Molecule Concept and Chemical Bonds PDF

Summary

This document provides a presentation on molecule concept and chemical bonds including organic, inorganic chemistry, physical chemistry, biochemistry. It details the basic concepts of chemistry, the history of chemistry and how chemistry is related to human life and the building blocks of matter. It covers structure of matter, states of matter, and energy involvement in phase changes.

Full Transcript

MOLECULE CONCEPT and
CHEMICAL BONDS
Dr. Göksemin Fatma ŞENGÜL
What is Chemistry?

Chemistry is the area of science that
focuses on the properties, composition and
structure of elements and compounds.

Chemistry also studies the transformations
and changes of these substances that they
undergo. Chemistry also investigates the
large-scale production methods.

2
What is Chemistry?
There are five main branches of chemistry:

ORGANIC CHEMISTRY: Study of structure,
properties, composition, reactions and
preparation of carbon-containing compounds.

INORGANIC CHEMISTRY: Study of remaining
(non-carbon containing) subset of compounds.

ANALYTICAL CHEMISTRY: Study of obtaining,
processing and communicating information about
the composition and structure of matter. 3
What is Chemistry?
There are five main branches of chemistry:

PHYSICOCHEMISTRY: Study of macroscopic, atomic,
subatomic and particulate phenomena in chemical systems
in terms of the principle, practices and concepts of physics
such as motion, energy, force, time, thermodynamic, quantum
chemistry, statistical mechanics, chemical equilibrium and analytical
dynamics. Physical chemistry also focuses on states of matter.

BIOCHEMISTRY: Study of chemical reactions that take place in
the living organisms, in turn, their functions, effects and ways to
control them.
Sub-disciplines related to these branches of chemistry: polymer chemistry, environmental chemistry,
4
petroleum chemistry, corrosion chemistry, thermochemistry, electrochemistry and others.
The History of Chemistry:
French chemist Lavoisier who lived in 18th
century, is considered as the founder of the
modern chemistry.
Lavoisier discovered that air consists of various
gases, explained the combustion phenomenon and
simplified the language used in chemistry.
Lavoisier found names and symbols for 33
elements and arranged them into four groups
including gases, metals, nonmetals and earths. 6
Chemistry and Human being
Chemistry mainly is interested in the building
blocks of matter. Thus, chemistry contains
direct relationship with all branches of science.

The chemical composition of man, the most advanced
and complicated being on earth: Phosphorus 700 g,
Hydrogen 7000 g, Nitrogen 2100 g, Sulfur 175 g,
Oxygen 45500 g, Chlorine 105 g, Carbon 12060 g,
Magnesium 35 g, Iron 2,8 g, Potassium 245 g,
Calcium 1050 g. 7
Structure of Matter
Matter:
Granular structure

Hallow (void) structure

Mobile structure

8
Structure of Matter
If the matter is made up of particles,
why we cannot see the particles?

The presence of 2x1021 water
molecules (H2O) in one drop of water
explains why the particles that make up
water cannot be seen with the naked
eye.

9
Structure of Matter

Particles of matter:
– Atoms
– Molecules
– Ions

10
Structure of Matter
An iron rod, mercury in a bottle, a copper
vessel, an aluminum frame are examples
of substances whose particles are atoms.

Water (H2O), alcohol (C2H5OH), acetone
(C3H6O), tea sugar (sucrose, C12H22O11)
and oxygen (O2) particles in a tube are
examples of molecules.

11
Structure of Matter
Examples of substances whose particles are ions:

Sodium chloride (table salt) NaCl Na+, Cl-

Calcium carbonate (limestone) CaCO3 Ca2+, CO32-

Sodium carbonate (washing soda) Na2CO3 , 2Na+,
CO32-

12
Structure of Matter
Hollow (void) structure of matter:

When 50 mL of water is mixed with 50 mL
of alcohol, the total volume of solution is
always less than 100 mL (approximately 90-
95 mL). How can this situation be explained?

The same situation can be also observed for
granular materials such as chickpea-rice
mixture etc.
13
Structure of Matter
Mobility of particles

The mobility of particles can be easily
detected especially when the gas state of
substance is considered.

If the gaseous particles of substances were
not mobile, could it be possible to understand
at the entrance of the apartment which food
was cooked in the house?
14
 States of Matter
State of matter is the form of matter
that can exist in the life.

States of matter:
– Solid (s)

– Liquid (l)

– Gas

– Plasma

15
States of Matter
Plasma state of matter: Plasmas are
mixture of ions, electrons and neutral
atoms moving randomly where collisions
at the atomic and molecular levels play
a crucial role. The ions and electrons
interact through long-range Coulomb
forces, whereas neutral atoms and
molecules interact by means of short-
range collisions.
Plasma state of matter is typically an
electrically neutral medium of unbound
positive and negative particles so that
overall charge of plasma is roughly zero.
16
States of Matter
Plasma state of matter:

A plasma state of matter is observed at
very high temperature and pressure.

The flame of match and luminescent
substance in a burning fluorescent lamp can
be given as an example of the plasma state
of the matter.

17
 States of Matter

Three states of water molecule
H2O(s) H2O(l) H2O(g)

18
 Energy Involvement in Phase Changes
Energy
Gas release
(exothermic)

Vaporization Condensation

Liquid

Melting Freezing
(Fusion)

Energy Solid
requirement
(endothermic) 19
Matter
Matter
Matter is anything that has mass and occupies space.

Mass
Mass is a measure of the amount of matter in a substance.

Weight
Weightis the force of gravity on an object and can be calculated as
the mass times acceleration of the gravity, w = mg.

20
CLASSIFICATION OF MATTER

21
Matter
All matters are composed of elements.

Elements are made up of single atoms and
the basic building blocks of matter.

There are approximately 111 elements in
nature.

Human body is mainly comprised of six
elements mostly carbon (C), hydrogen (H),
oxygen (O) and nitrogen (N), but also
sulfur (S) and selenium (Se) elements. 22
Chapter 2
23
Pure Substance (Matter)
Element
– Elements cannot be broken down into
simpler substances by chemical reactions.
Elements are made up of a single kind
atoms to form matter.
– For example: Hydrogen (H) and oxygen (O)

Compound
– Compound is a substance formed by the
combination of two or more elements in a
chemically fixed proportion.
– For example: Water - H2O
24
Mixtures

25
PRECISION and ACCURACY IN
MEASUREMENTS

27
SI UNITS FOR MEASUREMENTS
Base quantity Unit Abbreviation

Mass kilogram kg

Length meter m

Time second s

Temperature kelvin K

Electric current ampere A

Amount of substance mole mole

Luminous intensity candela cd
28
Physical quantity SI unit
Area m2

Volume m3

Density kg/m3

Velocity m/s

Acceleration m/s2

Power kg * m/s2 ( = newton, N)

Pressure kg/(ms2) ( = pascal, Pa)

Energy kg * m2/s2 ( = joule, J)
29
Prefix Abbreviation Number Meaning Exponential
Multiplier

tera T 1,000,000,000,000 trillion 1012
giga G 1,000,000,000 billion 109
mega M 1,000,000 million 106
kilo k 1,000 thousand 103
hecto h 100 hundred 102
deka da 10 ten 101
----- ---- 1 one 100
deci d 0.1 one in ten 10-1
centi c 0.01 one in hundred 10-2
milli m 0.001 one in thousand 10-3
micro   one in a million 10-6
nano n 0.000000001 one in a billion 10-9
pico p 0.000000000001 one in a trillion 10-12
femto f 0.000000000000001 one in a quadrillion 10-15 30
TEMPERATURE UNITS

Temperature unit
conversions

31
Basic structure of matter:
Atom
 History of Atom
Democritus (460-370 BC)
Original description of atomic concept
Dalton (1766 - 1844)
1803 Dalton’s Atomic Theory
Crookes (1837-1919)
1879 Discovery of negative charge on
cathode rays
J.J. Thomson (1856-1940)
1897 Discovery of electrons
Millikan (1868-1953)
1909 Discovery of elementary charge in an electron
Rutherford (1871-1937)
1911 Discovery of tiny, dense and positively charged nucleus
33
ATOMS and MOLECULES
Living organisms and non-living things in the universe are
composed of elementary particles called as atoms.

The differences of all these beings are derived from the
diversity of atoms that they consist of and the combination of
these atoms with different bonds.

The number of smaller particles, protons (is considered atomic
number) differentiates one from the another.

34
Atomic Structure
Atom is the smallest unit of an element
that show all of its chemical properties.
Atoms consist of smaller particles which
are electrons, protons and neutrons:

Particle Symbol Charge
electron e- -1

proton p +1

neutron n 0
35
Structure of Atom
Atom is a complex
arrangement of;
small, dense and positively
charged nucleus. Protons and
neutrons are located in the
positively charged nucleus.
small negatively charged
subatomic particles, electrons
are scattered around the
nucleus. 36
 Substructures of Atom

College Physics. Authored by: OpenStax College. Located at: http://cnx.org/contents/031da8d3-b525-429c-80cf-
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37
Structure of Atom
The nucleus is the small densely packed
center of the atom, containing protons and
neutrons.
The nucleus of the atom would be a pea in the
center of the football stadium and the electrons
would be whizzing around the outer stands.

The mass of the nucleus of an atom
is greater than 30 million tons.
38
RELATIVE ATOMIC SIZE OF THE MAIN
GROUP ELEMENTS
The radii given in picometer

39
 Basic Model of an Atom and
Atomic Theory
Basic model of atom is sometimes also called
as Bohr’s atomic model. According to Bohr
model;
Electrons encircle the nucleus of the atom in
specific allowable paths, known as orbit.

When the electron is in one of these orbits,
its energy is fixed.

Energy of an orbital can be determined solely
by principal quantum number.
40
 Bohr Model of the Atom
Small, dense and spherical center of an atom and contains the
Nucleus proton and neutrons.

Proton Positively electrical charge of one (1+) with a mass of one
atomic mass unit (amu), corresponding to about 1.67x 10-27
kg.

Neutron No charge (neutral, uncharged) with a mass of one amu.

Electron Negatively electrical charge of one (1-) with a mass of 9.1 x
10-31 kg, which only 1/1.836 the mass of a proton.
Shell Electrons in an atom are arranged in shells (orbits) that
surround the nucleus.
41
Bohr Model of the Atom

e-
e- e-
e-
Protons
positive
e- e-
Neutrons
neutral

e-
e-
e- e-

42
 Bohr Model of the Atom
Atomic number is the number of proton in an atom.

Each element has a different atomic number.
– In another word, each element has a different number of protons.

1 atomic mass unit (AMU) = proton + neutron
– 1 AMU = defined as one twelfth (1/12) the mass of an unbound
neutral atom of carbon.

– 1 AMU = 1,67x10-24 gram.

Atoms that contain the same number of protons, but
different number of neutrons are called as isotopes.
The numbers of protons and neutrons are summed up to
name the isotopes of elements. 43
Atomic Properties
atomic number = proton number
atomic mass, mass number of an atom =
total numbers of protons and neutrons
The results of atomic reactions:
An atom can gain, lose or share their
electrons.
Two or more atoms come together to form
molecules or compounds.
All reactions occur through intermolecular or
intramolecular interactions at the atomic
level.
44
 Atomic Symbol
A C

Z X #
A (Atomic mass) : proton + neutron
Z (Atomic number): proton number

C (charge) : + or - values
# The number of atoms in the formula of molecule
45
 Atomic Symbol
The atomic symbol representation provides
information about the proton, neutron and
electron numbers of an atom.

31 138 238
15 P 56 Ba 92 U

46
 Isotopes
An atom contains the same number of protons, but different
numbers of neutrons thereby having different mass numbers,
AMU. For example,

The atomic number of C is 6.

Carbon contains 6 proton.

The atomic mass of C is either 12 or 14.
– C12 = 6 proton + 6 neutron

– C14 = 6 proton + 8 neutron

– C12 and C14 are isotopes of carbon atom. 47
 Isotopes
Isotopes: Isotopes are the atoms of the
same element with different atomic mass.
Isotopes contain the same number of
protons, but different numbers of neutrons.
Isotopes of hydrogen 1 2 3
H H H
1 1 1

Isotopes of carbon 12 13 14
C C C
6 6 6

48
 Isotopes
Most elements are naturally found in a
mixture of its several isotopes on earth.

– Element Number of stable
isotopes
H 2
C 2
O 3
Fe 4

49
 Shells (Orbits)
Electrons are found in orbits (shells) around the nucleus.

The first shell contains 0e-, 1e- or 2e-, while

The second shell contains 0e-, 1e-, 2e-, 3e-, 4e-, 5e-, 6e-, 7e-, or 8e-.

Afterwards, 3rd and 4th shells are filled up with electrons.

An atom can have maximum of 7 shells.

The energy level of an electron shell increases as distance from the nucleus
increases, there is a decreased interaction of electron(s) with the nucleus.

The max number of electrons in an energy level can be calculated by 2n2
formula.
50
 Cloud or Orbital Model

According to orbital model, electrons in
orbits move in a volume.

The density of electrons increases as
getting close to the nucleus. The electron
shells from nucleus to outer shells are
ordered as s, p, d and f orbitals.

51
 Neutral Atoms
Neutral atom has equal magnitude of
negative and positive charges which
cancel each other and makes a neutral
atom uncharged.
An atom with atomic number 6 contains 6
proton.
The electron number of this neutral atom
is also 6.

52
Electron Configuration
The electrons in atoms
are arranged in shells
that surround the
nucleus.

Each shell contains a
fixed number of
electrons due to the size
limitation of it.

The number of electrons
increases as the number
of outer shell increases.
53
Electron Configuration

Atoms contain nucleus
at the center.

Nucleus is a tiny,
dense, central core of
atom which is
composed of protons
and neutrons.

54
Core and valence electrons
Valence electrons
Valence electrons are outer
shell electrons of
an atom and participate the
formation chemical bonds.
Core electrons
Core electrons are the
electrons other than valence
electrons of the atom and
they are tightly bound to the
nucleus. They play a role in
determination of the
chemical reactivity. 55
Energy levels in atoms
Each principal energy level can contain up to
2 n2 electrons when n is the number of the
level.

– The max number of (e-) = 2 n2

Shell Maximum numbers of
(n) (e-)
1 2
2 8
3 18
4 32

56
Octet Rule
Atoms gain or lose electrons to acquire 8
electrons in their outermost energy level
so that they become more stable. H and
He do not follow the octet rule.
When atoms;
Lose or gain e- forming (ionic compounds)
Share e- forming (covalent compounds)

57
Chemical Compound Formula
Chemical formula of a compound is a symbolic
representation of its chemical
representation.
Chemical formula shows the list of element
in the compound.
Chemical formula shows how many elements
are there in the given compound or molecule.
H2O - water CH3CH2OH – ethyl alcohol
2 hydrogen 2 carbon, 6 hydrogen
1 oxygen and 1 oxygen

58
Chemical Compound Formula
Hydrogen peroxide = H2O2

Benzene = C6H6

Glucose = C6H12O6

59
Molecular formula of compounds

H2O - water

CH3CH2OH – ethyl alcohol

60
Types of Molecules
Monoatomic
contains only one atom

Homoatomic
consists of atoms of the same element

Polyatomic
Composed of at least two or more elements in a stable structure.
61
Radioactivity
Radioactivity can be defined as the
spontaneous emission of high-energy
particles or rays from the nuclei of some
atoms.

The term radioactivity and radioactive
elements were first described by Henri
Becquerel in 1896.

62
What is radioactivity?
Radioactivity can be defined as the
spontaneous emission of high energy
particles or rays from the nuclei of some
atoms.

63
Types of radioactive emissions

Rutherford first identified three main
types of radioactive emissions which are:

1. Alpha rays (a, ⍺)

2. Beta rays (b, β)

3. Gamma rays (g, ɣ)

64
Penetrating power of radioactivity

a
b g

0.01 mm 1 mm 100 mm

65
Penetrating power of radioactivity

Ionization power = a > b > g
Penetrating power = a < b < g

66
Electromagnetic Spectrum

67
Periodic Properties
of Elements
 The order of elements
in the periodic table
Mendeleev’ periodic table in 1871
– “Elements were arranged on the
basis of fundamental property,
atomic mass and chemical
properties.”

»Periodic table;
– provides information about
- chemical properties,
- chemical reactions and
- groups different elements with similar
properties. 69
 Development of Periodic
Table Over Time
How more than 110 elements can be
arranged in a table?
– This problem was first solved by the Russian
chemist Mendeleev and the German chemist
Meyer.
– These scientists first classified the
elements based on their similar physical and
chemical properties.

70
The ordering of elements

Based on the recordings of 2015, there are
118 elements in total. Moreover, most of
these elements are discovered between
1735-1843.

71
 Periodic Table
H He
Li Be B C N O F Ne
Na Mg Al Si P S Cl Ar
K Ca Sc Ti V CrMn Fe Co Ni Cu Zn Ga Ge As Se Br Kr
Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe
Cs Ba La Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po At Rn
Fr Ra Ac Rf Du Sg Bo HaMe 110111

Ce Pr Nd Pm Sm Eu Gd Tb Dy Ho Er Tm Yb Lu
Th Pa U Np PuAmCm Bk Cf Es FmMd No Lr
1700 - 1750 1850 - 1900
Before 1600
1750 - 1800 1900 - 1950
1600 - 1700
1800 - 1850 1950 - 2000 72
Periodic Table: General names of
elemental groups
Alkali metals
I A II A Alkaline earth metal III A IV A V A VI A VIIA VIIIA

H He
Halogens
Li Be Noble gases B C N O F Ne

Na Mg III B IVB V B VIB VIIB VIII B IB IIB Al Si P S Cl Ar

K Ca Sc Ti V Cr Mn Fe Co Ni Cu Zn Ga Ge As Se Br Kr

Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe

Cs Ba La Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po At Rn

Fr Ra Ac Ce Pr Nd Pm Sm Eu Gd Tb Dy Ho Er Tm Yb Lu

Th Pa U Np Pu Am Cm Bk Cf Es Fm Md No Lr
73
List of name of chemical element

74
Properties of Periodic Table
The elements in periodic table are
arranged based on their chemical
properties such as reaction types and
reactivity and their physical properties
such as boiling points and melting points.
The elements of periodic table are
organized by;
– Atomic size (atomic radius)
– Ionization energy (the amount of energy
required to remove an electron from an
isolated atom or molecule)
– Electron affinity (the amount of energy
required for an electron to be added to a
neutral atom in a gas form)
– Ionic size (ionic radius) 75
PERIODIC TABLE INFORMATION

ABOUT ELEMENT

Chemical symbol Chemical activity
Atomic number Energy level
Atomic mass Electron configuration
Proton number Chemical properties
Physical state at RT
Electron number
Oxidation state
Neutron number
Characteristics of metal and nonmetal
76
Periodic Table Properties
All elements are arranged from left to right and top to bottom in
order of atomic numbers in the periodic table.

GROUP: The vertical columns on the periodic table are called as
groups because of their similar chemical properties. The members of
group of elements have the same numbers of valence electrons.

PERIOD: Horizontal rows are known as period and moving from left
to right across a same period, atoms become smaller and electrons
move close to the nucleus, thereby increasing the electron affinity
from left to right. 77
 ORBITAL BLOCKS
s-block: All of the elements in the first two columns on the left
side of the periodic table are filling the s orbital of their highest
energy level with their final electron.
– s-block elements in the first two columns on the left side of the periodic
table (IA and IIA groups).
p-block: Elements contain valence (highest energy) electrons in the
p-orbitals.
– p-block elements are IIIA, IVA, VA, VIA, VIIA and VIIIA groups in the
periodic table.
d-block:
– d-block elements are IIIB, IVB, VB, VIB, VIIB, IB and IIB groups in the
periodic table.
f-block: Elements are also known as inner transition metals because
of their placement in the periodic table. They contain the
lanthanides, and actinides, whose atomic number ranges from 89-111. 78
ORBITAL BLOCKS
s- and p-blocks elements in the periodic table are
also known as main group elements and their groups
are represented by prefixing their group numbers
with the letter ‘A’, such as 1A, 2A, 3A, 4A, 5A, 6A,
7A and 8A groups.

d and f block elements are also called as side groups
and they are presented by prefixing their group
numbers with the letter ‘B’ such as 2B and 3B
groups in the periodic table.
79
80
Chemical Bonds
Chemical Bonds
A chemical bond can be established between
atoms when they lose, acquire or share
electrons.
The bonding of atoms is directly related to the
numbers and configuration of electrons.
There are basically two types of chemical
bonds :
Intramolecular bonds
Intermolecular bonds
82
 Intramolecular Bonds
Transfer of electrons
attraction

Ionic Bond + -

cation anion

Sharing of electrons
Chemical bond Covalent ⚫⚫
Bond
⚫ ⚫
H Cl ⚫
⚫⚫
Metallic Bond

Bonding electrons
83
Ionic Bond
Ionic bond is a type of linkage formed from
the electrostatic attraction between
oppositely charged, positive (cation) and
negative (anion) ions in a chemical compound.

Sodium ion, Na+, — positive (cation) charge
Chloride ion, Cl–, — negative (anion) charge

85
Ionic Bond Properties
Ionic bond is formed when electrostatic
forces in different directions attract each
other.

The complete transfer of one or more
electrons from one atom to the other takes
place in a pure ionic bond.

In summary, ionic bond is based on transfer
of electrons and is the attraction between
positive and negative ions. 86
Electron transfer in NaCl
Na is a metal.
Cl is a non-metal element.
Na (metal) transfer its one electron to
Cl (non-metal) atom.
Because;
– The electron configuration of Na is 2-8-1. It
is easier to donate one electron rather than
acquiring seven electrons for Na metal.
– The electron configuration of Cl is 2-8-7. It
is easier to obtain one electron from Na to
complete its octet.

87
Sodium and Chlorine
Na is converted to Na+ cation; Cl, is converted to Cl-
anion.
Na+ and Cl- complete their octets, Na+ contains 10 e- and
Cl- contains 18 e- in total in NaCl
e- compound. e-
e- e- e- e- e- e-
e- e- e- e- e-
11 P+ 17 P+
e- e- e- e-
e- 12 N e- 18 N
e- e- e-
e- e- e- e- e-

e- 88
Potassium and Chlorine
K is converted to K+ cation; Cl, Cl- is converted to anion.
K+ and Cl- complete their octets, K+ contains 18 e- and Cl-
contains 18 e- in total in KCl compound.
e- e-
e- e- e- e- e- e- e-
e- e- e- e- e-
19 P+ 17 P+
-
e e - e - e- e- e- e- e- 18 N
20 N
e- e- e-
e- e- e- e-
e- e- e- e-
e- e-
e- 89
Covalent Bonds
Covalent bonds are formed by sharing
electrons to form electron pairs between
atoms.
Single covalent bond is formed when a pair of
electron is shared.
Double covalent bond is formed as a result of
sharing two pairs of electrons.
Triple covalent bond is formed when three
pairs of electrons are shared.

91
Single Covalent Bond

e-
1 P+
1 P+
e-

Two hydrogen atoms share a pair of electrons to form single
covalent bond and form H2 molecule.

92
 Double Covalent Bonds
0=0
structural
e- e- formula e- e-

e- e-
8 P+ 8 P+
e- 8N
e- e- e- e- 8N
e-
e-
02
molecular
formula e- e-
e-

Two oxygen atoms share two pairs of electrons to form double covalent bond
and to form 02 molecule.
93
 Triple Covalent Bond
e- structural e-
formula

e- e-
7 P+ 7 P+
e- 7N
e- e- e- e- 7N
e-
e- e-
N2
molecular
e-
e- formula

Both nitrogen atom contains 5 electrons in the outermost shell.
Two nitrogen atoms require 3 electrons to achieve their octet configurations so that they
shares three pairs of electrons to form triple covalent bonds and to form N2 molecule. 94
 Methane:
Four single covalent bond
P+

e- e-

P+ e- 6P+ e- P+
e- e- e- e-
6N

structural formula
e- e-

P+
CH4 – molecular formula
95
Polar Covalent Bonds
Polar covalent bonds are formed typically
between different atoms in a molecule.
Therefore, atoms with different
electronegativities share electrons in a
covalent bond.
While there is no net charge difference in the
molecule, sharing of electrons occurs at the
atomic level. Water (H2O) is an example of
polar covalent bond.

96
Oxygen and Hydrogen
Water is a typically polar molecule due to the significant unequal
sharing of electrons between hydrogen and oxygen atoms. The
unequal sharing of electrons makes H2O molecule slightly negative
near oxygen atom and slightly positive near its hydrogen atoms.

P+ P+
e- - e-
e e-
e- e- 8P+ e- e-
8N

H + H
H2O Water e- e-
O
molecular formula -
structural formula 97
Intermolecular Bonds (Interactions)
Differences in physical properties such
as melting or boiling points are affected
by intermolecular forces. Five major
types of intermolecular forces
(interactions):
– Ion-ion interactions,
– Dipole-dipole interactions,
– Ion-dipole interactions,
– London forces,
– Hydrogen bonds
98
Intermolecular Forces:
Differences in physical properties
such as melting or boiling points are
determined by intermolecular forces
between molecules.

99
Intermolecular Forces:
Five major types of intermolecular
forces:
Ion-ion interactions
Dipole-dipole interactions
Ion-dipole interactions
London forces
Hydrogen bonds

100
Ion-Ion Interactions
Ion-ion interaction is defined as
electrostatic attraction between
positively-charged cation ion and
negatively-charged anion ion.
Na+ and Cl- ions stack on each other
in NaCl salt.
Ion-ion interactions are weaker than
hydrogen, metallic, covalent and ionic NaCl: Ionic interaction
bonds. forming solid salt crystals.
The repeating ionic interactions in NaCl
form solid salt crystal structure.

101
Ionic solids:
Ionic solids melt at high
temperatures and boil at even
higher temperatures :
– NaCl mp = 801 °C; bp = 1413 °C
– KCl mp = 776 °C; bp = 1500 °C
– MgO mp = 2800 °C; bp = 3600 °C

102
Dipole-Dipole Interactions

Dipole-dipole
interactions are
encountered between
polar molecules.
Dipole-dipole interactions
are weaker than ion-ion
interactions.

103
Ion-Dipole Interactions
Ion-dipole
+ interactions are an
attractive force that
results from the
electrostatic
attraction between an
ion and a neutral
molecule containing
- dipole.

104
Ion-Dipole Interactions
A positive ion (cation)
attracts partially
+ negative end of a neutral
polar molecule.

A negative ion (anion)
- attracts partially
positive end of a neutral
polar molecule.
105
London Forces
London dispersion forces can be described as
a temporary attractive force due to the
formation of temporary dipoles in a nonpolar
molecule.

When electrons in two adjacent atoms are
displaced in such a way that atoms get some
temporary dipole moments, they attract each
other through London forces.
106
London Forces
London forces are the
weakest intermolecular
interactions.
London forces increase with
the increase in molecular mass
and in numbers of electrons.

107
Hydrogen Bonds
Hydrogen bond is an intermolecular force
that are formed as a result of interaction of
hydrogen with highly electronegative atoms
including F, O and N.
For example - H2O, DNA

Hydrogen bonds in water also gives the
characteristic feature of water as follows:
Surface tension
Fluidity (viscosity)
Vapor pressure.
108
Hydrogen Bonds
Hydrogen bonds are
formed between
hydrogen atoms of
one water molecule
and oxygen atom of
a neighboring water
molecule.
109
Hydrogen Bonds
Hydrogen bond is a special type of dipole-
dipole interaction that occurs between
the lone pair of a highly electronegative
atoms typically F, O and N, and H atom a
F-H, O-H and N-H bond.

Hydrogen bonds are weak intermolecular
interaction than intramolecular bonds.

110
 Hydrogen Bonds
Hydrogen bonds are stronger than
London forces, ion-ion interactions
and dipole-dipole interactions.

111