2nd Year Chemistry: Periodic Classification Of Elements And Periodicity PDF

Summary

This textbook chapter on periodic classification of elements and periodicity explains the organization of the periodic table. It discusses the historical development of periodic classifications and the modern periodic table and trends in physical properties.

Full Transcript

CHAPTER
Periodic Classification Of
1 Elements And Periodicity

Animation 1.1 : Periodic Table
Source and Credit: eLearn.Punjab
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

IN THIS CHAPTER YOU WILL LEARN

1. To describe the periodic table in terms of groups and periods.
2. To describe and explain periodicity in physical and chemical
properties.
3. To describe the position of hydrogen in the periodic table.

1.1 INTRODUCTION

To achieve a thorough understanding of a complex subject like chemis-
try, it would be highly desirable to fit all the facts into a simple logical pattern.
The periodic table of elements has served the purpose to systematize the
properties of the elements for well over 100 years.The development of pe-
riodic table is one of the most significant achievements in the history of
chemical sciences.
The Periodic Table provides a basic framework to study the periodic behaviour
of physical and chemical properties of elements as well as their compounds.
In previous classes, you have learnt about the periodic classification
of elements. This chapter describes in more detail the periodic table and the
periodicity of elements.

1.1.1 Historical Background

The early history of ideas leading up to the Periodic classification of elements
is fascinating but will not be treated in detail.Those who made memorable
contributions in this field are Al-Razi,Dobereiner,Newland and Mendeleev.
Al-Razi’s classifications was based on the physical and chemical properties
of substances. Dobereiner, a German chemist in 1829, arranged then known
elements in group called Triads, as each contained three elements with
similar properties. Newland who was an English chemist , in 1864, classified
62 elements, known at that time , in increasing order of thier atomic masses.
He noticed that every eighth element had some properties in common with the
first one. The principle on which this classification is based was called the Law of
Octaves.
2
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

In 1871, a Russian Chemist, Dmitri Mendeleev, gave a more useful
and comprehensive scheme for the classification of elements.
He presented the first regular periodic table in which elements
of similar chemical properties were arranged in eight vertical
columns called Groups.The horizontal rows of the table were
called Periods.
Mendeleev also started by arranging the elements in ascending order of their
atomic masses and found that elements having similar chemical
properties appeared at regular intervals. This significant observation was
called Periodic Law. Mendeleev left some gaps in his table for elements,
which had not yet been discovered, and by considering their positions
in the periodic table, he predicted properties of these elements. For
example, germanium was not known at that time, but Mendeleev was
confident that this element must exist so he predicted its properties.
A few years later, germanium was indeed discovered and a
remarkable agreement was found with Mendeleev’s predictions.

1.1.2 Improvements In Mendeleev 's Periodic Table

In order to make the periodic table more useful and accurate, a few
improvements were made in Mendeleev s periodic table. After the discovery
of atomic number by Moseley in 1911, it was noticed that elements
could be classified more satisfactorily by using their atomic numbers,
rather than their atomic masses.
Hence, the periodic table was improved by arranging the elements in
ascending order of their atomic numbers instead of their atomic
masses. This improvement rectified a number of confusions present
in the old periodic table.The modern Periodic Law states that:
“if the elements are arranged in ascending order of their
atomic numbers, their chemical properties repeat in a periodic
manner”
Another improvement was the addition of an extra group
(group VIIIA) at the extreme right of the periodic table.
This group contains noble gases, which had not been discovered in
Mendeleev’s time.

3
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Another confusion in Mendeleev’s table was that elements like Be, Mg, Ca,
Sr, Ba and Zn, Cd, Hg were placed in a single vertical group, while according
to their properties they belonged to two different categories. The same
was true for so many other elements placed in the same vertical group.
In modern periodic table, the confusion was removed by dividing the
elements in two types of vertical groups, A and B. In modern periodic table,
Be, Mg, Ca, Sr and Ba are placed in group IIA and Zn, Cd, Hg in group IIB.
1.2 THE MODERN PERIODIC TABLE

In modern periodic table (see periodic table) all the elements are arranged
inascending order of their atomic numbers.
Followings are the essential features of the periodic table.

1. Group and Periods

Elements with similar properties are placed in vertical columns called Groups.
There are eight groups ,which are usually numbered by Roman numerals I to
VIII.Each group is divided into two subgroups, designated as A and B subgroups.
The subgroups, containing the representative or normal elements are labelled
as A subgroups, whereas B subgroup contain less typical elements, called
transition elements and are arranged in the centre of the periodic table.
The horizontal rows of the periodic table are called Periods.The essential features of
periods are as follows:
a) There are 7 periods in the periodic table numbered by Arabic numerals 1 to 7.
b) The period 1 contains only two elements, hydrogen and helium.
c) The periods 2 and 3 contain eight elements each and are called short periods.
All the elements in these periods are representative elements and belong to
A subgroup. In these periods, every eighth element resembles in properties
with the first element. As lithium and beryllium in the 2nd period resemble
in most of their properties with sodium and magnesium of the 3rd period,
respectively. Similarly, boron and aluminium both show oxidation state of +3,
fluorine in 2nd period has close resemblances with chlorine of 3rd period.

4
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Table 1.1 MODERN PERIODIC TABLE OF THE ELEMENTS

5
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

d) The periods 4 and 5 are called long periods. Each long period consists of
eighteen elements. Out of these, eight are representative elements belonging
to A subgroup similar to second and third periods. Whereas the other ten
elements, placed in the centre of the table belong to B subgroups and are known
as transition elements. In these periods, the repetition of properties among
the elements occurs after 18 elements. As after 19K (having atomic number 19)
the next element with similar properties is 37Rb.
e) The period 6 is also a long period, which contains thirty-two elements.
In this period there are eight representative elements, ten transition
elements and a new set of fourteen elements called Lanthanides as
they start after 57
La. Lanthanides have remarkably similar properties
and are usually shown separately at the bottom of the periodic table.

f ) The period 7 is incomplete so far. It contains only two normal elements 87Fr
and 88Ra, ten transition elements and fourteen inner transition elements. The
inner transition elements of this period are called Actinides, as they follow
89
Ac.The actinides are also shown at the bottom of the periodic table under
the Lanthanides. Due to their scarcity, the inner transition elements are
also called rare earth elements.
2. Some More Families in the Periodic Table:
While studying about periods you have noticed that certain rows of elements with
similar properties have assigned common names such as transition elements,
Lanthanides, Actinides or Rate Earth elements.Similarly, due to their peculiar
characteristics, some typical elements belonging to sub-groups A, have also
been assigned family names. For example,elements of the group IA are called
Alkali Metals, because of their property to form strong alkalies with water.

2Na +2H2O ——-—> 2NaOH + H2
Similarly,due to their presence in Earth’s crust and alkaline character,the
elements of group IIA are known as Alkaline Earth Metals. Another important
family in the periodic table is Halogen family. The name “Halogens” is given to
the elements of group VIIA, due to their salt forming properties. As the gases
of group VIIIA ‘are least reactive they are called “Noble Gases”,These family
names are useful for a quick recognition of an element in the periodic table.
6
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

3. Blocks in the Periodic Table
Elements in the periodic table can also be classified into four blocks.
This classification is based upon the valence orbital of the element involved
in chemical bonding. According to this classification, elements of IA and IIA
subgroups are called s-block elements because their valence electrons are
available in s orbital.The elements of IIIA to VlllA subgroups (except He) are
known as p-block elements as their valence electrons are present in p orbital.
Similarly in transition elements, electrons in d-orbital are responsible for
their valency hence they are called d-block elements. For Lanthanides and
Actinides valence electrons are present in f- orbital hence these elements are
called f-block elements. This classification is quite useful in understanding
the chemistry of elements and predicting their properties especially the
concept of valency or oxidation state.
4. Metals, Non-metals and Metalloids
Another basis for classifying the elements in the periodic table is
their metallic character. Generally, the elements on the left hand
side, in the centre and at the bottom of the periodic table are metals,
while the non-metals are in the upper right corner of the table.
Some elements, especially lower members of groups, III A, IVA and VA(as
shown in Table 1.1) have properties of both metals as well as non-metals.
These elements are called semi-metals or metalloids. In the periodic table
elements of groups IVA to VIIIA, at the top right hand corner above the stepped
line, are non-metals. The elements just under the “steps’ such as Si, As, and Te
are the metalloids. All the remaining elements, except hydrogen, are metals.
1.3 PERIODIC TRENDS IN PHYSICAL PROPERTIES

As you have studied so far that in modern periodic table the elements
are arranged in ascending order of their atomic numbers and their classification
in groups and periods is based on the similarity in their properties. Yet,
due to the gradual increase in the number of protons in the nucleus
and electrons in outer shells the physical and chemical properties of the elements
steadily vary within a group or a period. Here, we study some trends in physical
properties.
7
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

1. ATOMIC SIZE
a) Atomic Radius:
Atoms are so small that it is impossible to see an atom even with a
powerful optical microscope. The size of a single atom therefore cannot
be directly measured. However, techniques have been developed which
can measure the distance between the centres of two bonded atoms of any
element. Half of this distance is considered to be the radius of the atom.
In the periodic table, the atomic radius increases from top to bottom within a
group due to increase in atomic number. This is because of the addition
of an extra shell of electrons in each period. In a period, however, as the
atomic number increases from left to right, the atomic radius decreases. This gradual decrease in the radius is due to increase in the positive
charge in the nucleus. As the positive nuclear charge increases, the
negatively charged electrons in the shells are pulled closer to the nucleus.
Thus, the size of the outermost shell becomes gradually smaller. This
effect is quite remarkable in the elements of longer periods in which “d”
and “f ” subshells are involved. For example, the gradual reduction in
the size of Lanthanides is significant and called Lanthanide Contraction.
b) Ionic Radius:
When a neutral atom loses one or more electrons, it becomes a positive
ion. The size of the atom is decreased in this process because of the two
reasons.

8
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

First the removal of one or more electrons from a neutral atom usually results
in the loss of the outermost shell and second, the removal of electrons
causes an imbalance in proton-electron ratio. Due to the greater attraction
of the nuclear charge, the remaining electrons of the ion are drawn
closer to the nucleus.
Thus, a positive ion is always smaller than the neutral atom from which
it is derived. The radius of Na is 157pm and the radius of Na+ is 95pm.
On the contrary, a negative ion is always bigger than its parent atom.
The reason is that addition of one or more electrons in the shell of
a neutral atom enhances repulsion between the electrons causing
expansion of the shell.

Thus, the radius of fluorine atom is 72pm and that of the fluoride ion (F ) is
136pm.
In a group of the periodic table, similar charged ions increase in size from
top to bottom. Whereas within a period, isoelectronic positive ions
show a decrease in ionic radius from left to right, because of the
increasing nuclear charge.
The same trend is observed for the isoelectronic negative ions of a
period; ionic size decreases from left to right. The variations in atomic and
ionic radii of alkali metals and halogens are shown in Fig 1.1 and Fig.1.2.
9
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

2. Ionization Energy

The ionization energy of an element is the minimum quantity of energy which
is required to remove an electron from the outermost shell of its isolated
gaseous atom in its ground state. The ionization energy of sodium is 496kJ mol-1.

Na(g) → Na+ (g) + e- i = 496 kJ mol-1
Elements with greater number of electrons have more than one
values of ionization energy. So for magnesium, the first ionization
energy value is the energy required to remove the first electron:

Mg (g) → Mg+ (g) + e- i1 = 738 kJ mol-1
Similarly, the second ionization energy value is the
energy required to remove the second electron.

Mg+ (g) → Mg++ + e- i2= 1451kJ mol-1

a) Variation Within a Group:

The factors upon which the ionization energy
of an atom mainly depends are magnitude
of nuclear charge, size of the atom, and the
“shielding effect”. The shielding effect is
actually the repulsion due to electrons in
between the nucleus and the outermost shell.
This effect increases, as the size of the atom
increases due to addition of an extra shell
successively in each period hence more
number of electrons shields the nucleus.
Fig. 1.3 Ionization energies of
alkali metals
10
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Going down in a group, the nuclear charge increases but as the
size of the atom and the number of electrons causing the shielding
effect also increases therefore ionization energy decreases from
top to bottom. That is why in alkali metals, for example, it is easier
to remove an electron from caesium atom than from lithium atom.
The change in ionization energies of IA elements is shown in Fig. 1.3.

b) Variation Across a Period:

Generally, smaller the atom with greater nuclear charge, more
strongly the electrons are bound to the nucleus and hence higher
the ionization energy of the atom. By moving from left to right
in a period, the outer shell remains the same, while the nuclear
charge increases effectively that makes the removal of an electron
difficult and hence the value of ionization energy increases.

Fig. 1.4 Ionization energies of
elements of short periods.

11
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Although, the number of electrons also increases in this case but the
shielding is not very effective within the same shell. The trend of ionization
energies of short periods is shown in Fig.1.4 The figure also reveals that inert
gases have the highest values of ionization energy because due to complete
outermost shell in them, the removal of electron is extremely difficult.
3. Electron Affinity (E.A)

The electron affinity is the energy released or absorbed, when
an electron is added to a gaseous atom to form a negative ion.

F (g) +e- → F-(g) E.A= -337 kJ mol-1

Energy is usually released when electronegative elements absorb the first
electron and E.A. in such cases is expressed in negative figures,
as in the case of halogens. When a second electron is added to a
uninegative ion, the incoming electron is repelled by the already
present negative charge and energy is absorbed in this process.

O(g) + e- →O -
(g)
E.A1= -141 kJ mol-1

O- (g) + e- →O 2-
(g)
E.A2= +780 kJ mol-1

The absorbed energy is expressed as the electron affinity in positive
figures. Electron affinity depends upon size of the atom, nuclear charge
and vacancies in the outermost shell. Relatively smaller atoms with one or
two vacancies in the outermost shell show large values of electron affinity.

12
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Electron affinity generally increases with increasing atomic number
within a period and decreases from lighter to heavier elements in a
given group of the periodic table. Knowledge of electron affinities can be
combined with the knowledge of ionization energies to predict which atoms
can easily lose electrons and which can accept electrons more readily.

4. Metallic and Non-Metallic Character

It has already been discussed in this chapter that elements of
periodic table can be divided into metals, non-metals and metalloids.
Chemically all the elements which have a tendency to form positive
ions by losing electrons are considered metals. All metals are good
conductor of heat and electricity. A characteristic property of metals
is that they form basic oxides which give bases when dissolved
in water.

Na2O (s) + H2O (l) →2 NaOH (aq)
As it becomes easier to remove the electron of an atom bigger in
size, therefore metallic character increases from top to bottom in a
given group of elements. On the contrary, it decreases from left to right
across a period. The elements of group VIIA (the halogens) are least
metallic in nature.The elements which gain electrons and form
negative ions are called non-metals. All the gases are non-metals. The
non-metals are normally poor conductor of heat and electricity. Non-
metals form acidic oxides which yield acids on dissolving in water.

SO3 (g) + H2O (l) →2 H SO (aq)
2 4

13
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Non-metallic character of an element, decreases as the atomic size increases.
Therefore in a group of non-metals like halogens, the non-metallic character
decreases from top to bottom. The member at the top, fluorine, is the
most non-metallic element of the periodic table. This trend can also be
verified in the elements of groups VA and VIA. Nitrogen and oxygen are pure
non-metals and usually exist in gaseous state while bismuth and polonium,
the members at the bottom of these groups, are fairly metallic in nature.
5. Melting And Boiling Points

Melting and boiling points of elements tell us something about
how strong the atoms or molecules in them are bound together.
(a) Variation in a Period
Across the short periods, the melting and boiling points of elements increase
with the number of valence electrons upto group IVA and then decrease
upto the noble gases. The melting points of group IA elements are low
because each atom in them provides only one electron to form a bond with
other atom. Melting points of group IIA elements are considerably higher
than those of group IA elements because each atom in them provides two
binding electrons.

Fig. 1.5 Variation of melting points with atomic number
14
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Since carbon has the maximum number of binding electrons, thus
it has a very high melting point in diamond in which each carbon is
bound to four other carbon atoms. In general, the elements which
exist as giant covalent structures have very high melting points, Fig. 1.5.

An important change occurs when we move from group IVA to groups VA,
VIA, VIIA as the lighter elements of these group exist as small,
covalent molecules, rather than as three dimensional lattices.
For instance, nitrogen,oxygen and fluorine exist as individual
molecules which have very weak intermolecular forces between them.
Consequently, their melting and boiling points are extremely low.
(b) Variation in a Group
The melting and boiling points of IA and IIA group elements decrease
from top to bottom due to the increase in their atomic sizes. The
binding forces present between large sized atoms are relatively
weaker as compared to those between smaller atoms, Fig. 1.6.
For elements of group VIIA, which exist in the form of molecules,
the melting and boiling points increase down the group, Fig. 1.7.
This is because large molecules exert stronger force
of attraction due to their higher polarizabilities.

Fig.1.6 Melting points of Group IIA elements.
15
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

6. Oxidation State

The oxidation state of an atom in a compound is defined as the charge
(with the sign), which it would carry in the compound. In ionic compounds,
it is usually the number of electrons gained or lost by the atom. As in the case of
sodium chloride, the oxidation states of sodium and chlorine are + 1 and -1,
respectively. In covalent compounds, it is decided on the basis of the
difference in their relative electronegativities. For example, SnCl4 is
a covalent compound. The oxidation state of tin is + 4 and that of
chlorine is -1. The oxidation state of an element is zero in its free state.
The oxidation state of a typical element is directly or indirectly related to the
group number to which the element belongs in the periodic table. The elements of
group IA to IVA have the same oxidation states as their group numbers are. Just as
B, Al and Ga belong to group IIIA, hence, they always show oxidation state of +3. So,
for the elements

Fig.1.7. Bloiling (.---------) and melting
points(;_______) of halogens.

16
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

of these groups, the oxidation state is same as the number of electrons
present in the valence shells of the elements. However, for the
elements of group VA, the oxidation states are either the number
of electrons present in the valence shell (which is same as their
group number) or the number of vacancies available in these shells.

For example, N, P, As and Sb frequently show +3 as well as +5 oxidation states.
Elements of group VIA show almost similar behaviour. In H2SO4, sulphur shows
the oxidation state of +6, which is the number of electrons in its outermost
shell whereas its oxidation state is -2 in H2S,
which is the number of vacancies in the shell.
In group VIIA elements oxidation state is mostly - 1, which is again
the number of vacancies in their outermost shells. Group VIIIA
elements, which are also called zero group elements, usually show zero
oxidation state because there is no vacancy in their outermost shells.
Transition elements, which are shown in B subgroups of the periodic table,
also show the oxidation states equal to their group number as it can be seen
for Cu(I), Zn(II), V(V), Cr(VI) and Mn (VII). But due to greater number of
valence electrons available in partly filled d-orbitals these elements usually,
show more than one oxidation states in their compounds.

7 Electrical Conductance

One of the most familiar properties of metals is their ability to conduct
electricity. This property is mainly due to the presence of relatively
loose electrons in the outermost shell of the element and ease of
their movement in the solid lattice. The electrical conductance of
metals in groups IA and IIA, generally increases from top to bottom.
However, the trend is not free from the individual variation in different
atoms. Metals of group IB, which are known as coinage metals, have
extraordinary high values of electrical conductance. Non-metals, on
the other hand, especially of groups VIA and VIIA, show such low
electrical conductance that they can be considered as nonconductors.

17
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

In the series of transition metals, the values of electrical conductance vary so
abruptly that no general trend can be assigned to them. Carbon, in the
form of diamond is non-conductor because all of its valence electrons are
tetrahedrally bound and unable to move freely, while in the form of graphite,
carbon is fairly good conductor because one of its four valence electrons is
relatively free to move. The lower elements of group IVA, tin and lead,
are fairly good conductors and their values of electrical conductivity
are comparable with those of their counterparts in group IA.

8 Hydration Energy
The hydration energy is the heat absorbed or evolved when one mole
of gaseous ions dissolve in water to give an infinitely dilute solution. For
example, when one mole of gaseous hydrogen ions are dissolved in water
resulting an infinitely dilute solution, a large amount of heat is liberated:

H+ (g) + H2O (l) → H3O+(aq) DHh = - 1075 kJ mol-1

Hydration energies of a few negative and
positive ions are shown in the Table 1.2. Table 1.2 Hydration
It is evident from the table that hydration
Energies of Ions
energies highly depend upon charge to size ratio
of the ions. For a given set of ions, for example Hh
Ion
of group IA, charge to size ratio decreases from kJ mol-1
top to bottom in a group, the hydration energy Li+ -499
also decreases in the same fashion. On the Na+ -390
contrary, the hydration energy increases
K+ -305
significantly by moving from left to right in
Mg2+ -1891
a period as the charge to size ratio increases,
as found in the metal ions of third period. Ca2+ -1562
Al3+ -4613
F- -457
Cl- -384
Br_ -351
I- -307
18
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

1.4 PERIODIC RELATIONSHIP IN COMPOUNDS

a) Halides:

Halides are the binary compounds which halogens form with other
elements. The physical properties of halides are largely determined by the
nature of bonding present in them. On this basis, halides can be classified
into twogeneral classes: ionic and covalent.In between the two, there is
another class of halides in which the halogen atom acts as a bridge between
the two atoms of the other element, such halides are termed as “Polymeric”
halides.Strongly electropositive elements, having greater electronegativity
difference with halogen atom, form ionic halides.The halides of group IA
are considered purely ionic compounds, which are high melting point solids.
Such halides have three-dimensional lattices consisting of discrete ions.

Table 1.3 Melting Points of Chlorides of Period
Three Elements and Their Bonding Character

Name Property
of compounds Melting
Type of bonding
point (°C)

NaCl 808 Ionic
MgCl2 715 Partly ionic
AlCl3 192 Partly ionic
SiCl4 -68 Partly covalent
PCI3 -93 Partly covalent
S2CI2 -80 Partly covalent

19
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Among the pure ionic compounds, the fluorides have the highest lattice
energies due to the small size of fluoride ion. Thus for ionic halides,
the fluorides have the highest melting and boiling points which
decrease in the order: fluoride > chloride > bromide > iodide.
Less electropositive elements, such as Be, Ga and AI form polymeric
halides having partly ionic bonding with layer or chain lattices.

The lattice of SiCl4 consists of discrete molecules, which are highly polar.
The bonds in PCI3, and S2Cl2 are less polar than those of SiCl4. On moving across the
periodic table from left to right, the electronegativity difference reduces
and the trend shifts towards covalent halides. The gradual change
in bond type and melting points of the chlorides on moving
across period 3 of the periodic table is shown in Table. 1.3.

As the intermolecular forces in covalent halide molecules are weak van der
Waal’s forces so they are often gases, liquids or low melting point solids.
Physical properties of covalent halides are influenced by the size and
polarizability of the halogen atom.Iodides, as being the largest and more
polarizable ions, possess the strongest van der Waal’s forces and therefore
have higher melting and boiling points than those of other covalent halides.

The variation in bonding character is also present in descending from top
to bottom in the halogen group. In general, for a metal the order of decreasing
ionic character of the halides is: fluoride > chloride > bromide > iodide.
For example, AlF3 is purely ionic compound having melting point 1290°C and fairly
a good conductor, whereas AlI3 is predominantly covalent with melting
point 198°C and electrically a non-conductor. In case of an element
forming more than one halides, the metal halide in its lower oxidation
state tends to be ionic, while that in the higher oxidation state is covalent.
For example, PbCl2 is mainly ionic and PbCl4 is fairly covalent. This can again
be explained by the high polarizing power of Pb4+ as compared to that
of Pb2+.

20
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

b) Hydrides
The binary compounds of hydrogen with other elements are called hydrides.
According to the nature of bonding, hydrides may be broadly classified
into three classes: ionic, covalent and intermediate. The elements of group
IA and the heavier members of group IIA form ionic hydrides, which
contain H- (Hydride) ion.These hydrides are crystalline solid compounds,
with high melting and boiling points and which conduct electricity
in molten state.
The tendency towards covalent character increases by moving
from left to right in the Periodic Table. Hydrides of beryllium
and magnesium represent the class of intermediate hydrides.
Their properties are in between the ionic and covalent hydrides.
They have polymeric structures and covalent nature, Table 1.4.
Table 1.4. Hydrides of the Elements of IA to VIIA and IIB Subgroups.

IA IIA IIB IIIA IVA VA VIA VIIA
LiH BeH2 BH3 CH4 NH3 H2O HF
NaH MgH2 AIH3 SiH4 PH3 H2S HCl
KH CaH2 ZnH2 GaH3 GeH4 AsH3 H2Se HBr
RbH SrH2 CdH2 InH3 SnH4 SbH3 H2Te HI
CsH BaH2 PbH4 BiH3
IONIC INTERMEDIATE COVALENT
The covalent hydrides are usually gases or volatile liquids. They are
non-conductors and dissolve in organic solvents. Their bond energies depend
on the size and the electronegativity of the element. Stability of covalent
hydrides increases from left to right in a period and decreases from top to
bottom in a group.Fluorine forms the most stable hydride
and the least stable are those of thallium, lead and bismuth.
These hydrides are formed by elements with electronegativity values
greater than 1.8 (Pauling Scale). Since the electronegativity of hydrogen is
2.1, most of these hydrides have polar covalent bonds in which hydrogen
is carrying a slight positive charge.

21
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

On moving from left to right across a period the electronegativity of the other
element increases and the hydrogen-element bond becomes more polar.
Due to high polarity the hydrides like H2O and HF are capable of forming
hydrogen bonds between their molecules. The boiling points of covalent
hydrides generally increase on descending a group as shown in Table 1.5,
except the hydrides like H2O, HF and NH3 which, due to hydrogen bonding, have
higher boiling points than might be expected.

Table. 1.5. Melting and Boiling points of Hydrides of Groups IV A and VI A

Hydrides Property

(Group IVA) Melting point Boiling point ‘
(°C) (°C)
CH4 -184 -164
SiH4 -185 -112
GeH4 -165 -90
SnH4 -150 -52
(Group VIA)
H2O 0.00 100
H2S -82.9 -59.6
H2Se -65.7 -41.3
H2Te -48 -1.8

c) Oxides
Oxygen forms compounds, called oxides, with almost every other element in the
periodic table. Since, many of these have quite unusual properties, there is an
extensive and varied chemistry of the compounds of oxygen. Oxides can be classified in
more than one ways: based upon the type of bonding they have as well as their
acidic or basic character.We shall discuss here the classification based on
their acidic or basic behaviour. In this chapter, you have already studied
that metal oxides are basic in character as they yield bases in water and
non-metallic oxides are acidic because they form acids in water.Basic
oxides and acidic oxides react with one another to give salts, for example:

22
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

Na2O (s) + SO3 (g) → Na2SO4 (s)

There is a third type of oxides, which show both acidic and basic properties,
these oxides are called amphoteric oxides. The classification of elements
which form oxides of acidic or basic properties is shown in Table 1.6.

Table 1.6 Classification of Oxides Based on their Acid and Base
Character

IA IIA IIB IIIA IVA VA VIA VIIA
Li Be B C N O F
Na Mg AI Si P S Cl
K Ca Zn Ga Ge As Se Br
Rb Sr Cd In Sn Sb Te I
Cs Ba Hg TI Pb Bi Po At

BASIC AMPHOTERIC ACIDIC

The oxides of alkali and alkaline earth metals except beryllium are basic
and contain O2- ions. The O2- ion has high affinity for proton and cannot exist
alone in an aqueous solution. Therefore, it immediately takes proton from water
and forms OH- ion. Oxides of nonmetallic elements i.e. of C, N, P and
S are acidic in nature. They generally dissolve in water to produce
acidic solutions. Oxides of relatively less electropositive elements,
such as BeO, Al2O3, Bi2O3 and ZnO are amphoteric and behave as
acids towards strong bases and as bases towards strong acids.

ZnO(s) + H2SO4 (aq) →ZnSO 4
(aq) + H2O (l)

ZnO (s) + 2NaOH (aq) + H2O (l) →
Na [Zn(OH) ]
2 4
(aq)

23
1. Periodic Classification of Elements and Periodicity eLearn.Punjab

In a given period, the oxides progress from strongly basic through weakly
basic,amphoteric, and weakly acidic to strongly acidic, e.g. Na2O, MgO, Al2O3, P4O10
, SO3 , Cl2O7.The basicity of main group metal oxides increases on descending a
group of the periodic table, (e.g. BeO C18H38 Lubrication
and greases
Paraffin M.p. 50 - 60 C23H48 - C29H60 Wax products
Asphalt, or Roofing, paving, fuel
Solids Residue
petroleum coke reducing agent

It is refined to get different petroleum fractions. At present four oil refineries
are in operation in our country. One oil refinery known as Attock Oil Refinery
is located at Morgah near Rawalpindi. It has about 1.25 million tonnes
oil refining capacity. Similarly, two oil refineries have been established at
Karachi which have about 2.13 million tonnes of oil refining capacity. Another
refinery known as Pak-Arab refinery is located at Mahmud Kot near Multan.
8
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

The crude petroleum is separated by fractional distillation into a number
of fractions each corresponding to a particular boiling range, Table 7.1.

7.5 CRACKING OF PETROLEUM

The fractional distillation of petroleum yields only about 20% gasoline.
Due to its high demand this supply is augmented by converting surplus
supplies of less desirable petroleum fractions such as kerosene oil and
gas oil into gasoline by a process called cracking. It is defined as breaking
of higher hydrocarbons having high boiling points into a variety of lower
hydrocarbons, which are more volatile (low boiling). For example, a
higher hydrocarbons CI6H34 splits according to the following reaction.

Heat
C16 H 34 
700o
→ C7 H16 +3CH 2 =CH 2 +CH 3 -CH=CH 2
Alkane

This is the process in which C-C bonds in long chain alkane molecules are
broken, producing smaller molecules of both alkanes and alkenes. The
composition of the products depends on the condition under which the
cracking takes place. Cracking is generally carried out in the following ways.
(1) Thermal Cracking

Breaking down of large molecules by heating at high temperature and
pressure is called Thermal Cracking. It is particularly useful in the
production of unsaturated hydrocarbons such as ethene and propene.

(2) Catalytic Cracking

Higher hydrocarbons can be cracked at lower tem perature (500°C) and
lower pressure (2 atm), in the presence of a suitable catalyst. A typical
catalyst used for this purpose is a mixture of silica (SiO2) and alumina
(AI2O3). Catalytic cracking produces gasoline of higher octane number
and, therefore, this method is used for obtaining better quality gasoline.
9
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

(3) Steam Cracking

In this process, higher hydrocarbons in the vapour phase are mixed with
steam, heated for a short duration to about 900°C and cooled rapidly.
The process is suitable for obtaining lower unsaturated hydrocarbons.

Besides increasing the yield of gasoline, cracking has also produced large
amounts of useful by-products, such as ethene, propene, butene and
benzene. These are used for manufacturing drugs, plastics, detergents,
synthetic fibres, fertilizers, weed killers and important chemicals like ethanol,
phenol and acetone.
7.6 REFORMING

The gasoline fraction present in petroleum is generally not of good quali-
ty. When it burns in an automobile engine, combustion can be initiated
before the spark plug fires. This produces a sharp metallic sound called
knocking which greatly reduces the efficiency of an engine. The quality
of a fuel is indicated by its octane number. As the octane number increas-
es, the engine is less likely to produce knocking. Straight- chain hydrocar-
bons have low octane numbers and make poor fuels. Experiments have
shown that isooctane or 2,2,4- trimethyl pentane burns very smooth-
ly in an engine and has been arbitrarily given an octane number of 100.
The octane number of gasoline is improved by a process called reform-
ing. It involves the conversion of straight chain hydrocarbons into branched
chain by heating in the absence of oxygen and in the presence of a catalyst.

10
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

The octane number of a poor fuel can also be improved by blend-
ing it with a small amount of additive like tetraethyl lead (TEL). Tetraeth-
yl lead (C2H5)4 Pb, is an efficient antiknock agent but has one serious disad-
vantage; its combustion product, lead oxide, is reduced to metallic lead
which is discharged into the air through the exhaust pipe and causes
air pollution.

7.7 CLASSIFICATIONS OF ORGANIC COMPOUNDS

There are millions of organic compounds. It is practically not possi-
ble to study each individual compound. To facilitate their study, or-
ganic compounds are classified into various groups and sub-
groups. They may be broadly classified into the following classes.

1. Open chain or Acyclic compounds.
2. Closed chain or Cyclic (or ring) compounds.
(1) Open Chain or Acyclic Compounds

This type of compounds contain an open chain of carbon atoms.
The chains may be branched or non-branched (straight chain). The
open chain compounds are also called aliphatic compounds.
Straight Chain (or non- branched) Compounds

Those organic compounds in which the carbon atoms are connected in
series from one to the other.

CH 3 -CH 2 -CH 2 -CH 3 H 2C= CH-CH 2 -CH 3 CH 3 -CH 2 -CH 2 -CH 2 -OH
n-Butane 1-Butene 1-Butanol

Branched chain compounds
Those organic compounds in which the carbon atoms are attached on the sides
of chain.

11
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

(2) Closed Chain Compounds or Cyclic Compounds

These compounds contain closed chains or rings of atoms and are known as
cyclic or ring compounds. These are of two types;
(a) Homocyclic or carbocycli compounds
(b) Heterocyclic compounds
The classification of organic compounds into various classes is shown in Fig.
7.1.
(a) Homocyclic or Carbocyclic Compounds

The compounds in which the ring consists of only carbon atoms,
Homocyclic or carbocyclic compounds.
Homocyclic compounds are further classified as :
1. Alicyclic compounds
2. Aromatic compounds

Fig:7.1 Classification of organic compounds.

12
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

(1) Alicyclic Compounds

The homocyclic compounds which contain a ring of three or more
carbon atoms and resembling aliphatic compounds are called alicyclic
compounds. The saturated alicyclic hydrocarbons have the general
formula CnH2n. Typical examples of alicyclic compounds are given below.
One or more hydrogen atoms present in these compounds may be
substituted by other group or groups.

(2) Aromatic Compounds

These carbocyclic compounds contain at least one benzene ring, six carbon
atoms with three alternate double and single bonds.These bonds are usually
shown in the form of a circle. Typical examples of aromatic compounds are
given below.

The aromatic compounds may have a side-chain or a functional group
attached to the ring. For example:

13
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

The aromatic compounds may also contain more than one benzene rings fused
together.

(b) Heterocyclic Compounds

The compounds in which the ring consists of atoms of more than one kind are
called heterocyclic compounds or heterocycles. In heterocyclic compounds
generally one or more atoms of elements such as nitrogen (N), oxygen
(O) or sulphur (S) are present. The atom other than carbon viz, N, 0, or S,
present in the ring is called a hetero atom.

14
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

7.8 FUNCTIONAL GROUP

An atom or a group of atoms or a double bond or a triple bond whose
presence imparts specific properties to organic compounds is called a
functional group, because they are the chemically functional parts
of molecules.
The study of organic chemistry is organized around functional groups.
Each functional group defines an organic family. Although over six mil-
lion organic compounds are known, there are only a handful of func-
tional groups, and each one serves to define a family of organic com-
pounds. The examples of functional groups are outlined in Table 7.2.
TABLE 7.2 FUNCTIONAL GROUPS
Class of compounds
Functional group Example

Formula Name

C C None Alkane CH — CH3

C C Double bond Alkene H2C = CH2

C C Triple bond Alkyne HC=CH
Halo (fluoro, chloro,
-X(X=F,Cl,Br,I) Alkyl halide CH3-CH2-Cl
bromo, iodo)
OH Hydroxyl group Alcohol or alkanol CH3-CH2-OH
NH2 Amino group Amine CH3-CH2-NH2

C NH Imino group Imine CH2=NH

C O C Ether linkage Ether CH3-CH2-O-CH2-CH3

O O
C Formyl group Aldehyde or alkanal CH3-C
H H
R CH3
C O Carbonyl Ketone or alkanohe C O
R CH3

15
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

O O
Carboxylicacid CH3-C
C Carboxyl group
(oralkanoicacid) OH
OH
O
C X Acid halide Acid halide CH3 C Cl

O
C NH2 Acid amide Acid amide CH3 C NH2

O O
R C Ester group Ester CH3-C
OH OCH3

SH Mercapto Thioalcohol or Thiol CH3-CH2-SH

Alkyl cyanide or alkane CH3-C N
C N Cyano
nitrile
O
N Nitro Nitro compounds C6H5NO 2
O

7.9 HYBRIDIZATION OF ORBITALS AND THE SHAPES OF
MOLECULES

Although the most stable electronic configuration of a carbon atom
(having two partially filled 2p orbitals) requires it to be divalent, car-
bon is tetravalent in the majority of its compounds. In order to explain
this apparent anamoly, it is assumed that an electron from the 2s orbit-
al is promoted to an empty 2pz orbital, giving the electronic configuration:

Ground state electronic configuration of carbon = 1s2 2s2 2p1x 2p1y 2p°z
Excited state electronic configuration of carbon = 1s2 2s1 2p1x 2p1y 2p1z

The excited state configuration can explain the tetravalency of carbon but
these four valencies will not be equivalent. Orbital hybridization theory
has been developed to explain the equivalent tetravalency of carbon.

16
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

According to this theory the four atomic orbitals of carbon belonging
to valence shell may be mixed in different ways to explain the
bonding and shapes of molecules formed by carbon atoms.

sp3 Hybridization

In order to explain the bonding and shapes of molecules in which carbon is
attached with four atoms, all these four atomic orbitals are mixed together to
give rise to four new equivalent hybrid atomic orbitals having same shape and
energy. This mode of hybridization is called tetrahedral or sp3 hybridization.

All these four sp3 hybrid orbitals are degenerate (having equal energy) and
are directed at an angle of 109.50 in space to give a tetrahedral geometry.
When a carbon atom forms single bonds with other atoms, these
hybrid orbitals overlap with the orbitals of these atoms to form four
sigma bonds. This type of hybridization explains the bonding and
shapes of all those compounds in which carbon atom is saturated.

x y
z

Fig. 7.2 sp3 hybridization of carbon to give methane (CH4)

17
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

In the formation of methane, the four hybrid atomic orbitals of carbon overlap
separately with four 1s atomic orbitals of hydrogen to form four equivalent
C-H bonds. The shape of methane thus formed is very similar to the actual
methane molecule. All the four hydrogen atoms do not lie in the same plane.

3

109.50

In ethane, CH3 - CH3, the two tetrahedrons of each carbon are joined together
as shown in the above figure. Further addition of a carbon atom with ethane
will mean the attachment of another tetrahedron. At this stage, it is necessary
to answer an important question.From where does the energy come to
excite the carbon atom?
The answer to this question is simple. Before excitation the carbon should
make two covalent bonds releasing an adequate amount of energy. After
excitation, however, it will form four covalent bonds releasing almost double
the amount of energy. This excess energy is more than that needed to excite
the carbon atom. So a tetravalent carbon atom is expected to be more stable
than a divalent carbon atom.

sp2 Hybridization

In order to explain the bonding in unsaturated compounds, two more modes
of hybridization have been developed.

18
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

The structure of alkenes can be explained by sp2 mode of hybridizaton.
In this type one 2s and two 2p orbitals of carbon are mixed together
to give three equivalent and coplanar sp2 hybridized orbitals, Fig. 7.3.

Each sp2 hybrid orbital is directed from the centre of an equilateral triangle
to its three corners. The bond angle between any two sp2 hybrid orbitals is
120°.The unhybridized 2pz orbital will remain perpendicular to the triangle
thus formed.

Fig. 7.3 sp2-hybridization of carbon.

In the formation of ethene molecule, three sp2 orbitals of each carbon atom
overlap separately with sp2 orbital of another carbon and 1s orbitals of two
hydrogen atoms to form three s bonds. This gives rise to what is called the
s-frame work of ethene molecule. The unhybridized orbitals of each carbon
atom will then overlap in a parallel fashion to form a π - bond, Fig. 7.4

19
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

π - bond
Fig. 7.4 Formation of ethene.

sp-Hybridization

The structure of alkynes can be explained by yet another mode of
hybridization called sp hybridization. In this type one 2s and one 2p orbitals
of the carbon atom mix together to give rise to two degenerate sp hybridized
atomic orbitals. These orbitals have a linera shape with a bond angle 180o.

The two unhybridized atomic orbitals, 2py and 2pz are perpendicular to these
sp hybridized orbitals.
Ethyne molecule is formed when two sp hybridized carbon atoms
join together to from a s-bond by sp-sp overlap. The other sp orbital
is utilized to form a s- bond with 1s orbital of hydrogen atom.

20
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

Fig. 7.6 Formation of ethyne

The two unhybridized p orbitals on a carbon atom will overlap separately with
the p orbitals of the other carbon atom to give two π -bonds both perpendicular
to the s -framework of ethyne. The presence of a s and two π bonds
between two carbon atoms is responsible for shortening the bond distance.

7.10 ISOMERISM

The concept of isomerism is an important feature of organic compounds. Two or
more compounds having the same molecular formula but different structural
formulas and properties are said to be isomers and the phenomenon is called isomerism.
The structural formula of a compound shows the arrangement of atoms and bonds
present in it.

The simplest hydrocarbon to have structural isomers is butane (C4H10).
The alkanes, methane, ethane and propane do not show the phenom-
enon of isomerism because each exists in one structural form only. If
we study the structural formula of butane or other higher hydrocar-
bons of the alkane family, we will observe that it is possible to arrange the
atoms present in the molecule in more than one way to satisfy all valencies.
This means that it is possible to have two or more different arrangements for
the same molecular formula.For example, butane molecule can have two dif-
ferent arrangements as represented by the following structural formulas:

21
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

CH 3 -CH 2 -CH 2 -CH 3
n-Butane

Isobutane

This fact has been supported by an experimental evidence that there
are two compounds with different physical properties but with the same
molecular formula of C4H10.
Isomerism is not only possible but common if the compound contains
more than three carbon atoms. As the number of carbon atoms in a
hydrocarbon increases, the number of possible isomers increase very rapidly.
The five carbon compound, pentane, has three isomers. When the number
of carbon atoms increases to thirty, the number of isomers amount to over
four billions.

7.10.1 Types of Isomerism

(1) Structural Isomerism

The structural isomerism is not confined to hydrocarbons only. In
fact, all classes of organic compounds and their derivatives show the
phenomenon of structural isomerism. The structural isomerism arises due
to the difference in the arrangement of atoms within the molecule. The
structural isomerism can be exhibited in five different ways. These are :
(i) The Chain Isomerism.

This type of isomerism arises due to the difference in the nature of the carbon
chain. For example, for pentane (C5H12), the following arrangements are
possible.

22
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

CH 3 -CH 2 -CH 2 -CH 2 -CH 3
n-Pentane

(ii) Position Isomerism.

This type of isomerism arises due to the difference in the position of the
same functional group on the carbon chain. The arrangement of carbon
atoms remains the same. For example,
(a) Chloropropane can have two positional isomers given below.

CH 3 -CH 2 -CH 2 -Cl
1-Chloropropane

(b) Butene (C4H8) can have two positional isomers.

CH 3 -CH 2 -CH=CH 2 CH 3 -CH=CH-CH 3
I-Butene 2-Butene

(iii) Functional Group Isomerism

The compounds having the same molecular formula but different functional
groups are said to exhibit functional group isomerism. For example, there
are two compounds having the same molecular formula C2H6O , but different
arrangement of atoms.

CH 3 -O-CH 3 CH 3 -CH 2 -OH
Diethyl
Dimethyl etherether Eethyl alchohal
Ethyl alcohol

23
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

(iv) Metamerism

This type of isomerism arises due to the unequal distribution of carbon atoms
on either side of the functional group. Such compounds belong to the same
homologous series. For example, diethyl ether and methyl n-propyl ether are
metamers.

CH 3 − CH 2 − O − CH 2 − CH 3 CH 3 − O − CH 2 − CH 2 − CH 3
Diethyl ether Methyl n-propyl ether
For a ketonic compound having the molecular formula C5H10O, the following
two metamers are possible.

(v) Tautomerism

This type of isomerism arises due to shifting of proton from one atom to other
in the same molecule.

(2) Cis-trans Isomerism or Geometric Isomersim

Two carbon atoms joined by a single bond are capable of free rotation about
it. However, when two carbon atoms are joined by a double bond, they
cannot rotate freely. As a result, the relative positions of the various groups
attached to these carbon atoms get fixed and gives rise to cis- trans isomers.

24
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

Such compounds which possess the same structural formula, but differ
with respect to the positions of the identical groups in space are called cis-
trans isomers and the phenomenon is known as the cis-trans or geometric
isomerism.

The necessary and sufficient condition for a compound to exhibit geomet-
ric isomerism is that the two groups attached to the same carbon must be
different.

2-Butene can exist in the form of cis and trans isomers.

Similarly 2-pentene and l-bromo-2-chloropropene also show cis-trans
isomerism.

In the cis-form, the similar groups lie on the same side of the double bond
whereas in the trans-form, the similar groups lie on the opposite sides of the
double bond.
The rotation of two carbon atoms joined by a double bond could happen only
if the π bond breaks.This ordinarily costs too much energy, making geometric
isomers possible.

25
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

KEY POINTS
1. Chemical compounds were classified as organic and inorganic compounds based
upon their origin. Organic compounds are obtained from living things whereas
inorganic compounds are obtained from mineral sources.
2. It was thought that organic compounds could not be synthesized in the laboratory
from inorganic sources.
3. Organic chemistry is now-a-days defined as the chemistry of carbon compounds.
4. Most of the commercially important compounds we use everyday are organic in
nature.
5. Coal, petroleum and natural gas are important sources of organic compounds.
6. The process of cracking is developed to increase the yield of lower hydrocarbons
which serve as important fuels commercially.
7. Organic compounds are classified into acyclic and cyclic compounds.
8. The study of organic chemistry is organized around functional groups. Each
functional group defines an organic family.
9. The type of bonding and the shapes of different type of compounds formed by
carbon can be explained by sp3, sp2 and sp modes of hybridization.
10.Compounds having the same molecular formula but different structural formulas
are called isomers. There are four different type of structural isomers.
11.Isomerism arises due to restricted rotation around a carbon- carbon double bond
is called cis-trans isomerism.

EXERCISE

Q l. Fill in the blanks
i) Organic compounds having same molecular formula but different ______are called
isomers.
ii) The state of hybridization of carbon atom in ______ is sp2.
iii) Alkenes show______ due to restricted rotation around a carbon-carbon double
bond.
iv) Heating an organic compound in the absence of oxygen and in the presence
of________as a catalyst is called cracking.

26
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

v) A group of atoms which confers characteristic properties to an organic
compound is called _________.
vi) 2-Butene is________of 1-butene.
vii) Carbonyl functional group is present in both_________and ketones.
viii) A heterocyclic compound contains an atom other than______ in its ring.
ix) The quality of gasoline can be checked by finding out its_____.
x) A carboxylic acid contains___________ as a functional group.

Q.2 Indicate true or false.
(i) There are three possible isomers forpentane.
(ii) Alkynes do not show the phenomenon of cis-trans isomerism.
(iii) Organic compounds can not be synthesized from inorganic compounds.
(iv) All close chain compounds are aromatic in nature.
(v) The functional group present in amides is called an amino group.
(vi) Government of Pakistan is trying to use coal for power generation.
(vii) Crude petroleum is subjected to fractional sublimation in order to separate
it into different fractions,
(viii) A bond between carbon and hydrogen serves as a functional group for
alkanes.
(ix) o-Nitrotoluene and p-nitrotoluene are the examples of functional group
isomerism.
(x) Almost all the chemical reactions taking place in our body are inorganic
in nature.

Q 3. Multiple choice questions. Encircle the correct answer.
(i) The state of hybridization of carbon atom in methane is:
(a) sp3 (b) sp2 (c) sp (d) dsp2

(ii) In t-butyl alcohol, the tertiary carbon is bonded to:
(a) two hydrogen atoms (b) three hydrogen atoms
(c) one hydrogen atom (d) no hydrogen atom

(iii) Which set of hybrid orbitals has planar triangular shape.
(a) sp3 (b) sp (c) sp2 (d) dsp2

(iv) The chemist who synthesized urea from ammonium cyanate was:
(a) Berzelius (b)Kolbe (c) Wholer (d) Lavoisier
27
7. Fundamental Principles of Organic Chemistry eLearn.Punjab

(v) Linear shape is associated with which set of hybrid orbitals?
(a) sp (b) sp2 (c) sp3 (d) dsp2

(vi) A double bond consists of:
(a) two sigma bonds (b) one sigma and one pi bond
(c) one sigma and two pi bonds (d) two pi bond

(vii) Ethers show the phenonenom of:
(a) position isomerism (b) functional group isomerism
(c) metamerism (d) cis-trans isomerism

(viii) Select From the following the one which is alcohol:
(a) CH3-CH2-OH (b) CH3-O-CH3
(c) CH3COOH (d) CH3-CH2-Br

Q 4. How organic compounds are classified? Give suitable example of each type.
Q 5. What are homocyclic and heterocyclic compounds? Give one example of
each.
Q 6. Write the structural formulas of the two possible isomers of C4H10.
Q 7. Why is ethene an important industrial chemical?
Q 8. What is meant by a functional group? Name typical functional groups
containing oxygen.
Q 9. What is an organic compound? Explain the importance of Wohler’s work in
the developrnent of organic chemistry.
Q 10. Write a short note on cracking of hydrocarbons.
Q 11. Explain reforming of petroleum with the help of suitable example.
Q 12. Describe important sources of organic compounds.
Q13. What is orbital hybridization? Explain sp3 sp2 and sp modes of hybridization
of carbon.
Q14. Explain the type of bonds and shapes of the following molecules using
hybridization approach.
CH3 - CH3, CH2 = CH2, CH = CH, HCHO, CH3CI
Q 15. Why there is no free rotation around a double bond and a free rotation
around a single bond ? Discuss cis-trans isomerism.

28
CHAPTER

8 ALIPHATIC
HYDROCARBONS

Animation 8.1 : Cycloalkanes
Source and credit : Stackexchange
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

In This Chapter You Will Learn:
1. How to name the aliphatic hydrocarbons according to IUPAC
rules.
2. The synthesis of alkanes, alkenes and alkynes and their important
reactions.
3. The comparison of reactivity of s bond and p bond.
4. About the free radical nature of reactions of alkanes and electrophilic
addition of alkenes and alkynes.
5. The comparison of reactivities of alkanes, alkenes and alkynes.

8.1 INTRODUCTION

Hydrocarbons are organic compounds which contain carbon and hydro-
gen only. The number of such compounds is very large because of the prop-
erty of catenation. Hydrocarbons have been divided into various class-
es on the basis of structure of the chain or size and nature of the ring.

2
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

If all the valencies of the carbon atoms in a molecule are fully satisfied and
these cannot further take up any more hydrogen atoms, then the
hydrocarbons are named as saturated hydrocarbons or alkanes.
The compounds of carbon and hydrogen in which all the four valen-
cies of carbon are not fully utilized and they contain either a double or
a triple bond, such compounds are called unsaturated hydrocarbons.
Those unsaturated hydrocarbons which contain a double bond are
called alkenes while those containing a triple bond are called alkynes.
Classification of hydrocarbons has been’ shown at page 136.

8.2 NOMENCLATURE

8.2.1 Common or Trivial Names:

In the early days, the compounds were named on the basis of their history,
the method of preparation or name of the person working on it, e.g., the name
marsh gas was given to methane because it was found in marshy places.
Acetic acid derives its name from vinegar (Latin, acetum means vinegar).
Organic compounds were named after a person, like barbituric acid after
Barbara. Such a system may have a certain charm but is never manageable.
For alkanes with five or more carbon atoms, the root word is derived from
the Greek or Latin numerals indicating the number of carbon atoms in
a molecule, and the name is completed by adding ‘ane’ as a suffix, e.g.
pentane (C5H12), hexane (C6H14), heptane (C7H16), etc. The common or
trivial names are applicable to all isomers of a given molecular formula.
The prefixes n, iso, neo are, however, to differentiate between isomers.

3
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

CH3 CH2 CH2 CH3 H3C CH CH3
|

n-butane CH3
Isobutane

CH3 CH2 CH2 CH2 CH3
n-pentane

CH3
|
H3C CH CH2 CH3 H3C C CH3
| |

CH3 CH3
Isopentane Neophentane

These prefixes have only limited use, as they are not workable with
complex molecules. Moreover, common names give only minimum
information about the structure of the compounds.Alkenes are similarly
named by replacing the ending -ane of the name of alkane with ylene. e.g.

CH3
|
H3C C=CH2
H2C=CH2 H3C CH =CH2
Ethylene Propylene Isobutylene

4
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

8.2.2 IUPAC Names
In 1889 the solution for naming the organic compounds systematically
was sought by International Chemical Congress. A report was accepted in
1892 in Geneva but it was found incomplete. In 1930, International Union of
Chemistry (IUC) gave a modified report which is also referred as Liege Rules.
This report was further modified by International union of Pure and
Applied Chemists (IUPAC) in the year 1947. Since that date the union
has issued periodic reports on rules for the systematic nomenclature of
organic compounds, the most recent of which was published in the year
1979. IUPAC system of nomenclature is based on the following principle.
‘Each different compound should have a different name’.
Thus through a systematic set of rules, the IUPAC system provides
different names for more than 7 million known organic compounds.

Nomenclature of Alkyl Groups:
If we remove one hydrogen atom from an alkane, we obtain what is
called an alkyl group. These alkyl groups have names that end in —
yl.When the alkane is unbranched and the hydrogen atom that is
removed is a terminal hydrogen atom, the names are straight forward:

Alkane Alkyl Group Abbreviation
CH3 H CH3 Me-
Methane Methyl
Et-
CH3 CH2 H CH3CH2

Ethane Ethyl
Pr-
CH3 CH2 CH2 H CH3CH2CH2

Propane n-propyl
n-Bu-
CH3 CH2 CH2 CH2 H CH3CH2CH2CH2

n-Butane n-Butyl

5
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

8.2.3 Nomenclature of Alkanes
Branched-chain alkanes are named according to the following rules.

1. Locate the longest continuous chain of carbon atoms; this chain determines
the parent name for the alkane. We designate the following compound as
a hexane because the longest continuous chain contains six carbon atoms.

H3C CH2 CH2 CH2 CH CH3
|

CH3
The longest continuous chain may not always be obvious from the way the
formula is written. Notice, for example, that the following alkane is designated
as a heptane because the longest chain contains seven carbon atoms.

2.Number the longest chain beginning from the end of the chain nearer the
substituent. Applying this rule, we number the two alkanes shown above in
the following way.

6
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

3.Use the numbers obtained by the application of rule 2 to designate the
location of the substituent group. The parent name is placed last, and the
substituent group, preceded by the number designating its location on
the chain, is placed first. Numbers are separated from words by a hyphen.
The systematic names ot the two compounds shown above will then be:

4. When two or more substituents are present, give each substituent a number
corresponding to its location on the longest chain. For example, we designate
the following compound as 4 -ethyl-2 -methylhexane.

The substituent groups should be listed alphabetically (i.e. ethyl before methyl).
In deciding on alphabetical order disregard multiplying prefixes such as “di”
and “tri”.
5. When two substituents are present on the same carbon atom, use that
number twice.

7
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

6.When two or more substituents are identical, indicate this by the use of the
prefixes di, tri , tetra , and so on. Then make certain that each and every substituent
has a number. Commas are used to separate numbers from each other.

Application of these six rules allows us to name most of the alkanes that we
shall encounter. Two other rules, however, may be required occasionally.

7.When two chains of equal length compete for selection as the parent chain,
choose the chain with the greater number of substituents.

8
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

8. When branching first occurs at an equal distance from either end of the
longest chain, choose the name that gives the lower number at the first point of
difference.

8.2.4 Nomenclature of Alkenes:
The IUPAC rules for naming alkenes are similar in many respects to those for naming
alkanes.

1.Select the longest continuous chain that contains the C = C as the parent
chain. Change the ending of the name of the alkane of identical length
from — ane to — ene, e.g.,

2.Number the chain so as to include both carbon atoms of the double
bond. Numbering begins from the end nearer to the double bond.

9
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

3.Designate the location of the double bond by using the number of the first
atom of the double bond as a prefix.

1 2 3 4 5
1 2 3 4
H2 C = CH CH2 CH3 H2 C = CH CH2 CH2 CH3
1-Pentene
1-Butene
4.Indicate the locations of the substituent groups by the numbers of the
carbon atoms to which they are attached.

5.If the parent chain contains more than one double bonds, they are alkadienes
for two, alkatrienes for three and so on.

1 2 3 4
= =
CH2 CH CH CH2
1,3-Butadiene

8.2.5 Nomenclature of Alkynes:

1.The largest continuous carbon chain containing triple bond is selected.
The name of the identical alkane is changed from ane to — yne. e.g.

2 1 3 2 1
CH ≡ CH H3 C C ≡ CH
Ethyne
Propyne
10
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

2.The position of triple bond is shown by numbering the alkyne, so that minimum
number is assigned to the triple bond.

4 3 2 1
H3 C CH2 C ≡ CH
1-Butyne

3.If a hydrocarbon contains more than one triple bonds, it is named as
alkadiyne and triyne, etc. depending on the number of triple bonds.

6 5 4 3 2 1
HC ≡ C CH2 CH2 C ≡ CH

1,5 - Hexadiyne
4.If both double and triple bonds are present in the compound then ending
enyne is given to the root.

a.Lowest possible number is assigned to a double or a triple bond irrespective
of whether ene or yne gets the lower number.

1 2 3 4 5 1 2 3 4 5
HC ≡ C CH=CH CH3 =
H2 C CH C=
≡ C CH3
3 - Penten - 1- yne 1- Penten - 3 - yne
b.In case a double and a triple bond are present at identical positions, the double
bond is given the lower number.

11
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

8.3 ALKANES OR PARAFFINS

Alkanes are the simplest organic compounds made up of carbon and
hydrogen only. They have a general formula of CnH2n+2. In these compounds
the four valencies of carbon atoms are satisfied by single bonds to either other
carbon atoms or hydrogen atom. They are, therefore known as Saturated
Hydrocarbons. Methane (CH4) is the simplest member of this family. Each
carbon atom in alkane is sp3 hybridized and has a tetrahedral geometry.
8.3.1 General Methods of Preparations
(1) Hydrogenation of Unsaturated Hydrocarbons
(Sabatier-Sendem’s Reaction)

Hydrogenation of alkenes or alkynes in the presence of nickel at 200-300OC
yields alkanes.

R CH = CH2 + H2  Ni
200−300o C
→ R CH2 CH3

Alkene

e.g CH2 = CH2 + H2  Ni
200−300o C
→ CH3 CH3

Ethane
The hydrogenation can also be carried out with platinum or
palladium at room temperature but they are expensive than nickel.
The method is of industrial importance. Production of vegetable ghee
by the catalytic hydrogenation of vegetable oil (unsaturated fatty acids)
is an example of the application of this method on industrial scale.
(2) From Alkyl Halides:
An alkane is produced when an alkyl halide reacts with zinc in the
presence of an aqueous acid.

12
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

R X + Zn + H+ + X − 
→ R H + ZnX 2
Alkyl halide Alkane

CH3 I + Zn + H+ + I− 
→ CH4 + ZnI2
Methyl iodide Methane

CH3 CH2 CH CH3
|

Br + Zn + H+ + Br − 
→ CH3 CH2 CH2 CH3 + ZnBr
2-Bromo-butane n-Butane

Alkanes can also be prepared from alkyl halides using palladium-charcoal
as acatalyst. The method is known as Hydrogenolysis (hydrogenation
accompanied by bond cleavage)

R X + H2 
Pd/C
∆
→R H+H X
(3) Decarboxylation of Monocarboxylic Acids
i) When sodium salts of fatty acids are heated with soda-lime (prepared
by soaking quick lime (CaO) with caustic soda solution and drying
the product). They eliminate a molecule of CO2 to form alkanes.

e.g

13
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

ii) Kolbe's Electrolytic Method
When a concentrated solution of sodium or potassium salt of a mono
carboxylic acid is electrolysed, an alkane is produced. This method
is only suitable for the preparation of symmetrical alkanes i.e. those
of the type R—R. Methane cannot be prepared by this method.

2RCOO−Na + + 2 H2O 
Electrolysis
→R R+2CO2 + 2NaOH+H2
It is known to involve the following mechanism.
When potassium salt of acetic acid is electrolysed, acetate ion migrates.
towards the anode gives up one electron to produce acetate free.
radical (CH3COO), which decomposes to give a methyl free radical
(CH3) and CO2.Two such methyl radicals combine to give ethane.

At Anode

O
||
2H3C C O   + 2CO
→ 2CH3 2

 + CH
CH  → H3C CH3
3 3
At Cathode

2H2O + 2e− 
→ 2OH + H2

2K + + 2OH 
→ 2KOH
This reaction has limited synthetic applications as it forms a number of side
products.
14
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

(4) From Carbonyl Compounds (Aldehydes or Ketones)

The carbonyl groups of aldehydes or ketones are reduced to methyl or
methylene group respectively by either Clemmensen or Wolf-Kishner’s
reduction. In the former reaction a ketone is reduced to an alkane
using zinc amalgam and hydrochloric acid whereas in the later an
aldehyde is reduced to alkane with hydrazine in the presence of KOH.

3
Acetone Propane

(5) From Grignard Reagents
Alkyl halides react in anhydrous ether with magnesium to
form alkyl magnesium halides, known as Grignard Reagent.
They decompose on treatment with water or dilute acid to give alkanes.

ether

15
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

8.3.2. Physical Properties
1. Alkanes containing upto four carbon atoms are colourless, odourless gases
while pentane to heptadecane (C5 to C17) are colourless, odourless liquids. The
higher members from C18 onwards are waxy solids which are also colourless and
odourless.
2. Alkanes are non-polar or very weakly polar and are insoluble in polar solvents
like water, but soluble in non-polar solvents like benzene, ether, carbon tetra
chloride,etc.
3. Their physical constants like boiling.points, melting points, density, etc increase
with the increase in number of carbon atoms, whereas solubility decreases
with increase in molecular mass. The boiling point increases by 20 to 30°C
for addition of each CH2 group to the molecule. The boiling points of alkanes
having branched chain structures are lower than their isomeric normal chain
alkanes, e.g. n-butane has a higher boiling point-0.50 C than isobutane (-1 1.7°C).
4.The melting points of alkanes also increase with the increase in molecular mass
but this increase is not so regular.

8.3.3. Reactivity of Alkanes
The alkanes or paraffins (Latin: parum = little, affins = affinity) under ordinary
condition are inert towards acids, alkalis, oxidizing and reducing agents.
However, under suitable conditions, alkanes do undergo two types of reactions.
1. Substitution Reactions
2. Thermal and Catalytic Reactions

These reactions take place at high temperature or on absorption of
light energy through the formation of highly reactive free radicals.

The unreactivity of alkanes under normal conditions may be explained on the
basis of the non-polarity of the bonds forming them. The eletronegativity values
of carbon (2.5) and hydrogen (2.1) do not differ appreciably and the bonding
electrons between C-H and C-C are equally shared making them almost non-
polar. In view of this, the ionic reagents such as acids, alkalies, oxidizing agents,
etc find no reaction site in the alkane molecules to which they could be attached.

16
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

Inertness of s-bond
The unreactivity of alkanes can also be explained on the basis of inertness of a
s-bond. In a s -bond the electrons are very tightly held between the nuclei which
makes it a very stable bond. A lot of energy is required to break it. Moreover
the electrons present in a s-bond can neither attack on any electrophile nor a
nucleophile can attack on them. Both these facts make alkanes less reactive.

8.3.4 Reactions

1. Combustion
Burning of an alkane in the presence of oxygen is known as Combustion.
Complete combustion of an alkane yields CO2, H2O and heat.

The amount of heat evolved when one mole of a hydrocarbon is burnt to
CO2 and H2O is called heat of combustion, e.g;

CH4 ( g ) + 2O2 ( g ) 
Flame
→ CO2 ( g ) + 2H2O ( g ) + 891kJmol-1
Although the reaction is highly exothermic, it requires very
high temperature to initiate it, e.g. by a flame or a spark.
Combustion is the major reaction occurring in the internal combustion
engines of automobiles. A compressed mixture of alkanes and air burns
smoothly in the internal combustion engine and increases its efficiency.

2. Oxidation
Oxidation of methane under different conditions gives different products.
i) Incomplete oxidation occurs in a limited supply of oxygen
or air and results in the formation of CO and carbon black.

3CH4 ( g )+ 4O2 ( g ) 
Flame
→ 2CO ( g ) + 6H2O ( g ) + C ( s )

17
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

ii) Catalytic Oxidation: Lower alkanes when burnt in the presence of metallic
catalysts, at high temperature and pressure, result in the formation of useful
products.

CH4 + [O] 
→ H3C Cu
400o C/200atm
OH
Methyl alcohol
H3C OH + O  Cu
400o C/200atm
→ HCHO+H2O

Formaldehyde

HCHO + [O]  Cu
400o C/200atm
→ HCOOH
Formic acid
HCOOH + [O] 
→ CO2 + H2O Cu
400o C/200atm

Catalytic oxidation of alkanes is used industrially to prepare
higher fatty acids used in soap and vegetable oil industries.

3. Nitration:

It is a substitution reaction of alkanes in which a hydrogen atom of an
alkane is replaced by nitro group (-NO2). Alkanes undergo vapour-phase
nitration under drastic condition (at 400-500°C) to give nitroalkanes, e.g.

450o C
CH4 + HONO2 
→ CH3NO2 + H2O
Nitromethane
Nitroalkanes generally find use as fuels, solvents, and in organic synthesis.

18
8. ALIPHATIC HYDROCARBONS eLearn.Punjab

4. Halogenation
Alkanes react with chlorine and bromine in the presence of sunlight
or UV light or at high temperature resulting in the successive
replacement of hydrogen atoms with halogens called halogenation.
Extent of halogenation depends upon the amount of halogen used.
Reaction of alkanes with fluorine is highly violent and results in
a mixture of carbon, fluorinated alkanes and hydrofluoriq acid.
Iodine does not substitute directly because the reaction is too slow
and reversible. The order of reactivity of halogens is F2>Cl2>Br2>I2.
Halogenation is believed to proceed through free radical mechanism.
It involves the following three steps.

hυ )Initiation(
Step I Cl Cl  → Cl − + Cl −

]
hυ
Step 2 H3C H + Cl
 → CH
3 + HCl )Propagation(
hυ
CH
3 + Cl Cl  → CH3 Cl + Cl

)Termination(
Step 3 CH
3 + Cl

→ CH3 Cl

By repetition of step II, a mi