that break the octet rule for the
central atom.
However, we can still determine the 3D shape of the molecule using VSEPR theory:
Cl
Cl P Cl
Cl
Trigonal bipyramidal 120 ̊ and 90 ̊ angles
Cl
Two tetrahedra stacked on top of each other....
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VSEPR and lone pairs
Lone pairs are treated like bonding pairs; they are also repelled by valence electron pairs.
However because they are closer to the central atom, lone pairs are slightly more repulsive.
This results in a small compression of the bond angles in structures with lone pairs (CH4 =
109°, NH3= 107.5°)
HNH H
107.5 ̊
The order of repulsion between different types of electron pairs is as follows: Lone pair –
lone pair > lone pair – bond pair > bond pair – bond pair
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Tetrahedral
Four electron pairs Electron-pair geometry = tetrahedral
Trigonal pyramidal
107.5 ̊
Ammonia, NH3 3 bond pairs
1 lone pair
Ammonia has 3 bond pairs and 1 lone pair, so it has a trigonal pyramidal molecular shape
Bent
Water, H2O 2 bond pairs
2 lone pairs
Water has 2 bond pairs and 2 lone pair, so it has a bent or angular molecular shape
Effect of lone pair on bond angles
104.5 ̊
109.5 ̊
Methane, CH4 4 bond pairs
No lone pairs
Methane has bond pairs, so it has a tetrahedral molecular shape
4
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VSEPR electron arrangements
Electron arrangement is the 3D arrangement of electron pairs around a central atom.
As we know, lone pairs and bonding pairs have a slightly different effect on the molecular
geometry.
We can catalogue the VSEPR predictions for all possible electron arrangements using the
following notation:
A Xm En
En = Number of lone pairs (n)
A = element of central atom
Xm = element of surrounding atoms (X) and number of atoms (m)
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VSEPR type Bonding Lone pairs (2e-) Geometry Examples pairs
AX2 2 0 Linear BeCl2, CaCl2
AX2E2 2 2 Bent H2O, H2S (non – linear)
AX3 3 0 Trigonal planar BCl3, BF3
AX3E 3 1 Trigonal NH3 pyramidal
AX4 4 0 Tetrahedral CH4
AX5 5 0 Trigonal PCl5 bipyramidal
AX6 6 0 Octahedral SF6
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H
HCH H
Methane
Bond in the plane of the paper
Dashed wedge – bond going backwards into the page
Solid wedge – bond coming forward from the page
Drawing in 3D
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H N HH
Trigonal Pyramidal
Drawing in 3D
PCl5
Trigonal bipyramid
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Polar bonds vs. Polar molecules
A polar covalent bond exists between two atoms of different electronegativities such as C-
Cl, C-F, C-Br, C-O, C-N, O-H, N-H, P-Cl, Si-Cl
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Polar bonds vs. Polar molecules
A polar covalent bond exists between two atoms of different electronegativities such as C-
Cl, C-F, C-Br, C-O, C-N, O-H, N-H, P-Cl, Si-Cl
The electrons in the bond are closer to the more electronegative atom, so this becomes δ-
(a little bit more negative) while the other end of the bond becomes δ+ ( a little bit more
positive)
+ - C Cl
A non-polar covalent bond exists between atoms of the same or close electronegativity such
as C-C, C-H, H-H, F-F, Br-Br, Cl-Cl, I-I, O-O
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Polar bonds and non-polar molecule
Carbon dioxide (CO2) is a linear molecule by VSEPR theory:
OC
O
Linear 180 ̊
Oxygen is more electronegative than carbon; thus each bond is polarised. However due to
the symmetry of the molecule, CO2 is not a polar molecule.
δ- δ+ δ- OCO
Both ends of CO2 have a partial negative charge, so it’s not polar
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Predicting the polarity of water
Oxygen in water (H2O) has to lone pairs, so the bond angle is further reduced to just 104.5°
OH H
104.5 ̊
Oxygen is more electronegative than hydrogen, so the bonding electrons are more
attracted to oxygen. A partial negative charge builds up around oxygen, and a partial
positive charge around hydrogen. As a result, water is a highly polar molecule.
δ- O
HH
δ+ δ+
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Things you need to understand from L1-4
Structure of the atom. Reading number of protons, calculating number of electrons
Understand order of periodic table and the trends
Calculating number of moles/molar mass/number of atoms.
Know 4 quantum numbers and write electronic configuration
Different types of bonding, why they happen, draw lewis structures.
VSEPR and Shapes of Molecules

Chemical reactions
Reactions convert one set of substances to another.
The initial substances are called reactants/reagents and the resulting
substances are called products.
Reactants Products
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Chemical reactions
Involve a rearrangement of the atoms in one or more substances.
Distinct from physical or nuclear changes
e.g. Combustion of methane (CH4), in oxygen (O2) to form carbon dioxide (CO2) and water
(H2O)
CH4 + O2 → CO2 + H2O
Reactants
Products
Bonds are broken
Bonds are formed.
All atoms present in reactants must be accounted for in products.
This involves balancing the chemical equation.
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Moles
Mole: amount of substance that contains as many units as there are atoms in 12 g of carbon
– 12. This number is called the Avogadro’s
23
number (𝑁 ) = 6.022 x 10 molecules or atoms
1 mol of O = 6.022 x 1023 atoms of oxygen
1 mol of H2O = 6.022 x 1023 molecules of water
The mass in grams of one mole of any substance is its molar mass.
𝑛𝑢𝑚𝑏𝑒𝑟 𝑜𝑓 𝑚𝑜𝑙𝑒𝑠(𝑚𝑜𝑙) = 𝑚𝑎𝑠𝑠 (𝑔) 𝑚𝑜𝑙𝑎𝑟 𝑚𝑎𝑠𝑠(𝑛)
No. of atoms/molecules/ions = No. of moles x Avogadro’s constant
𝑛𝑜𝑜𝑓𝑎𝑡𝑜𝑚𝑠=𝑛 × 𝑁 𝐴
𝐴
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Applying stoichiometry
2H2 +O2→2H2O
The number of moles of each species are contained within the chemical
equation (relative stoichiometry).
e.g: 1moletoO2 :2molesofH2O
Q. How many moles of H2O form from 0.25 moles O2? 1 mole of O2 2 moles of H2O
0.25 moles 0.5 moles of H2O
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Chemical reactions
Two laws of import for every reaction you see:
1. Mass Balance
2. Charge Balance
1. The law of conservation of mass:
2H2 +O2→2H2O
Mass is neither created nor destroyed in a chemical reaction, it is only converted from one
form to another.
Number of reactant atoms = Number of product atoms
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Chemical reactions
Two laws of import for every reaction you see:
1. Mass Balance
2. Charge Balance
2. The law of charge balance:
2H2 +O2→2H2O
If all reactants are neutral, the products will also be neutral overall.
Number of reactant charges = Number of product charges
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Chemical equations
Tell us what will be formed when reactants combine.
Mg + O2→MgO Does this satisfy the law of conservation of mass?
No. We have to balance the equation
Step 1:
Mg
1 Mg
Mg
1 Mg
2Mg
+
+
O2
2O
O2
2O
→ MgO 1 Mg
1O
→ 2MgO 2 Mg
2O
Count both sides
Add coefficients as needed
Count both sides
Add coefficients as needed
Step 2:
Step 3:
+
1 O2
→ 2MgO Count both sides Balanced!
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Balancing chemical equations
Na + H2O→NaOH+ H2
1 Na
2H
1O
1 Na
1O
1H
2H
1Na, 2H, 1O
Hydrogens are not balanced, so we need to balance them:
Na + 2H2O→2NaOH+ H2
2 Na 2 H 2O
2H
1Na, 4H, 2O
But, now sodium are not balanced, we need to balance them:
2Na + 2H2O → 2NaOH + H2
1 Na 4 H 2O
1Na, 3H, 1O
2Na, 4H, 2O
2Na, 4H, 2O
2Na, 4H, 2O
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Reaction components
Why is that important?
The states of reactants and products are important. They inform on whether a reaction is:
» Feasible
» Likely going to be fast or slow
▪ (two solids at RT? Probably not) ▪ (homogeneity vs. heterogeneity)
» Actually taking place
▪ (ionic dissociation)
» Being driven by a particular effect
▪ (precipitation, gas evolution)
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State symbols:
Reaction components
» (s) = solid
» (l) = liquid
» (g) = gaseous
» (aq) = aqueous solution
Dissolved in water
Is a change: physical or chemical or both? State symbols will show this
Dissolution
Homogeneous Water reaction splitting.
Expected in all balanced reaction equations.
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State symbols:
» (s) = solid
» (l) = liquid
» (g) = gaseous
» (aq) = aqueous solution
Most metal and non-metal
elements in their standard states.
Ionic compounds (e.g. NaCl, BaCl2, TiO2)
Water, alcohol, mercury
H2, O2, He, N2, N2O, CO, CO2, Noble gases, methane (CH4), ammonia (NH3)
Reaction components
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Reaction components
2Na + 2H2O → 2NaOH + H2 2Na(s) + 2H2O(l)→2NaOH(aq)+ H2(g)
HCl (aq) + NaOH (aq) → NaCl (aq) + H2O (aq)
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Various types of solutions
Example State of State of solute State of solution solvent
Air, natural gas Gas Gas Gas
Antifreeze Liquid Liquid Liquid
Brass Solid Solid Solid
Carbonated water
Liquid Gas Liquid
Seawater, sugar solution
Liquid Solid Liquid
Hydrogen in platinum
Solid Gas Solid
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Water: the common solvent
 Water is one of the most important substances on the earth.
A H2O molecule is bent or V-shaped with an H-O-H angle of 104.5 o
Water is a polar molecule.
This polarity gives water its ability to dissolve compounds.
OH H
104.5 ̊
δ- O
HH
δ+ δ+
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Hydration and Dissolution
δ+ parts of water molecules attracted to negatively charged anions
δ- part attracted to the positively charged cations.
Hydration of ions tends causes salt to dissolve.
Strong forces (between positive and negative ions in solid) replaced by strong water-ion
interactions.
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Solubility
Ability of a given substance (solute), to dissolve (in a solvent)
Measured in terms of the maximum amount of solute dissolved at equilibrium.
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1. Ionic substances
Solubility
Solubility of ionic substances in water varies.
NaCl is quite soluble in water, whereas AgCl very slightly soluble
Solubility in water depends on
– the relative attractions of the ions for each other
– attractions of the ions for water molecules(hydration)
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Solubility
Water also dissolves non-ionic substances e.g. ethanol (C2H5OH)
Ethanol contains a polar O-H bond like those in water.
In general, polar substances are only soluble in polar solutions.
2. Non – ionic substances
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Levels of solubility
Very soluble
Freely soluble Soluble
Sparingly soluble Slightly soluble Very slightly soluble Insoluble
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Concentration
Ratio of solute to solvent
Can be expressed in various units depending on the circumstances
Sometimes units of grams per dm3 (or grams per litre)
e.g. a solution containing 20 g of sodium chloride dissolved in 1 dm3 3 -3
of solution has a concentration of 20 g/dm (20 g dm )
We are more interested in the chemical amount of substance present rather than the
mass
So we again return to moles
This time as mol/L or Molarity (M).
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Molarity
Number of moles dissolved per Litre of solution.
The units are = mol/dm3 or mol/L. 𝑀𝑜𝑙𝑎𝑟𝑖𝑡𝑦= 𝑚𝑜𝑙𝑒𝑠𝑜𝑓𝑠𝑜𝑙𝑢𝑡𝑒
𝑙𝑖𝑡𝑟𝑒 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
𝑁𝑢𝑚𝑏𝑒𝑟 𝑜𝑓 𝑚𝑜𝑙𝑒𝑠(𝑛) = 𝑐𝑜𝑛𝑐𝑒𝑛𝑡𝑟𝑎𝑡𝑖𝑜𝑛 × 𝑣𝑜𝑙𝑢𝑚𝑒
mol Mol L-1 L
(1dm3 =1L)
n cV
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1. Percent composition
𝐴𝑚𝑜𝑢𝑛𝑡 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒 𝐴𝑚𝑜𝑢𝑛𝑡 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
Can be divided into:
a) Percentage composition by mass (w/w %)
b) Percentage composition by volume (v/v %)
c) Percentage composition by mass/volume (w/v %)
× 100
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a) Percent composition: w/w %
Let's consider a 12% by weight sodium chloride solution. Such a solution would have 12 g of
sodium chloride for every 100 g of solution. To make such a solution, you could weigh out
12 g of sodium chloride, and then add 88 g of water, so that the total mass for the solution
is 100 g.
𝐺𝑟𝑎𝑚𝑠 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒 𝐺𝑟𝑎𝑚𝑠 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
×100
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b) Percent composition: v/v %
Used whenever a solution is prepared by mixing pure liquid solutions
70% v/v rubbing alcohol may be prepared by taking 70 ml of isopropyl alcohol and adding
sufficient water to obtain 100 ml of solution.
Solutions made to a specific volume percent concentration typically are prepared using a
volumetric flask.
𝑉𝑜𝑙𝑢𝑚𝑒 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒 𝑉𝑜𝑙𝑢𝑚𝑒 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
×100
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c) Percent composition: w/v %
amount of solute in grams but amount of solution in millilitres.
Physiologic or isotonic saline is a 0.9% aqueous solution of NaCl.
0.9% saline = 0.9 g of NaCl diluted to 100 mL of deionized water, where NaCl is the solute
and deionized water is the solvent.
𝑊𝑒𝑖𝑔h𝑡 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑒 (𝑔) × 100 𝑉𝑜𝑙𝑢𝑚𝑒 𝑜𝑓 𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 (𝑚𝐿)
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Example:
A 4 g sugar cube (Sucrose: C12H22O11) is dissolved in a 350 ml teacup of 80 °C water. What
is the percent composition by mass of the sugar solution? Given: Density of water at 80 °C =
0.975 g/ml
Step 1 - Determine mass of solute
We were given the mass of the solute in the problem. The solute is the sugar cube.
masssolute = 4 g
Step 2 - Determine mass of solvent
mass = density x volume = 0.975 g/ml x 350 ml masssolvent = 341.25 g
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Example:
Step 3 - Determine the total mass of the solution
msolution = msolute + msolvent msolution = 4 g + 341.25 g
msolution = 345.25 g
Step 4 - Determine percent composition by mass of the sugar solution.
Percent composition = 𝑚𝑠𝑜𝑙𝑢𝑡𝑒 × 100% 𝑚𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛
= 4 ×100% 345.25
= 1.16%

Dilution
To save time and space in the lab, routinely used solutions are often purchased or prepared
in concentrated form called stock solutions. Water is then added to achieve the desired
molarity for a particular solution. This process is called dilution.

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Dilution
When calculating the dilution factors, it is important to remember the units of volume and
concentration remain constant.
𝑴𝟏𝑽𝟏 = 𝑴𝟐𝑽𝟐
𝑀𝑜𝑟𝑀 =𝑐𝑜𝑛𝑐𝑒𝑛𝑡𝑟𝑎𝑡𝑖𝑜𝑛𝑜𝑓𝑡h𝑒𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 12
𝑉𝑜𝑟𝑉 =𝑣𝑜𝑙𝑢𝑚𝑒𝑜𝑓𝑡h𝑒𝑠𝑜𝑙𝑢𝑡𝑖𝑜𝑛 12
For example, what volume of 16 M sulphuric acid must be used to prepare 1.5 L of a 0.1 M
sulphuric acid solution?
𝑀 =16𝑀 𝑉 =? 11
𝑀 =0.1𝑀 𝑉 =1.5𝐿 22
𝑀𝑉=𝑀𝑉 11 22
16Mx𝑉 =0.1Mx1.5L 1
-3
𝑉 =9.4x10 Lor9.4mL 1
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Serial dilutions
Serial dilutions involve diluting a stock or standard solution multiple times in a row.
Typically, the dilution factor remains constant for each dilution, resulting in an exponential
decrease in concentration. For example, a ten-fold serial dilution could result in the
following concentrations: 1 M, 0.1 M, 0.01 M, 0.001 M, and so on.
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Dilution of original culture
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The concept of Limiting Reagents
Let’s start with an example:
Limiting Reagent
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The concept of Limiting Reagents
When molecules react to form products, we also need to consider this N2 (g) + 3 H2 (g)→2
NH3 (g)
H2 N2
For the reaction to go to completion, we need to remember that each N2 requires 3 H2
molecules to form 2 NH3.
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Stoichiometric Mixtures
H2
N2 NH3
3:1

Relative amounts that match the numbers in the balanced equation: N2 (g) + 3 H2 (g)→2
NH3 (g)
This type of mixture is called a stoichiometric mixture All reactants will be consumed to
form products.
Before the reaction
After the reaction
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Limiting Reagents
N2 (g) + 3 H2 (g)→2 NH3 (g)
Remember that each N2 still requires 3 H2 molecules to form 2 moles of NH3
H2 N2
NH3
The H2 molecules are used up before all the N2 molecules are consumed.
Amount of hydrogen limits the amount of product NH3 that can form.
H2 is the limiting reagent.
Before the reaction After the reaction
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Determination of limiting reagent
1. Using reactant quantities
e.g 25 kg of N2 and 5 kg of H2 are mixed to form ammonia. Calculate the mass of ammonia
produced when the reaction is run to completion (until one of the reactants is completely
consumed)?
1. Get balanced equation
2N2H 1N3H
N2 (g) + H2 (g)→NH3 (g)
Count both sides
Add coefficients as needed
2 N, 2 H
N (g) + H (g)→2NH (g)
223
Count both sides
Add coefficients as needed
Count both sides Balanced!
1 N, 3 H
N2 (g) + 3H2 (g)→2NH3 (g)
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2. Calculate number of moles of each reactant
ForN2:No.ofmoles= 𝑚𝑎𝑠𝑠 𝑚𝑜𝑙𝑒𝑐𝑢𝑙𝑎𝑟 𝑤𝑒𝑖𝑔h𝑡
ForH2:No.ofmoles= 𝑚𝑎𝑠𝑠 𝑚𝑜𝑙𝑒𝑐𝑢𝑙𝑎𝑟 𝑤𝑒𝑖𝑔h𝑡
=25×1000𝑔 =893molN2 28 𝑔Τ𝑚𝑜𝑙
=5×1000𝑔 =2480molH2 2 𝑔Τ𝑚𝑜𝑙
3. Compare the mole ratio of the substances required in balanced equation with the mole
ratio of reactants actually present
Inthebalancedequationwehave:3𝑚𝑜𝑙𝐻2 =3 1𝑚𝑜𝑙𝑁2
Intheexperimentwehave:2480𝑚𝑜𝑙𝐻2 =2.78 893 𝑚𝑜𝑙 𝑁2
mole ratio of H2 to N2 is smaller than required-> H2 must be the limiting reagent
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4. To calculate the amount of product (ammonia) formed, we must use the amount of
hydrogen.
N2 (g) + 3H2 (g)→2NH3 (g)
From balanced equation:
3 moles of H2 give 2 moles of NH3
3 moles H2 = 2 moles NH3 (we actually have 2480 mol H2) 2480 moles H2 = X
=2480 ×2𝑚𝑜𝑙𝑁𝐻3 =1650molNH3 3𝑚𝑜𝑙𝐻2
Convert the moles to mass: Mass = moles x molecular weight
= 1650 mol x 17 g/mol = 28 kg NH3
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N2 + 3 H2 → 2 NH3
Moles from balanced eqn.
132
Mass 25 kg
5 kg
Calculated moles =
𝑚𝑎𝑠𝑠 𝑚𝑜𝑙𝑒𝑐𝑢𝑙𝑎𝑟 𝑤𝑒𝑖𝑔h𝑡
= 25 ×1000𝑔
28 𝑔Τ𝑚𝑜𝑙 = 893 mol N2
5 ×1000𝑔
2 𝑔Τ𝑚𝑜𝑙
= 2480 mol H2
Actual ratio
3 𝑚𝑜𝑙 𝐻2 = 3 1 𝑚𝑜𝑙 𝑁2
Calculated ratio
2480 𝑚𝑜𝑙 𝐻2 = 2.78 893 𝑚𝑜𝑙 𝑁2
Moles of ammonia
2480 ×2𝑚𝑜𝑙𝑁𝐻3
3 𝑚𝑜𝑙 𝐻2 = 1650 mol NH3
Mass of ammonia
1650 mol x 17 g/mol = 28 kg NH3
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Determination of limiting reagent
2. Using quantities of products formed
Determination of limiting reagent by calculating the amounts of products formed by
completely consuming each reactant. The reactant that produces the smallest amount of
product must run out first and thus will be the limiting reagent.
Consider previous example: 25kgofN2 and5kgofH2
1. Get balanced equation
N2 (g) + 3H2 (g)→2NH3 (g)
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2. Calculate number of moles of each reactant
ForN2:No.ofmoles= 𝑚𝑎𝑠𝑠 𝑚𝑜𝑙𝑒𝑐𝑢𝑙𝑎𝑟 𝑤𝑒𝑖𝑔h𝑡
ForH2:No.ofmoles= 𝑚𝑎𝑠𝑠 𝑚𝑜𝑙𝑒𝑐𝑢𝑙𝑎𝑟 𝑤𝑒𝑖𝑔h𝑡
=25×1000𝑔 =893molN2 28 𝑔Τ𝑚𝑜𝑙
=5×1000𝑔 =2480molH2 2 𝑔Τ𝑚𝑜𝑙
N2 (g) + 3H2 (g)→2NH3 (g)
3. Calculate moles of products formed by completely consuming each reactant.
1 mole of N2 gives 2 moles of NH3
1 mole H2 = 2 moles NH3 (we actually have 893 mol H2) 893 moles N2 = X
893molN2 ×2𝑚𝑜𝑙𝑁𝐻3 =1790molNH3 1 𝑚𝑜𝑙 𝑁2
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3 moles of H2 give 2 moles of NH3
3 moles H2 = 2 moles NH3 (we actually have 2480 mol H2) 2480 moles H2 = X
=2480mol𝐻2×2𝑚𝑜𝑙𝑁𝐻3 =1650molNH3 3𝑚𝑜𝑙𝐻2
If all the N2 reacted we would form 1790 mol of NH3
If all the H2 reacted we would form 1650 mol NH3 H2 must be limiting agent
Convert the moles to mass: Mass = moles x molecular weight
= 1650 mol x 17 g/mol = 28 kg NH3
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Example:
Nitrogen gas can be prepared by passing ammonia over solid copper (II) oxide at high
temperatures. The other products of the reaction are solid copper and water vapour. If a
sample containing 18.1 g of NH3 is reacted with 90.4 g of CuO, which is the limiting reagent?
How many grams of N2 will be formed?
Reaction (unbalanced):
NH3 (g)+CuO(s)→N2 (g)+Cu(s)+H2O(g)
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1. Get balanced equation
NH3 (g)+CuO(s)→N2 (g)+Cu(s)+H2O(g)
1N 1Cu 2N 1Cu 2H 3H1O1O
2NH3 (g) + CuO (s)→N2 (g) + Cu (s) + H2O (g) 2NH3 (g) + CuO (s)→N2 (g) + Cu (s) + 3H2O (g)
2NH3 (g) + 3CuO (s)→N2 (g) + 3Cu (s) + 3H2O (g)
Count both sides
Add coefficients as needed
Count both sides Balanced!
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2. Calculate number of moles of each reactant
For NH3: No. of moles = 𝑚𝑎𝑠𝑠 = 𝑚𝑜𝑙𝑒𝑐𝑢𝑙𝑎𝑟 𝑤𝑒𝑖𝑔h𝑡
For CuO: No. of moles = 𝑚𝑎𝑠𝑠 = 𝑚𝑜𝑙𝑒𝑐𝑢𝑙𝑎𝑟 𝑤𝑒𝑖𝑔h𝑡
18.1 𝑔 = 1.06 mol NH3 17 𝑔Τ𝑚𝑜𝑙
3. Calculate moles of products formed by completely consuming each reactant. (Second
method)
1.06molNH3× 1𝑚𝑜𝑙𝑁2 =0.530molN2 2 𝑚𝑜𝑙 𝑁𝐻3
1.14molCuO× 1𝑚𝑜𝑙𝑁2 =0.380molN2 3 𝑚𝑜𝑙 𝐶𝑢𝑂
Because a smaller amount of N2 is produced from CuO than from NH3, the limiting reagent
is CuO.
90.4 𝑔 79.55 𝑔Τ𝑚𝑜𝑙
= 1.14 mol CuO
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4.Calculate the mass of product formed.
Because CuO is the limiting reagent, we must used the amount of CuO to
calculate the amount of N2 formed.
Convert the moles to mass: Mass of N2 = moles x molecular weight
= 0.380 mol x 28 g/mol = 10.6 g N2
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Theoretical and Percentage Yields
The amount of a product formed when the limiting reagent is completely consumed is called
the theoretical yield.
In the above example, the amount of nitrogen formed (10.6 g) represents the theoretical
yield. This is the maximum amount of nitrogen that can be produced from the quantities of
reactants used.
The theoretical yield is seldom obtained (side reactions that involve one ore more of the
reactants or products)
The actual yield of product is often given as a percentage of the theoretical yield. This is
called as the percentage yield.
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Theoretical and Percentage Yields
𝑃𝑒𝑟𝑐𝑒𝑛𝑡𝑎𝑔𝑒 𝑦𝑖𝑒𝑙𝑑 = 𝐴𝑐𝑡𝑢𝑎𝑙 𝑦𝑖𝑒𝑙𝑑 × 100% 𝑇h𝑒𝑜𝑟𝑒𝑡𝑖𝑐𝑎𝑙 𝑦𝑖𝑒𝑙𝑑
In the above example, if the reaction considered actually gave 6.63 g of nitrogen instead of
predicted 10.6 g, the percentage yield will be:
6.63 × 100 = 62.5% 10.6
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Problem solving strategy
1. Write and balance the equation.
2. Convert the known masses of substances to moles. (don’t forget to do any unit
conversions if there is any).
3. Determine the limiting reagent.
4. Using the amount of limiting reagent and the appropriate mole ratios, compute the
number of moles of the desired product.
5. Convert from moles to grams, using the molar mass.
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Outline
Limiting reagents Theoretical and percentage yields Types of chemical reactions
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Reaction components
An electrolyte is a substance that dissolves to give a solution that contains ions.
The ions allow the solution to conduct electricity.
1. A strong electrolyte is a compound that dissolves to give a solution that contains mainly
ions.
NaCl→Na+(aq)+Cl- (aq)
An ionic solution that conducts electricity
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Electrolytes
 A weak electrolyte is a compound that dissolves to give a solution that contains mostly
molecules.
won’t conduct
CH3COOH (aq) → H+ + CH3COO- CH3COOH (aq) ⇌ H+ + CH3COO-
A non-electrolyte is a substance that dissolves to solution but doesn’t contain ions and
therefore, doesn’t conduct electricity.
E.g. Glucose (C6H12O6), Ethanol (C2H5OH)
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Types of chemical reactions
Types of solution reactions:
Precipitation reactions
Acid – base reactions
Oxidation – reduction reactions
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1. Precipitation reactions
A precipitation reaction usually occurs when solutions of 2 strong electrolytes are mixed.
NaCl (aq) + AgNO3 (aq)→ AgCl (s) + NaNO3 (aq) AgNO3 (aq)
NaCl (aq)
AgCl (s) + NaNO3 (aq)
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1. Precipitation reactions
Precipitation is the process in which a solute comes out of solution rapidly as a solid, called a
precipitate.
Precipitate
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2. Acid – base reactions
An acid is a species which donates a proton.
A base is a species which accepts a proton.
Neutralization is the reaction of an H+ (H3O+) ion from the acid and the OH- ion from the
base to form water, H2O.
HCl (aq) + NaOH (aq)→NaCl (aq) + H2O (aq)
acid base salt water

Redox in biology
Living cells utilise redox chemistry to generate energy. Respiration is the oxidation of sugar
to form CO2 and H2O:
C6H12O6(s)+6O2 (g)→6CO2(g)+6H2O(g)
Oxygen is a strong oxidising agent, meaning it can accept electrons easily.
Oxygen acts as a final acceptor of electrons in the electron transport chain, one method
mitochondria (the 'power plant' of cells) use to produce ATP (a biological form of energy).
 Biological systems usually transfer electrons as a chemical bond between a pair of atoms;
very often between a pair of H atoms.

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Vitamin B: NAD and FAD
NAD (Nicotinamide Adenine Dinucleotide) is derived from Niacin (Vitamin B3) while FAD (
Flavin Adenine Dinucleotide) is derived from Riboflavin (Vitamin B2), both of these co-
enzymes carry energy during respiration in the form of hydrogen:
FAD (oxidised) FADH2 (reduced) NAD (oxidised) NADH + H+ (reduced)
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NAD can be reversibly reduced. They act as coenzymes in many biological processes.
NAD+ gets reduced to NADH in glycolysis, among other processes.
NADH gets oxidised in anaerobic metabolism.
NAD
Vitamin B: NAD and FAD
NAD+ NADH
(Oxidized)
(Reduced)
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Redox reactions
Redox
Oxidation number Rules for Oxidation number
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Na: 11 electrons
Cl: 17 electrons
Chloride ion (Cl-) Chlorine gains 1 electron
Reduction reaction
Redox reactions

Sodium ion (Na+) Sodium loses 1 electron
Oxidation reaction

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Redox reactions
Redox reactions involve reduction or oxidation: Oxidation is the loss of electrons.
Reduction is the gain of electrons. OILRIG: Oxidation is loss, Reduction is gain.
e.g. 3Ag+ (aq) + Al (s) → 3Ag (s) + Al3+ (aq)
+ Eachsilvercationhasgained1electron→Ag isreduced
Each aluminium atom has lost 3 electrons →Al is oxidised
Oxidation Numbers: An arbitrary system to allow us to keep track of electrons; Electrons are
redistributed as elements react with each other.
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Example redox
Na (s) + Cl2 (g) → Na+Cl- (s) Charge
Na+ Cl2
Na1+ Cl20
Stoichiometry
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Oxidation numbers: Rules
1. Oxidation number (O.N.) of an ion equals the charge on that ion.
Mg2+ O.N. = +2 Cl- O.N. = -1 O2- O.N. = -2 Al3+ O.N. = +3
2. The O.N. of an uncharged (non-ionised) element is zero. Mg (s) O.N. = 0
O2 (g) O.N. = 0
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Oxidation numbers: Rules
3. An increase in O.N. indicates oxidation. O.N. = 0 O.N. = +2
Mg–2e- → Mg2+ (O.N. 4. A decrease in O.N. indicates reduction.
O.N. = 0 O.N. = -1
0→2)
Cl2 + 2e- → 2Cl- (O.N. 0 →-1) Special case:
In some reactions that produce multiple products you may see a species is both reduced
and oxidised: Disproportionation reaction
H2O2 (aq)→2 H2O (l) + O2 (g) O.N. = -1 O.N. = -2 O.N. = 0
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Oxidation numbers: Rules
5. O.N. of Hydrogen:
» -1 in compounds with metals
» +1 in compounds with non-metals
O.N. of Oxygen:
» Always -2
» except in peroxide, O22- where each oxygen atom has an O.N. of
-1.
O.N. of Fluorine: -1 in all its compounds
O.N. of other Halogens: -1, except if bound to oxygen or a halogen with larger atomic
weight.
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Oxidation numbers: Rules
6. The O.N. of a compound with several atoms is equal to the sum of the O.N. of all the
atoms within that species.
Eg 1. H2= H + H = 0 + 0 O.N. = 0 Eg2. NaCl=Na++Cl- =(+1)+(-1)=0 O.N.=0
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Examples
What is the Oxidation Number of Sulfur in: A) SO2 and B) SO42-?
A) SO2
Sum of oxidation numbers of S and 2(O) equals zero (rule 6) [O.N. of Sulfur] + [2 x (O.N. of
Oxygen)] = 0
x + 2(-2) =0 (rule5...O.N.ofOis-2) x =+4
So, the O.N. of Sulfur in SO2 is +4
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Examples
What is the Oxidation Number of Sulfur in: A) SO2 and B) SO42-?
B) SO42-
Sum of all oxidation numbers = -2 (rule 1 and 6) [O.N. of Sulfur] + [4 x (O.N. of Oxygen)] = -2
x + 4(-2) =-2 (rule5...O.N.ofOis-2) x =+6
So, the O.N. of Sulfur in SO2 is +6
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Examples
What is the O.N. of sulfur in hydrogen sulfide (H2S)? 2H+S = 0(rule1)
Hydrogen combined with non-metal has O.N. = +1 (rule 5) 2(+1) + x = 0
x = -2
So, the O.N. of Sulfur in H2S is -2
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More examples...
What is the O.N. of nitrogen in the nitrate ion (NO3-)? »N+3(O) =-1
»x +[3x(-2)]=-1
»x +(-6) =-1
» x=-1+6 =+5 O.N.ofN=+5
What is the O.N. of chlorine in HClO3? »H +Cl+3(O) =0
»+1+ x +[3x(-2)]=0
»1+x-6 =0
» x=6-1=5 O.N.ofCl=+5
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Oxidising and reducing agents
Oxidising Agent is a species which causes oxidation; it is reduced during a redox reaction.
Nomenclature: [O]
Reducing Agent is a species which causes reduction; it is oxidised during a redox reaction.
Nomenclature: [H]
Cr2O72- (aq) + Fe2+ (aq) + H+ (aq) → Fe3+ (aq) + Cr3+ (aq) + H2O(l)
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balance the equation before finding the oxidation numbers
Cr2O72- (aq) + 6Fe2+ (aq) + 14H+ (aq) → 6Fe3+ (aq) + 2Cr3+ (aq) + 7H2O(l) Cr2O72- (aq) +
6Fe2+ (aq) + 14H+ (aq) → 6Fe3+ (aq) + 2Cr3+ (aq) + 7H2O(l)
+6 -2 +2 +1 +3 +3 +1 -2
Working out the oxidation numbers (in red) for the above reaction we see that Cr is reduced
(gains e-) while Fe is oxidised (loses e-).
Therefore:
Cr2O72- (Dichromate) is the oxidising agent and is reduced in the reaction. Fe2+ (Iron (II)) is
the reducing agent and is oxidised in the reaction.
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Balancing in redox – charge balance
In a chemical reaction, electrons cannot be created nor destroyed, they are transferred from
one species to another.
Because electrons are charged, the total charge of reactants must equal the total charge of
the products.
You are given the unbalanced redox equation: Al(s)+H+ (aq)→Al3+(aq)+H2 (g)
1 Al 1 H 1 Al 2 H
Balance the number of atoms on either side of the equation:
Al(s)+2H+ (aq)→Al3+(aq)+H2 (g)
1 Al 2 H 1 Al 2 H
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Balancing in redox – charge balance
Balance charges on both sides of the equation: Al(s)+2H+ (aq)→Al3+(aq)+H2 (g)
0 +2 +3 0
The left side has charge +2, and the right side has charge +3. Lowest Common Multiple = 6
So we need a +6 charge on both sides to balance the equation. We can obtain this by
multiplying all H's by 3 and all Al's by 2. Fully balanced equation is:
2Al (s) + 6H+ (aq) → 2Al3+ (aq) + 3H2 (g)
0 +6 +6 0
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Balancing in redox II – charge balance
Sn (s) + Fe3+ (aq) → Sn2+ (aq) + Fe2+ (s)
0 +3 +2
+3 +4
Left species has charge +3 and Right species have charge +2 each Lowest Common Multiple
=6
So we need a 6+ charge on both sides of the equation.
We can obtain this by multiplying each Fe species by 2.
Sn (s) + 2Fe3+ (aq) → Sn2+ (aq) + 2Fe2+ (s)
The equation is now balanced with a charge of +6 on both sides.
+2
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Balancing in redox II – charge balance
Sn (s) + 2Fe3+ (aq)
0 2 x 3 = +6
+6
→
Sn2+ (aq)
+2
+ 2Fe2+ (s)
2 x 2 = +4
The equation is now balanced with a charge of +6 on both sides.
+6
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Summary
Oxidizing agent
Reducing agents
No of electrons
Gained
Lost
Oxidation state
Decreases
Increases
Substance
Reduced
Oxidized
Oxidizers gain electrons
They undergo reduction => they are reduced
Reducing agents lose electrons They undergo oxidation => are oxidized
Oxidation is the loss of electrons. Reduction is the gain of electrons.
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Half-reactions
Redox reactions can be split into reduction and oxidation half-reactions. Chemists use half-
reactions to make it easier to see the electron transfer, and it also helps when balancing
redox reactions.
Cu2+ + Mg→Cu + Mg2+
Split the ionic equation into 2 parts in terms of Cu and Mg:
Mg→Mg2+ + 2e- Cu2+ +2e- → Cu
Electron half- equations
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Half-reactions
Working out electron-half-equations and using them to build ionic equations
Chlorine gas oxidizes iron(II) ions to iron(III) ions. In the process, the chlorine is reduced to
chloride ions. From this information, the overall reaction can be obtained.
Step 1: chlorine gas is reduced to chloride ions Cl2 →Cl-
But it is not balanced: Cl2 →2 Cl-
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Half-reactions
Working out electron-half-equations and using them to build ionic equations
Step 2: To completely balance a half-equation, all charges and extra atoms must be equal on
the reactant and product sides. In order to accomplish this, the following can be added to
the equation:
electrons
 water
hydrogen ions (unless the reaction is being done under alkaline conditions, in which case,
hydroxide ions must be added and balanced with water)
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Half-reactions
Working out electron-half-equations and using them to build ionic equations
Thus the fully balanced half-reaction is:
Cl2 +2e-→2Cl-
Next, lets consider the iron half-reaction. Iron (II) is oxidised to iron (III):
Fe2+ → Fe3+
The atoms are balanced, but the charges are not.
Fe2+→Fe3+ + e-
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Half-reactions
Working out electron-half-equations and using them to build ionic equations
Step 3: combination of two half-equations This reaction has 2 electrons
Cl2 + 2e- → 2Cl- Fe2+→Fe3+ + e-
1 x ( Cl2 + 2e-→2Cl-)
2 x (Fe2+→Fe3+ + e-)
But this has only 1 electron
Cl2 + 2e- + 2 Fe2+→2Cl- + 2Fe3+ + 2e- Cl2 + 2 Fe2+→2Cl- + 2Fe3+

Recap about atoms
Atoms are composed of protons, neutrons and electrons)
"!X
Examples: !𝐻 #"He
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A = mass number
Z = atomic number (no of neutrons = A – Z) X = element symbol
Particle Symbol
Charge Mass (x 10-27 (x 10-19 Coul.) kg)
Proton p +1.60218 1.672623
Neutron n 0 1.674929
Electron e -1.60218 0.000911
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Isotopes
Atoms of an element that have different numbers of neutrons and therefore different mass
numbers.
Most elements occur in nature in a particular isotopic composition.
Example:
Ø All neutral carbon atoms (Z = 6) have 6 protons and 6 electrons,
Ø 98.89% of naturally occurring carbon atoms have 6 neutrons (A = 12) Ø A small
percentage (1.11%) have 7 neutrons (A = 13),
Ø Less than 0.01% have 8 (A = 14).
3 naturally occurring isotopes of carbon:
"#C , "$C , and "%C !!!
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Example: 1
An isotope of molybdenum has 54 neutrons. What is its atomic symbol?
Molybdenum has an atomic number of 42-> no of protons = 42
Mass number = number of protons + no of neutrons = 42 + 54 = 96
Thus the atomic symbol is $%Mo #"
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Example: 2
An element consists of 1.40% of an isotope with mass 203.973 u, 24.10% of an isotope with
mass 205.9745 u, 22.10% of an isotope with mass 206.9759 u and 52.40% of an isotope with
mass 207.9766 u. Calculate the average atomic mass and identify the element.
1.4×203.973 + 24.1×205.9745 + 22.10×206.9759 +(52.4×207.9766) 100
= 207.2
Therefore, the element is Pb.
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Chemical versus Nuclear Reactions
Chemical Reactions
1. One substance converted to another, 1. atoms don’t change identity.
2. Orbital electrons involved, bonds 2. break and form; nucleus is not involved
Nuclear Reactions
Atoms of one element typically change into atoms of another
Protons, neutrons and other particles are involved; orbital electrons rarely take part.
Reactions accompanied by large changes in energy and measurable changes in mass.
Rates affected by number of nuclei, not by temperature or catalysts.
3. Relatively small changes in energy
4. Reaction rates influenced temperature, concentration, catalysts.
3.
4.
by
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Radioactive decay
Unstable nucleus emits radiation, forming another nucleus (and producing one or more
particles)
)*𝐶à)*𝑁+ -𝑒 ( + ,)
A and Z must be conserved. Z values must give the same sum on the both sides of the
equation (6 = 7 -1 ), as must the A values (14 = 14 + 0).
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1. Alpha decay emission – heavy elements
Helium nucleus ejected, leaving daughter nucleus
Ø Note difference in A and Z
Ø Note A and Z balanced on both sides
Eg. α-decay of uranium-238
#$5𝑈 → #$%𝑇h + %𝐻𝑒 4# 46 #
238Uà234Th + %#𝛼 𝑡"/# = 4.48×104 𝑦𝑒𝑎𝑟𝑠
210Po à 206Pb + %#𝛼 𝑡"/# = 138 𝑑𝑎𝑦𝑠 Unstable nuclides beyond bismuth (Z = 83).
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(which is ejected)
90Sr􏰍90Y + 􏰍􏰍 + Energy 14C􏰍14N + 􏰍􏰍 + Energy
􏰍􏰍􏰍􏰍 􏰍 􏰍􏰍 􏰍􏰍􏰍􏰍􏰍 􏰍􏰍􏰍􏰍 􏰍 􏰍􏰍􏰍􏰍 􏰍􏰍􏰍􏰍􏰍
􏰍􏰍􏰍􏰍 􏰍 􏰍 􏰍􏰍􏰍􏰍
neutrino).
Common for proton deficient nuclides, high n/p ratio
Ø ( β–particle or 86"𝑒 )
131I 􏰍 131Xe + 􏰍􏰍 + Energy
2. Beta decay
􏰍􏰍􏰍 􏰍 􏰍􏰍􏰍 􏰍 􏰍􏰍􏰍􏰍 􏰍 􏰍􏰍
Neutron converted to proton (which remains), and β–particle
ØNote Z chTarininty Cgolleege Dsub,linA, The Udnivoersiety osf Dnubli’nt (remember mass
of electron)
"%𝐶 → "%𝑁 + 6𝑒 ! 9 8"
90Sr à 90Y + β8 + Energy
14C à 14N + β8 + Energy
𝑡"/# = 30 𝑦𝑒𝑎𝑟𝑠
𝑡"/# = 5730 𝑦𝑒𝑎𝑟𝑠 𝑡"/# = 8 𝑑𝑎𝑦𝑠
131I à 131Xe + β8 + Energy
Common for proton deficient nuclides, high n/p ratio
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electromagnetic radiation, as gamma (􏰍)-ray
3. 𝛾 – emission 􏰍􏰍􏰍􏰍􏰍 􏰍 􏰍􏰍􏰍􏰍 􏰍 􏰍
Nucleons reorganise into more stable arrangement.
Normally happens along with other radiation events
High energy photons released. Trinity College Dublin, The University of Dublin
Ø-𝛾 or γ
Note, no change in atomic number or mass
44:𝑇𝑐 → 44𝑇𝑐 + 𝛾 %$ %$
􏰍􏰍 􏰍􏰍
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Most common forms of emission-Recap
α
β
γ
Charge
+2
-1
0
 Mass
6.64 x 10-24
9.11 x 10-28
-
Penetrating Power (relative)
1
100
10000
Nature of Radiation
"!𝐻𝑒 Nuclei
Electrons
High Energy Photons
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4. Positron Emission
Unstable nuclides which are neutron deficient.
Proton converted to a neutron plus a high energy positron (β= or e=), increasing the n/p
ratio.
" " 𝑝 → "6 𝑛 + 6" 𝛽
Process leaves A unchanged, Z decreases by 1.
7Beà7Li + β= + Energy 𝑡"/# = 53 𝑑𝑎𝑦𝑠 144Gd à 144Eu + β= + Energy 𝑡"/# = 4.5 𝑚𝑖𝑛
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5. Electron capture
Nucleus captures electron from electron cloud " " 𝑝 + 8 6" 𝛽 → "6 𝑛
A is unchanged, Z decreases by 1, as in β+ emission. 51Cr+𝑒8à51V+Energy 𝑡"/# =28𝑑𝑎𝑦𝑠
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β em
ission
Positron emission or electron capture
α emission
NZ = 1
Stable
Radioactive
à## $%&'()* 23 Nuclear Chemistry But why?
unstable isotopes. A graph of the
number of neutrons (N) versus the
number of protons (Z) for stable
(black circles) and radioactive (red All elements beyond bismuth (Z = 83) are unstable.
Need to decrease atomic number-> alpha emission
FIGURE !"." Stable and
140
circles) isotopes from hydrogen to 110
bismuth. This graph is used to assess
100
90
80
70
60
50
40
30
20
10
00 10 20 30 40 50 60 70 80 90 100
criteria for nuclear stability and to
predict modes of decay for unstable nuclei.
130
120
Isotopes above band of stability have high neutron-proton ratio Need to lower neutron-to-
proton ratio -> beta emission
Isotopes below band of stability have a low neutron-to-proton ratio Need to lower atomic
number (move closer to band of stability)
Decay by positron emission or by electron capture
Number of protons (Z)
All elements beyond bismuth (Z = 83) are unstable. To rea stability starting with these
elements, a process that decreases t ber is needed. Alpha emission is an effective way to
lower Z, the because each emission decreases the atomic number by 2. For cium, the
radioactive element used in smoke detectors, decay
243Am → 4α + 239Np 95 2 93
Beta emission occurs for isotopes that have a high neutron-to that is, isotopes above the
band of stability. With β decay, the increases by 1, and the mass number remains constant,
resu
Co→− β+28Ni
Number of neutrons (N)
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neutron-to-proton ratio:
60 0 60

Nuclear stability
Modes of Radioactive Decay
 Modes Isotopes Symbol
Alpha decay Heavy isotopes 𝛼 or #"𝐻𝑒"&
Beta decay Neutron rich isotopes β' or 𝑒'
Gamma-ray emission Decay of nuclear excited 𝛾 states
Positron emission Proton rich isotopes β&
Electron capture Proton rich isotopes X-rays
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Radioactive half-life (𝑡!/#)
Time taken for activity to reach half of its initial value
𝑡)/3 = 45 3 𝑁 = 7 = 78!/# 6 69:3
k = reaction rate constant N= number of nuclides A=activity
Can relate activity to number of nuclides in sample if t1/2 or k is known.
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Effects of radioactive emissions
Nuclear changes cause chemical changes in matter.
Virtually all radioactivity causes ionization
Number of cation-electron pairs related energy of radiation
Resulting charged species go on to form free radicals, molecular or atomic species (with
unpaired electrons).
Effect on living tissue depends on the penetrating power and ionizing ability of the
radiation.
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Units of Radiation Dose (in SI units)
Gray (Gy)= 1 joule of energy absorbed per kg ⟹ 1 Gy = 1 J/kg Common unit is the rad
(radiation absorbed dose)
1rad=0.01Gy
Tissue damage depends on:
1. radiation strength
2. exposure time
3. tissue type
1Gy=1 ( =1 +! )* ,!
multiply rads by Relative Biological Effectiveness (RBE) to get radiation dose in roentgen
equivalents for man (rem)
No. of rems = no. of rads x RBE. (SI unit: 1 Sievert (Sv) = 100 rem)
Give us measures of effect of low level ionising radiation on the human body
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s
of radiation

The S-shaped response model implies there is a threshold above which the effects are more
significant: very low risk at low dose and high risk at high dose.
Table 24.8
Acute Effects of a Single Dose of Whole-Body Irradiation
Dose
(rem) Effect
5–20 Possible late effect; possible chromosomal aberrations
20–100 Temporary reduction in white blood cells
Lethal Dose
501
Temporary sterility in men (1001 rem 5 1-yr duration)
Population (%)
————
— 50–70
60–95 100
No. of Days
————
— 30
30 2
100–200 “Mild radiation sickness”: vomiting, diarrhea, tiredness in a
few hours
Reduction in infection resistance Possible bone growth retardation in
children
Permanent sterility in women
3001
500 “Serious radiation sickness”:
marrow/intestine destruction 400–1000 Acute illness, early deaths
30001
Acute illness, death in hours to days
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Radiotracers
Isotopes exhibit similar chemical and physical behaviour.
Certain compounds localize in specific tissues in the body.
Map 𝛾 emission from organ of interest e.g. thyroid
##$𝑇𝑐 →##𝑇𝑐+𝛾. I-&TcO-actalike !"!" 4
Relatively safe, no biological function, rapidly excreted
Short half-life (6 h), decays to fairly stable nuclei
Production of 99mTc pharmaceuticals is very important industry
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1080

PET
Can be used to track a substance in the body – Positron Emission Tomography (brain
structure and function)
Substance synthesized with isotope that emits positrons. Injected into patient as part of
biologically active molecule
Positron emitted
Patient placed in instrument that measures positron emission.
Computer reconstruction of organ
Chapter 24 Nuclear Reactions and Their Applications
Normal Brain Activity Alzheimer's Disease
Figure 24.14 PET and brain activity. These PET scans show brain activity in a normal person
(left )
Can be used to measure blood flow, blood volume, oxygen usage, tissue pH (acidity),
and in a patient with Alzheimer’s disease (right ). Red and yellow indicate relatively high
activity within
glucose (sugar) metabolism, and drug activity.
a region.
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Additional Applications of Ionizing Radiation

Radiation Therapy
Cells can be damaged by high energy radiation (Cancer cells more susceptible than health
cells)
Can be used for treatment cancer inside/outside the body
Almost all cases use γ radiation (strongly penetrating)
Difficult to avoid healthy cell damage with γ radiation
Implants of 198Au or of 90Sr (which decay to a γ emitter) used to destroy pituitary and
breast tumour cells,
γ rays from 60Co used to destroy brain tumors Effective in slowing cancer or even
prompting the regression
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Summary
Nuclear decay via three main types of radiation.
Half lives and/or decay constants can be calculated.
Radiation damages tissue by formation of free radicals.
α emitters such as 99mTc very good for imaging.
β- emitters such as 90Y useful for cancer therapy.
β+ emitters finding more uses in imaging (PET).