CBSE CLASS 11TH CHEMISTRY
CHAPTER-3
CLASSIFICATION OF ELEMENTS AND PERIODICITY IN PROPERTIES OF ELEMENTS
CHAPTER-3
CLASSIFICATION OF
ELEMENTS AND PERIODICITY IN PROPERTIES OF ELEMENTS
Mandeleev’s
Periodic Law:- The properties of the elements are
the periodic function of their atomic masses.
Moseley, the English physicist showed that
atomic number is more fundamental property of an element than its atomic mass.
Therefore, the position of an element in the periodic table depends on its
atomic number than its atomic mass.
Modern
Periodic Law: The physical and chemical properties
of elements are the periodic functions of their atomic numbers.
Types
of Elements: s-, p-, d- and f- blocks.
MAIN GROUP ELEMENTS/ REPRESENTATIVE ELEMENTS:
The s- and p- block elements are called
main group elements or representative elements.
s-
block elements: Group-1 (Alkali metals) and Group-2
elements (Alkaline earth metals) which respectively have ns1 and ns2
outermost electronic configurations.
p-
Block elements: They belongs to group- 13 to 18. The outer most
electronic configuration is ns2 np1-6. He (1s2)
is a s- block element but is positioned with the group 18 elements (ns2
np6) because it has completely filled valence shell and as a result,
exhibits properties characteristic of other noble gases.
d-
block elements (Transition elements) are the
elements of group 3 to 12 having outer electronic configuration (n-1) d1-10
ns1-2. Four transition series are 3d, 4d, 5d and 6d. The 6d- series
is incomplete. Atomic radius generally decreases across a period and increases
as we descend the group.
f-Block elements (Inner- transition Series)
Lanthanoids charecterised by the filling
of4 f-orbitals, are the elements following lanthanum from 58Ce to 71Lu.
Actinoids characterised by filling of 5f-orbitals, are the elements following
actinium from 70Th to 103Lr. Characteristic
outer electronic configuration is (n-2) f1-14 (n-1) d0-1
ns2.
Noble
Gases: The gaseous elements of group 18 are called
noble gases. The general outermost electronic configuration of noble gases
(except He) is ns2 np6. He exceptionally has 1s2
configuration. Thus the outermost shell of noble gases is completely
filled.
PERIODICITY:
The repetition of similar properties after regular
intervals is called periodicity.
Cause
of Periodicity: The properties of elements are the
periodic repetition of similar electronic configuration of elements as the
atomic number increases.
ATOMIC
PROPERTIES: The physical characteristics of the
atom of an element are called atomic properties. The properties such as atomic
radius, ionic radius, ionisation energy, electro-negativity, electron affinity
and valence etc., called atomic properties.
ATOMIC
RADIUS- The distance from the centre of the nucleus
to the outermost shell of the electrons in the atom of any element is called
its atomic radius.
 |
Periodicity- (a) In period- Atomic radius of elements decreases from left to right in a period.
(b) In Group- Atomic radius of elements
increases on moving top to bottom in a group.
COVALENT
RADIUS- Half the inter-nuclear distance between two
similar atoms of any element which are covalently bonded to each other by a
single covalent bond is called covalent radius.
VAN
DER WAALS’ RADIUS: Half the inter-nuclear
separation between two similar adjacent atoms belonging to the two neighbouring
molecules of the same substance in the solid state is called the van der
waals’radius of that atom.
METALLIC
RADIUS: Half the distance between the nuclei of the
two adjacent metal atoms in a close packed lattice of the metal is called its
metallic radius.
Van der Waals’radius > Metallic radius > Covalent radius
IONIC
RADIUS: The effective distance from the centre of
the nucleus of an ion upto which it has an influence on its electron cloud is
called its ionic radius.
A cation is smaller but the anion is
larger than the parent atom. In case of isoelectronic species, the cation with
greater positive charge has smaller radius but anion with greater negative
charge has the larger radii.
IONISATION
ENTHALPY: The ionisation enthalpy is the molar
enthalpy change accompanying the removal of an electron from a gaseous phase
atom or ion in its ground state. Thus enthalpy change for the reaction; M(g)→ M+(g)
+ e-
Is the ionisation enthalpy of the element
M. Like ionisation energies for successive ionisation, the successive
ionisation enthalpy may also be termed as 2nd ionisation enthalpy (∆rH2),
third ionisation enthalpy (∆rH3)
etc. The term ionisation enthalpy is taken for the first ionisation enthalpy,
(∆rH1) is expressed in kg mol- or in eV.
Periodicity:
i)
Generally the ionisation enthalpies follow the order (
there are few exceptions):
(∆rH1) <
(∆rH2) < (∆rH3) ii)
The ionisation enthalpy decreases on moving top to
bottom in a group.
|
iii) The ionisation enthalpy increases on moving from left to right in a period.
ELECTRON
GAIN ENTHALPY: The electron gain enthalpy ((∆egH)
is the molar enthalpy change when an isolated gaseous atom or ion in its ground
state adds an electron to form the corresponding anion thus the enthalpy change
for the reaction; X(g) + e-
→ X-(g)
Is called the electron gain enthalpy (∆eg
H) of the element X. The∆eg H may be positive or negative.
The successive values for the addition of
second, third etc. Electron, these are called second, third etc. electron gain
enthalpies. For example,
|
X(g) + enthalpy |
e- |
→ |
X-(g) |
∆H= ∆eg H1 is called first electron gain |
|
X-(g) + enthalpy |
e- |
→ |
X2-(g) |
∆H= ∆eg H2
is called second electron gain |
|
X2-(g) + |
e- |
→ |
X3-(g) |
∆H= ∆eg H3 is called third electron gain |
enthalpy Usually the term electron gain
enthalpy (∆egH) means the first electron gain enthalpy.
Periodicity:
(i) In period- The electron gain enthalpy increases from left to right
in a period.
(ii) In group- The electron gain enthalpy decreases from top to bottom in
a group.
ELECTRONEGATIVITY:
“The relative tendency of an atom in a molecule to
attract the shared pair of electrons towards itself is termed as its
electronegativity.”
Periodicity:
(i) In period- The electro-negativity increases from left to right in a
period.
(ii) In group- The electro-negativity decreases from top to bottom in a
group.
VALENCE
ELECTRONS: The electrons present in outermost shell
are called as valence electron. Because the electrons in the outermost shell
determine the valency of an element.
 |
VALENCY OF AN ELEMENT: The number of hydrogen or halogen atom or double the number of oxygen atom, which combin with one atom of the element is taken as its valency. According to the electronic concept of valency, “ the number of electrons which an atom loses or gains or shares with other atom to attain the noble gas configuration is termed as its valency.” Periodicity:
(i) In period- The valency first increases then decreases from left to
right in a period.
(ii) In group- The valency remains constant from top to bottom in a
group.
ELECTROPOSITIVE OR METALLIC CHARACTER: The
tendency of an
element to lose electrons and forms
positive ions (cations) is called electropositive or metallic character. The
elements having lower ionisation energies have higher tendency to lose
electrons, thus they are electropositive or metallic in their behaviour.
Alkali metals are the most highly
electropositive elements.
Periodicity:
In period- The electropositive or metallic
characters decreases from left to right in a period.
In group- The electropositive or metallic
characters increases from top to bottom in a group.
ELECTRO-NEGATIVE OR NON- METALLIC CHARACTERS: the
tendency of an element to accept electrons
to form an anion is called its non metallic or electronegative character. The
elements having high electro-negativity have higher tendency to gain electrons
and forms anion. So, the elements in the upper right hand portion of the
periodic table are electro-negative or non-metallic in nature.
Periodicity:
(i) In period- The electro-negative or non- metallic characters
increases from left to right in a period.
(ii) In group- The electro-negative or non-metallic characters decreases
from top to bottom in a group.
REACTIVITY OF METALS:
Periodicity:
(i)
|
In period- The tendency of an element to lose electrons decreases in a period. So the reactivity of metals decreases from left to right in a period.
(ii) In group- The tendency of an element to lose electrons increases in
a period. So the reactivity of metals
increases from top to bottom in a group.
REACTIVITY OF NON- METALS:
(i) In period- The tendency of an element to gain electrons increases in
a period. So the reactivity of
non-metals increases from left to right in a period.
(ii) In group- The tendency of an element to gain electrons decreases in
a group. So the reactivity of
non-metals increases from top to bottom in a group.
SOLUBILITY OF ALKALI METALS CARBONATES AND BICARBONATES:
PERIODICITY
IN GROUP: The solubility of alkali metal carbonates
and bicarbonates in water increases down the group (From Lithium to Caesium).
SOLUBILITY OF ALKALINE EARTH METAL HYDROXIDES AND SULPHATES:
PERIODICITY
IN GROUP: The solubility of alkaline earth metal
hydroxide and sulphates in water increases down the group (From Beryllium to
Barium).
BASIC STRENGTH OF ALKALINE EARTH METAL HYDROXIDES:
PERIODICITY
IN GROUP: The basic strength of alkaline earth
metal hydroxide in water increases down the group (From Beryllium to Barium),
i.e.,
Be(OH)2 <
Mg(OH)2 < Ca(OH)2 <
Sr(OH)2 < Ba(OH)2
Basic strength increases
THERMAL STABILITY OF CARBONATES OF ALKALI AND ALKALINE EARTH METALS:
Except lithium carbonate, (LiCO3),
the carbonates of all other alkali metals are stable towards heat, i.e.,
carbonates of alkali metals (except LiCO3) do not decompose on
heating. LiCO3 decomposes on heating to give lithium oxide (LiCO3).
The carbonates of alkaline earth metals
are relatively less stable. On heating, they decompose to give corresponding
oxide and CO2 gas. The decomposition temperature for alkaline earth
metal carbonates increases as we go down the group.
Anomalous Properties of Second Period Elements
Their anomalous behaviour is attributed to
their small size, large charge/radius ratio, high electro negativity, non-
availability of d- orbitals in their valence shell. the first member of each
group of p-Block elements displays greater ability to form pp-pp multiple bonds
to itself (e.g. C=C, C≡C O=O, N≡N) and to other second period elements (e.g.
C=O, C≡N, N=O) compared to subsequent member of the group.
ONE MARK QUESTIONS
Q1. Select the species which are
iso-electronic (same number of electron) with each other.
(1) Ne (2)
Cl- (3)
Ca2+ (4) Rb+
Ans-The
Cl- and Ca2+. Both have 18 e_
each.
Q.2.
What the elements of a group have common among them?
Ans- They have same number of electrons in
the valence shell.
Q.3. What the s- and p- block elements are
collectively called?
Ans- Representative
elements. Q.4. Define atomic radius.
 |
Ans- The one-half the distance between the nuclei of two covalently bonded atoms of the same element in a molecule is called as atomic radius. Q.5. State the modern periodic law.
Ans- The physical and chemical properties
of the elements are the periodic function of their atomic numbers.
Q.6. Name the groups of elements
classified as s-, p- and d- blocks.
Ans- s- block= 1,2 (including He), p-
block= 13 to 18 (except He), d- block= 3 to 12.
Q.7. Define the term ionisation enthalpy.
Ans- The energy required to remove the
outer most electron from the valence shell of an isolated gaseous atom is called as ionisation
enthalpy.
Q.
8.In how many groups and periods
the elements in modern periodic table are classified?
Ans- In 18 groups and 7 periods.
Q.9. What do you mean by electronic
configuration of the elements?
Ans- The systematic distribution of the
electrons among the orbitals of an atom of an element according to increasing
order of their energies is called as electronic configuration of that element.
TWO MARKS QUESTIONS
Q.1.
Describe the two merits of long
form periodic table over the Mendeleev’s periodic table?
Ans- 1. It removed the anomalies about the
position of isotopes which existed in the Mendeleev’s table.
2. It relates the position of an element in the periodic table with its
electronic configuration.
Q.2.
What is a period in the
periodic table? How do atomic sizes change in a period with an increase in
atomic number?
Ans- The horizontal rows in periodic table
are called as periods. The atomic sizes decrease in a period with an increase
in atomic number.
Q.3.
The outer electronic
configuration of some elements are:
(a) 3s2 3p4 (b)
3d104s2 (c) 3s2 3p6 4s2 (d) 6s2 4f3
To which block of elements in the periodic table each
of these belongs?
Ans- (a) p- Block (b) d- Block (c) s-
Block (d) f- Block
Q.4.
What is meant by periodicity in
properties of elements? What is the reason behind this?
Ans- The repetition of similar properties
after regular intervals is called as periodicity. It is due to the similarity
in the outer electronic configurations which gives rise to the periodic
properties of the elements.
Q.5.
How do atomic radii vary in a
group and a period?
Ans-
In group- Atomic size increases on moving from top to bottom.
In
period- Atomic size decreases on moving left to right in a period. Q.6. Arrange
the following in the order of increasing radii:
(a) I, I+, I- (b)
F, Cl, Br
Ans- (a) I+ < I < I+
(b) O < N< P
Q.7. Name the factors which affect the
ionisation enthalpy of an element.
Ans- (i) Size of atom or ion (ii) Nuclear charge (iii) Electronic
configuration
(iv) Screening effect (v)
Penetration effect of the electrons
Q.8.
How does ionisation enthalpy vary
in a group and a period?
Ans- In Period- It increases from left to
right In
group- It decreases down the group.
Q.9.
Noble gases have zero electron gain
enthalpy values. Explain.
Ans- Because the outer most shell of noble
gases is completely filled and no more electrons can be added.
Q.10. Elements in the same group have equal valency. Comment on it.
Ans- Because the general outer most
electronic configurations of the elements of a group remain same and they
contain equal number of electrons in their respective outer most shells.
THREE
MARKS QUESTIONS
Q.1. The
first ionisation enthalpy of magnesium is higher than that of sodium. On the
other hand, the second ionisation enthalpy of sodium is very much higher than
that of magnesium. Explain.
Ans- The 1st ionisation
enthalpy of magnesium is higher than that of Na due to higher nuclear charge
and slightly smaller atomic radius of Mg than Na. After the loss of first
electron, Na+ formed has the electronic configuration of neon (2,8).
The higher stability of the completely filled noble gas configuration leads to
very high second ionisation enthalpy for sodium. On the other hand, Mg+
formed after losing first electron still has one more electron in its outermost
(3s) orbital. As a result, the second ionisation enthalpy of magnesium is much
smaller than that of sodium.
Q.2.
What are the major differences between metals and
non- metals? Ans-
|
Property |
Metal |
Non- Metal |
|
Nature |
Electropositive |
Electronegative |
|
Type of ion formed |
Cation (Positively Charged) |
Anion (Negatively Charged) |
|
Reaction with acids |
Active metals displace hydrogen |
Do not displace hydrogen |
|
Oxides |
Basic |
Acidic |
Q.3. Among the
elements of the second period Li to Ne pick out the element: (i) with the
highest first ionisation energy(ii) with the highest electronegativity (iii)
with the largest atomic radius Give the reason for your choice.
Ans- (i) The ionisation energy increases
on going from left to right. Therefore, the element with the highest ionisation
energy is Ne.
(ii)
The electro negativity is
electron- accepting tendency. This increases on going from left to right and
decreases down the group. Therefore, the element with the highest electro-
negativity is F.
(iii)
The atomic radius decreases
across a period on going from left to right. Thus, the first element of any period should have the largest atomic
radii. Here, Li has the largest atomic radii.
Q.4. Arrange the following as stated:
(i)
N2, O2, F2,
Cl2 (Increasing order of bond dissociation energy)
(ii)
F, Cl, Br, I (Increasing order of electron gain enthalpy)
(iii)
F2, N2,
Cl2, O2
(Increasing order of bond length)
|
Ans- (i) F2 |
< |
Cl2
|
< |
O2 |
< |
N2 |
|
(ii) I |
< |
Br |
< |
F |
< |
Cl |
|
(iii) N2 |
< |
O2
|
< |
F2 |
< |
Cl2 |
Q.5. Why does the first ionisation enthalpy increase as we go from left
to right through a given period of the periodic table?
Ans- In a period, the nuclear charge (the
number of protons) increases on going from left to right. The electron added to
each element from left to right enters the same shell. This results in an
increase of the effective nuclear charge across the period on moving from left
to right. As a result, the electron get more firmly bound to the nucleus. This
causes an increase in the first ionisation enthalpy across the period.
Q.6. Use the periodic table to answer the following questions.
(i)
Identify the element with five
electrons in the outer sub-shell.
(ii)
Identify an element that would tend
to lose two electrons.
(iii) Identify
an element that would tend to gain two electrons.
Ans- (i) Chlorine (ii) Magnesium (iii)
Oxygen
Q.7. Explain why are cations smaller and
anions larger in size than their parent atoms?
Ans- (a) The cations are smaller than their parent atoms due to the
following reasons:
(i)
Disappearance of the valence
shell.
(ii) Increase of effective nuclear charge
(b) The anions are larger than their
parent atoms due to the following reason:
An increase in the number of electrons
in the valence shell reduces the effective nuclear charge due to greater mutual shielding by the
electrons. As a result, electron cloud
expands, i.e., the ionic radius increases.
Q.8. Describe the theory associated with the radius
of an atom as it
(a) gains an electron (b) loses an electron
Ans- (a) When an atom gains an electron, its size
increases. When an electron is added, the number of electrons goes up by one.
This results in an increase in repulsion among the electrons. However, the
number of protons remains the same. As a result, the effective nuclear charge
of the atom decreases and the radius of the atom increases.
(b) When an atom loses an electron, the number of
electrons decreases by one while the nuclear charge remains the same.
Therefore, the interelectronic repulsions in the atom decrease. As a result,
the effective nuclear charge increases. Hence, the radius of the atom
decreases.
Q.9.
How does
atomic radius vary in a period and in a group? How do you explain the
variation?
Ans- Atomic radius generally decreases from left to right
across a period. This is because within a period, the outer electrons are
present in the same valence shell and the atomic number increases from left to
right across a period, resulting in an increased effective nuclear charge. As a
result, the attraction of electrons to the nucleus increases.
On
the other hand, the atomic radius generally increases down a group. This is
because down a group, the principal quantum number (n) increases which results in an increase of the distance between
the nucleus and valence electrons.
Q.10.
Consider
the following species:
N3–,
O2–, F–, Na+, Mg2+ and Al3+
(a)
What is
common in them?
(b) Arrange them in the order of increasing ionic
radii.
Ans- (a) the same number of electrons (10
electrons). Hence, the given species are isoelectronic.
(b) Al3+ < Mg2+ < Na+
< F– < O2– < N3–
FIVE MARKS QUESTIONS
Q.1. What is the cause of the periodicity
in the properties of the elements? How do the following properties vary in (a)
a group and (b)in a period
(i) electronegativity (ii)
ionisation enthalpy (iii) Atomic
size
Ans- It is due to the similarity in the
outer electronic configurations which gives rise to the periodic properties of
the elements.
(a) In a group:
(i)
Electronegativity- It decreases
down the group.
(ii)
Ionisation enthalpy- It
decreases down the group.
(iii)
Atomic size- It increases down
the group.
(b) In a period:
(i) Electronegativity-
Increases (ii) Ionisation enthalpy- Increases (iii) Atomic size- Dereases.
Q.2. The first (ΔiH1) and the second (ΔiH) ionization enthalpies (in kJ mol–1) and
the (ΔegH) electron gain
enthalpy (in kJ mol–1) of a few elements are given below:
Elements ΔiH ΔiH
ΔegH
I
520 7300 –60
II
419 3051 –48
III
1681 3374 –328
IV
1008 1846
–295 V 2372 5251 +48
VI 738
1451 –40
Which
of the above elements is likely to be :
(a) the least reactive element. (b) the
most reactive metal.
(c) the most reactive non-metal. (d)
the least reactive non-metal. (e) the metal which can form a stable binary
halide of the formula MX2, (X=halogen).
(f) the metal which can form a
predominantly stable covalent halide of the formula MX (X=halogen)?
Ans- (a) Element V is likely to
be the least reactive element. This is because it has the highest first
ionization enthalpy (ΔiH1)
and a positive electron gain enthalpy
(ΔegH).
(b) Element II is likely to be the most reactive metal as it has the
lowest first ionization enthalpy (ΔiH1)
and a low negative electron gain enthalpy (ΔegH).
(c) Element III is likely to be the
most reactive non–metal as it has a high first ionization enthalpy (ΔiH1) and the
highest negative electron gain enthalpy (ΔegH).
(d) Element V is likely to be the
least reactive non–metal since it has a very high first ionization enthalpy (ΔiH2) and a
positive electron gain enthalpy (ΔegH).
(e) Element VI has a low negative
electron gain enthalpy (ΔegH).
Thus, it is a metal. Further, it has the lowest second ionization enthalpy (ΔiH2). Hence, it
can form a stable binary halide of the formula MX2(X=halogen).
(f) Element I has low first
ionization energy and high second ionization energy. Therefore, it can form a
predominantly stable covalent halide of the formula MX (X=halogen).
0 Comments
Please Provide Your Feedback.