1. Periodic Variation in Physical Properties of the Elements H to Ar38
38.1 The Periodic Table
38.2 Periodic Variation in Physical Properties of Elements

2. 38.1
The Periodic Table

3. The Periodic Table With more and more elements being discovered
38.1 The Periodic Table (SB p.2)
The Periodic Table
With more and more elements being discovered
 needed a way to organize them effectively

4. The Periodic Table The modern Periodic Table
38.1 The Periodic Table (SB p.2)
The Periodic Table
The modern Periodic Table
 the basis of the atomic numbers and electronic configurations of element

5. The modern Periodic Table
38.1 The Periodic Table (SB p.2)
The modern Periodic Table

6. The Periodic Table The earliest version of the Periodic Table
38.1 The Periodic Table (SB p.3)
The Periodic Table
The earliest version of the Periodic Table
 introduced in 1869
 by a Russian chemist called Dimitri Mendeleev

7. 38.1 The Periodic Table (SB p.3)
A portion of one of Dimitri Mendeleev’s handwritten drafts of the Periodic Table

8. Dimitri Mendeleev’s Periodic Table in 1872
38.1 The Periodic Table (SB p.3)
Dimitri Mendeleev’s Periodic Table in 1872

9. 38.1 The Periodic Table (SB p.3)
Mendeleev created the first Periodic Table based on atomic masses
Many elements had similar properties
 occurred periodically
 the name Periodic Table was used

10. The Periodic Table The periodic law stated
38.1 The Periodic Table (SB p.3)
The Periodic Table
The periodic law stated
 the chemical and physical properties of the elements vary in a periodic way with their atomic masses

11. The Periodic Table Example:
38.1 The Periodic Table (SB p.3)
The Periodic Table
Example:
Lithium, sodium, potassium, rubidium and caesium
 have similar chemical properties

12. The Periodic Table Example:
38.1 The Periodic Table (SB p.3)
The Periodic Table
Example:
Beryllium, magnesium, calcium, strontium and barium
 also have similar chemical properties

13. The Periodic Table According to Mendeleev’s theory
38.1 The Periodic Table (SB p.3)
The Periodic Table
According to Mendeleev’s theory
 they could be perfectly arranged by increasing atomic masses
Some elements did not match perfectly

14. The Periodic Table Tellurium is heavier than iodine
38.1 The Periodic Table (SB p.3)
The Periodic Table
Tellurium is heavier than iodine
 but the chemical properties of tellurium did not match with those of chlorine and bromine
 the chemical properties of iodine did not match with those of sulphur and selenium

15. The Periodic Table Tellurium should be placed before iodine
38.1 The Periodic Table (SB p.3)
The Periodic Table
Tellurium should be placed before iodine
 even though tellurium was heavier than iodine

16. The Periodic Table The modern Periodic Table
38.1 The Periodic Table (SB p.3)
The Periodic Table
The modern Periodic Table
 arranged according to atomic numbers instead of atomic masses
Let's Think 1

17. The Periodic Table The modern Periodic Table is divided into
38.1 The Periodic Table (SB p.4)
The Periodic Table
The modern Periodic Table is divided into
 7 horizontal rows called periods
 18 vertical columns called groups

18. 38.1 The Periodic Table (SB p.4)
Elements with atoms having the same number of electron shells
 put in the same period
Elements having the same number of outermost shell electrons
 put in the same group

19. The Periodic Table Elements can be classified as  s-block elements
38.1 The Periodic Table (SB p.4)
The Periodic Table
Elements can be classified as
 s-block elements
 p-block elements
 d-block elements
 f-block elements

20. 38.1 The Periodic Table (SB p.4)
1. s -Block Elements
Group IA and Group IIA elements constitute the s-block
They are elements with outermost shell electrons occupying the s orbital

21. 38.1 The Periodic Table (SB p.4)
1. s -Block Elements
Group IA elements have only one outermost shell electron occupying the s orbital
Examples:
Lithium, sodium, potassium, rubidium, caesium and francium

22. 1. s -Block Elements They are highly reactive metals
38.1 The Periodic Table (SB p.4)
1. s -Block Elements
They are highly reactive metals
They are known as the alkali metals

23. 38.1 The Periodic Table (SB p.4)
1. s -Block Elements
Group IIA elements have two outermost shell electrons in the s orbital
Example:
Beryllium, magnesium, calcium, strontium, barium and radium

24. 1. s -Block Elements They are also chemically reactive
38.1 The Periodic Table (SB p.4)
1. s -Block Elements
They are also chemically reactive
They are known as the alkaline earth metals

25. 38.1 The Periodic Table (SB p.4)
2. p -Block Elements
Elements having electronic configurations from [ ] ns2np1 to [ ] ns2np6
They include Group IIIA, IVA, VA, VIA, VIIA and 0

26. 2. p -Block Elements Group VIIA elements are all non-metals
38.1 The Periodic Table (SB p.4)
2. p -Block Elements
Group VIIA elements are all non-metals
They are known as the halogens

27. 2. p -Block Elements Group 0 elements are called noble gases
38.1 The Periodic Table (SB p.4)
2. p -Block Elements
Group 0 elements are called noble gases
They have a fully-filled outermost electron shell
 gives rise to extra stability
 the very stable electronic configuration

28. 38.1 The Periodic Table (SB p.4)
2. p -Block Elements
s-Block and p-block elements together are also known as representative elements

29. 38.1 The Periodic Table (SB p.4)
3. d -Block Elements
Elements with electronic configurations from [ ] (n – 1)d1ns2 (Group IIIB) to [ ] (n – 1)d10ns2 (Group IIB)
They are also called transition elements

30. 38.1 The Periodic Table (SB p.4)
4. f -Block Elements
Two series of f-block elements in which the 4f and 5f orbitals being filled up with 1 to 14 electrons respectively
They are the lanthanide series and the actinide series
They are sometimes called inner-transition elements

31. 38.1 The Periodic Table (SB p.5)
Elements can be classified as s-block elements, p-block elements, d-block elements and f-block elements in the Periodic Table

32. 38.1 The Periodic Table (SB p.5)
Check Point 38-1

33. First ionization enthalpy
38.2 Periodic Variation in Physical Properties of Elements (SB p.6)
First ionization enthalpy
The first ionization enthalpy of an atom is the energy required to remove one mole of electrons from one mole of its gaseous atoms to form one mole of gaseous ions with one positive charge.

34. First ionization enthalpy
38.2 Periodic Variation in Physical Properties of Elements (SB p.6)
First ionization enthalpy
Energy is required
 overcome the attractive forces between the nucleus and the electron to be removed
 the ionization enthalpy always has a positive value

35. First ionization enthalpy
38.2 Periodic Variation in Physical Properties of Elements (SB p.6)
First ionization enthalpy
The ionization enthalpy of an element
 reflects the relative force of attraction between the nucleus and the electron being removed

36. First ionization enthalpy
38.2 Periodic Variation in Physical Properties of Elements (SB p.6)
First ionization enthalpy
Four main factors affecting the magnitude of the ionization enthalpy of an atom:
1. the electronic configuration of an atom;
2. the nuclear charge;
3. the screening effect; and
4. the atomic radius
Let's Think 2

37. The first ionization enthalpies of the first 20 elements
38.2 Periodic Variation in Physical Properties of Elements (SB p.6)
The first ionization enthalpies of the first 20 elements

38. Variation in the first ionization enthalpy of
38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
Variation in the first ionization enthalpy of
the first 20 elements

39. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
1. General increase in the first ionization enthalpy across both Periods 2 and 3
The consequence of the increase in nuclear charge with atomic numbers

40. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
1. General increase in the first ionization enthalpy across both Periods 2 and 3
At the same time
 additional electrons are entering the same electron shell
 they have poor screening effect

41. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
1. General increase in the first ionization enthalpy across both Periods 2 and 3
In other words
 an increase in effective nuclear charge across the periods

42. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
1. General increase in the first ionization enthalpy across both Periods 2 and 3
Going across a period
 the electrons are drawn closer to the nucleus
 more energy is required to remove an electron from the atom
 the first ionization enthalpy generally increases across both Periods 2 and 3

43. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
In Period 2
 the first ionization enthalpy of boron is lower than that of beryllium

44. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
In Period 3
 the first ionization enthalpy of aluminium is lower than that of magnesium

45. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
Boron and aluminium have [ ] ns2np1 electronic configurations
 easier to remove the outermost p electron

46. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
 the electron is shielded from the attraction of the nucleus by the completely filled s orbitals (ns2)
 The first ionization enthalpies of Group III elements are not very high

47. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
Beryllium and magnesium have a relatively stable electronic configuration
 the s orbital is completely filled
 a relatively large amount of energy is needed to ionize their atoms

48. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
In Period 2
 the first ionization enthalpy of oxygen is lower than that of nitrogen

49. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
In Period 3
 the first ionization enthalpy of sulphur is lower than that of phosphorus

50. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
The atoms of oxygen and sulphur have one electron more than the half-filled p sub-shell
 when the electronic configuration of half-filled p sub-shell (np3) is attained
 extra stability is gained

51. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
A relatively small amount of energy is required to remove the first electron from the atoms of oxygen and sulphur

52. 38.2 Periodic Variation in Physical Properties of Elements (SB p.7)
2. Irregularities with general increase in the first ionization enthalpy across both Periods 2 and 3
The electronic configurations of nitrogen and phosphorus are [ ] ns2np3 (i.e. half-filled p sub-shell)
 a relatively stable electronic configuration
 more energy is required to remove an electron from their atoms

53. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
3. A sharp drop in the first ionization enthalpy from one period to the next
The element at the end of each period (i.e. the noble gas)
 has a completely filled octet (except helium which has a duplet)
 this electronic configuration is very stable

54. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
3. A sharp drop in the first ionization enthalpy from one period to the next
 A large amount of energy is required to remove an electron from their atoms

55. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
3. A sharp drop in the first ionization enthalpy from one period to the next
The element at the beginning of the next period (i.e. the Group I element)
 has an electron entering a new electron shell
 further away from the nucleus

56. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
3. A sharp drop in the first ionization enthalpy from one period to the next
 The attractive force between the nucleus and the electron is relatively weak

57. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
3. A sharp drop in the first ionization enthalpy from one period to the next
This s electron is shielded from the attraction of the nucleus effectively by the inner electron shells
 once this electron is removed, a stable electronic configuration is attained

58. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
3. A sharp drop in the first ionization enthalpy from one period to the next
 The first ionization enthalpies of Group I elements are relatively low

59. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
4. The first ionization enthalpy decreases down any group in the Periodic Table
When going down a group
 increase in atomic radius
 the outermost shell electrons will experience less attraction from the nucleus

60. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
4. The first ionization enthalpy decreases down any group in the Periodic Table
There is an increase in the nuclear charge down a group
 the outermost shell electrons would experience less attraction from the positively charged nucleus
 the first ionization enthalpy decreases down a group

61. Atomic radius Atomic radius is used to describe the size of an atom.
38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
Atomic radius
Atomic radius is used to describe the size of an atom.

62. Atomic radius For non-metals
38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
Atomic radius
For non-metals
 the atomic radii commonly used are the covalent radii

63. Atomic radius For metals  the metallic radii are used
38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
Atomic radius
For metals
 the metallic radii are used

64. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
Atomic radius
Covalent radius is defined as half the internuclear distance between two covalently bonded atoms in a molecule of the element.

65. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
Atomic radius
Metallic radius is defined as half the internuclear distance between two atoms in a metallic crystal.

66. Atomic radius The atomic radius of an atom is governed by two factors:
38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
Atomic radius
The atomic radius of an atom is governed by two factors:
1. Attraction between the nucleus and the electrons
2. Screening of the outermost shell electrons from the nucleus by inner electron shells

67. 1. Attraction between the nucleus and the electrons
38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
1. Attraction between the nucleus and the electrons
The greater the number of protons in the nucleus
 the higher the nuclear charge

68. 1. Attraction between the nucleus and the electrons
38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
1. Attraction between the nucleus and the electrons
This results in greater attraction between the nucleus and the electrons
 the electrons are drawn closer to the nucleus
 the atomic radius becomes smaller

69. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
2. Screening of the outermost shell electrons from the nucleus by inner electron shells
As electrons are negatively charged
 repulsion between the outermost shell electrons and the electrons on the inner shells of an atom
 the outermost shell electrons are screened from the attraction of the nucleus

70. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
2. Screening of the outermost shell electrons from the nucleus by inner electron shells
The greater the number of electron shells in the atom
 the greater the screening effect

71. 38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
2. Screening of the outermost shell electrons from the nucleus by inner electron shells
The outermost shell electrons are less strongly held by the nucleus
 the atomic radius becomes larger
Let's Think 3

72. The atomic radii of the first 20 elements
38.2 Periodic Variation in Physical Properties of Elements (SB p.9)
The atomic radii of the first 20 elements

73. Variation in atomic radius of the first 20 elements
38.2 Periodic Variation in Physical Properties of Elements (SB p.9)
Variation in atomic radius of the first 20 elements

74. Atomic radius Within a given period
38.2 Periodic Variation in Physical Properties of Elements (SB p.9)
Atomic radius
Within a given period
 the atomic radii decrease progressively with increasing atomic numbers
 an increase in atomic number by one means that one more electron and one more proton are added in the atom

75. Atomic radius The additional electron
38.2 Periodic Variation in Physical Properties of Elements (SB p.9)
Atomic radius
The additional electron
 cause an increase in repulsion between the electrons in the outermost shell
 results in an increase in atomic radius

76. Atomic radius The additional proton in the nucleus
38.2 Periodic Variation in Physical Properties of Elements (SB p.9)
Atomic radius
The additional proton in the nucleus
 cause the electrons to experience greater attractive forces from the nucleus

77. Atomic radius The newly added electron  goes to the outermost shell
38.2 Periodic Variation in Physical Properties of Elements (SB p.9)
Atomic radius
The newly added electron
 goes to the outermost shell
 is at approximately the same distance from the nucleus
 the repulsion between the electrons is relatively ineffective to cause an increase in atomic radius

78. 38.2 Periodic Variation in Physical Properties of Elements (SB p.9)
Atomic radius
The effect of increasing nuclear charge outweighs the effect of repulsion between the electrons
 an increase in effective nuclear charge
 the atomic radii of elements decrease across a period

79. Atomic radius If we look closer
38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Atomic radius
If we look closer
 sharp decrease in atomic radius from the first element to the third element of each period
 followed by a gradual decrease along subsequent elements

80. Atomic radius At the beginning of each period
38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Atomic radius
At the beginning of each period
 increasing effective nuclear charge with atomic numbers predominates
 greater contraction of the electron cloud

81. Atomic radius When more electrons are added to the same electron shell
38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Atomic radius
When more electrons are added to the same electron shell
 the effect of repulsion between electrons becomes more significant
 the effective nuclear charge increases only slowly towards the end of the period
 the decrease in atomic radius is thus smaller

82. Atomic radius Going down a group in the Periodic Table
38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Atomic radius
Going down a group in the Periodic Table
 the atoms have more electron shells occupied
 the outermost electron shells become further away from the nucleus

83. Atomic radius The outermost shell electrons
38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Atomic radius
The outermost shell electrons
 more effectively shielded by the inner electron shells from the nuclear charge
 decrease in the attractive force between the nucleus and the outermost shell electrons
 the atomic radii of elements increase down a group

84. 38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Electronegativity
Electronegativity is the relative tendency of an atom to attract bonding electrons towards itself in a covalent bond.

85. 38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Electronegativity
Pauling assigned electronegativity values to the elements on an arbitrary scale from 0 to 4

86. Electronegativity The higher the electronegativity value of an atom
38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Electronegativity
The higher the electronegativity value of an atom
 the higher the ability of the atom to attract bonding electrons towards itself in a covalent bond

87. Electronegativity Fluorine  the most electronegative element
38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Electronegativity
Fluorine
 the most electronegative element
 assigned an electronegativity value of 4.0 in Pauling’s scale

88. Electronegativity values of the first 20 elements
38.2 Periodic Variation in Physical Properties of Elements (SB p.10)
Electronegativity values of the first 20 elements

89. Variation in electronegativity values of the first 20 elements
38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
Variation in electronegativity values of the first elements

90. Electronegativity Going across Periods 2 and 3 in the Periodic Table
38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
Electronegativity
Going across Periods 2 and 3 in the Periodic Table
 electronegativity of the elements increases from left to right
 the decrease in atomic size

91. 38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
Electronegativity
As the effect of increasing nuclear charge outweighs the screening effect of the electrons in the same electron shell
 the bonding electrons are attracted more strongly

92. Electronegativity Moving down a group in the Periodic Table
38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
Electronegativity
Moving down a group in the Periodic Table
 electronegativity of the elements decreases
 the increase in atomic size

93. 38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
Electronegativity
With the increase in number of electron shells and greater screening effect
 the bonding electrons are attracted less strongly

94. 38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
Melting point
The melting point of a substance is the temperature at which the substance changes from its solid phase to liquid phase.

95. Melting point A solid does not melt
38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
Melting point
A solid does not melt
 unless there is sufficient energy to overcome the forces holding the particles together in the solid state

96. Melting point The amount of energy depends on
38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
Melting point
The amount of energy depends on
1. the magnitude of the attractive forces between the particles
2. how the particles are arranged in the solid

97. The melting points of the first 20 elements
38.2 Periodic Variation in Physical Properties of Elements (SB p.11)
The melting points of the first 20 elements

98. Variation in melting point of the first 20 elements
38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
Variation in melting point of the first 20 elements

99. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
1. A steady increase in melting point from lithium to boron and from sodium to aluminium
Both lithium and beryllium have a giant metallic structure
The metallic bond strength increases with the number of outermost shell electrons

100. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
1. A steady increase in melting point from lithium to boron and from sodium to aluminium
As lithium has only one outermost shell electron while beryllium has two
 the metallic bond strength in beryllium is stronger than that in lithium
 beryllium has a higher melting point than lithium

101. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
1. A steady increase in melting point from lithium to boron and from sodium to aluminium
Boron has a giant covalent structure
The bonding that holds the boron atoms together is stronger than those of lithium and beryllium
 the melting point of boron is higher than those of lithium and beryllium

102. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
1. A steady increase in melting point from lithium to boron and from sodium to aluminium
For Period 3 elements
 sodium, magnesium and aluminium all have a giant metallic structure

103. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
1. A steady increase in melting point from lithium to boron and from sodium to aluminium
There is an increase in number of electrons involved in the metallic bond
 the strength of metallic bond increases from sodium to aluminium
 the melting point increases from sodium to aluminium

104. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
2. Carbon and silicon correspond to the maxima in Periods 2 and 3 respectively
Both carbon and silicon have a giant covalent structure
 the atoms are held together by strong covalent bonds

105. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
2. Carbon and silicon correspond to the maxima in Periods 2 and 3 respectively
A large amount of energy is needed to overcome the strong covalent bonds
 the melting points of carbon and silicon are extremely high

106. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
3. The melting points of the elements from nitrogen to neon and from phosphorus to argon are relatively low
They all exist as discrete molecules
 held together by weak van der Waals’ forces

107. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
3. The melting points of the elements from nitrogen to neon and from phosphorus to argon are relatively low
Only a little amount of energy is needed to overcome the weak van der Waals’ forces
 their melting points are relatively low
Let's Think 4

108. Melting point In Period 3
38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Melting point
In Period 3
 sulphur exists as S8 molecules in its molecular crystal
 phosphorus exists as P4 molecules in its solid molecular crystal

109. Melting point S8 molecule  a higher molecular mass
38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Melting point
S8 molecule
 a higher molecular mass
 a greater surface area for contact with neighbouring molecules

110. 38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Melting point
The van der Waals’ forces between S8 molecules are stronger than those between P4 molecules
 the melting point of sulphur is higher than that of phosphorus

111. Melting point Sulphur  higher melting point than chlorine
38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Melting point
Sulphur
 higher melting point than chlorine

112. Melting point Chlorine  only exists as diatomic molecules
38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Melting point
Chlorine
 only exists as diatomic molecules
 the van der Waals’ forces between S8 molecules are stronger than those between Cl2 molecules

113. 38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Check Point 38-2
Example 38-1

114. 38.2 Periodic Variation in Physical Properties of Elements (SB p.14)
Structure and Bonding
A summary of the variations in structure and bonding of elements across both Periods 2

115. 38.2 Periodic Variation in Physical Properties of Elements (SB p.14)
Structure and Bonding
A summary of the variations in structure and bonding of elements across both Periods 3

116. 38.2 Periodic Variation in Physical Properties of Elements (SB p.14)
Structure and Bonding
In each of the periods, the structures of the elements changes from
 giant metallic structures
 followed by giant covalent structures
 finally to simple molecular structures

117. Structure and Bonding Going across the periods from left to right
38.2 Periodic Variation in Physical Properties of Elements (SB p.14)
Structure and Bonding
Going across the periods from left to right
 the bonding of the elements also varies in a repeating pattern
 from metallic bonding to covalent bonding

118. The END

119. 38.1 The Periodic Table (SB p.3)
Let's Think 1
The atomic numbers of tellurium and iodine are 52 and 53 respectively. Why is tellurium heavier than iodine?
Answer
Atomic number of an element is not related to the mass of an atom of the element. The atomic number of an element is the number of protons in an atom of the element. It is unique for each element. The mass of an atom of the element is mainly determined by the number of protons and neutrons in the nucleus. Therefore, tellurium is heavier than iodine though the atomic number of tellurium is smaller than that of iodine.
Back

120. 38.1 The Periodic Table (SB p.5)
Check Point 38-1
To which block (s-, p-, d- or f-) in the Periodic Table do rubidium, gold, astatine and uranium belong respectively?
Answer
Rubidium: s-block
Gold: d-block
Astatine: p-block
Uranium: f-block
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121. Which element would have the highest first ionization enthalpy?
38.2 Periodic Variation in Physical Properties of Elements (SB p.6)
Let's Think 2
Which element would have the highest first ionization enthalpy?
Answer
Helium
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122. Which element would have the smallest atomic radius?
38.2 Periodic Variation in Physical Properties of Elements (SB p.8)
Let's Think 3
Which element would have the smallest atomic radius?
Answer
Helium
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123. 38.2 Periodic Variation in Physical Properties of Elements (SB p.12)
Let's Think 4
Why is the melting point of chlorine higher than argon?
Answer
Chlorine atom has a higher effective nuclear charge than argon atom, so the atomic radius of chlorine is smaller than that of argon. Therefore, the van der Waals’ forces between chlorine molecules are stronger than those between argon molecules. Since a higher amount of energy is needed to overcome the stronger van der Waals’ forces, the melting point of chlorine is higher than that of argon.
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124. 38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Example 38-1
Considering the trend of atomic radius in the Periodic Table, arrange the elements Si, N and P in the order of increasing atomic radius. Explain your answer briefly.
Answer
In the Periodic Table, N is above P in Group VA. As the atomic radius increases down a group, the atomic radius of N is smaller than that of P.
Si and P belong to the same period. Since the atomic radius decreases across a period, the atomic radius of P is smaller than that of Si.
Therefore, the atomic radius increases in the order: N < P < Si.
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125. 38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Check Point 38-2
(a) With the help of the Periodic Table only, arrange the elements selenium, sulphur and argon in the order of increasing first ionization enthalpies.
Answer
(a) The first ionization enthalpy increases in the order: Se < S < Ar.

126. 38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Check Point 38-2
(b) Describe and explain the general periodic trend of atomic radius of elements in the Periodic Table.
Answer

127. 38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
(b) Within a given period, the atomic radii decrease progressively with increasing atomic numbers. This is because an increase in atomic number by one means that one more electron and one more proton are added in the atom. The additional electron would cause an increase in repulsion between the electrons in the outermost shell and results in an increase in atomic radius. The additional proton in the nucleus would cause the electrons to experience greater attractive forces from the nucleus. Due to the fact that the newly added electron goes to the outermost shell and is at approximately the same distance from the nucleus, the repulsion between the electrons is relatively ineffective to cause an increase in atomic radius. Therefore, the effect of increasing nuclear charge outweighs the effect of repulsion between the electrons. That means, there is an increase in effective nuclear charge. As a result, the atomic radii of elements decrease across a period.

128. 38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
Check Point 38-2
(c) With reference to Fig on p.11 (variation in electronegativity value of the first 20 elements), explain why the alkali metals are almost at the bottom of the troughs, whereas the halogens are at the peaks of the plot.
Answer

129. 38.2 Periodic Variation in Physical Properties of Elements (SB p.13)
(c) The alkali metals are almost at the bottom of troughs, indicating that they have low electronegativity values. It is because their nuclear charge is effectively shielded by the fully-filled inner electron shells of electrons, and the bonding electrons are attracted less strongly. On the other hand, the halogens appear at the peaks. This indicates that they have high electronegativity values. It is because they have one electron less than the octet electronic configuration. They tend to attract an electron to complete the octet, and the bonding electrons are attracted strongly.
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