Physical properties

         (1) A regular increasing trend in density down the group is due to increase in size.

         (2) Melting points do not vary regularly and decrease from B to Ga and then increase.

         (3) Boron has quite high melting point because it exist as the giant covalent polymer in both solid and liquid state.

         (4) Low melting point of Ga (29.8⁰C) is due to the fact that consists of only Ga₂ molecule; it exists as liquid upto 2000⁰C and hence used in high temperature thermometry.

         (5) Boiling point of these elements however shows a regular decrease down the group.

         (6) The sudden increase in the atomic radius of Al is due to greater screening effect in Al (it has 8 electrons in its penultimate shell) than in B (it has 2 electrons in its penultimate shell)

         (7) The atomic radii of group 13 elements are smaller than the corresponding s-block elements. This is because of the fact that when we move along period, the new incoming electrons occupy same shell while the nuclear charge increases regularly showing more effective pull of the nucleus towards shell electrons. This reduces the atomic size of it .

         (8) The atomic radius of Ga is somewhat lesser than of Al because in going from Al to Ga, electrons have already occupied 3d sub shell in the Ga. The screening effect of these intervening electrons being poor and has less influence to decrease effective nuclear charge, thus the electrons in Ga experience more forces of the attractions towards nucleus to result in the lower size of Ga than that of Al

         (9) Oxidation state

     (i) All exhibit +3 oxidation state and thus complete their octet either by covalent or ionic union.

     (ii) Boron being smaller in size cannot lose its valence electrons to form B³⁺ ion and it usually show +3 covalence. The tendency to show +3 covalence however decreases down the group even Al shows +3 covalence in most of its compounds.

         (iii) Lower elements also show +1 ionic state e.g Tl ⁺, Ga⁺. This is due to inert pair effect. The phenomenon in which outer shell 's' electrons (ns²) penetrate to (n-1) d-electrons and thus become closer to nucleus and are more effectively pulled the nucleus. This results in less availability of ns² electrons pair for bonding  or  ns² electron pair becomes inert. The inert pair effect begins after n ³ 4 and increases with increasing value of n.

         (iv) The tendency to form M⁺ ion increases down the gp.   Ga⁺¹ < Tl⁺¹

         (10) Hydrated ions : All metal ions exist in hydrated state.

         (11) Ionisation energy

         (i) Inspite of the more charge in nucleus and small size, the primary ionisation energies of this group elements are lesser than the corresponding elements of s block. This is because of the fact that removal of electron from a p-orbitals (being far away from the nucleus and hence less effectively held than s-orbitals) is relatively easier than s-orbitals.

         (ii) The ionisation energy of this group element decrease down the group due to increases in size like other group elements.

         (iii) However, ionisation energy of Ga are higher than that of Al because of smaller atomic size of Ga due to less effective shielding of 3d electrons in Ga. Thus valence shell exerts more effective nuclear charge in Ga to show higher ionisation energies.

         (12) Electropositive character

         (i) The electropositive character increases from B to Tl.

         (ii) Boron is semi metal, more closer to non-metallic nature whereas rest all members are pure metals.

         (iii) Moreover, these elements are less electropositive than s-block elements due to smaller size and higher ionisation energies.

         (13) Oxidation potential

         (i) Standard oxidation potentials of these element are very high and are given as follows,

                                                   B          Al           Ga          In         Tl

E⁰op for M → M³⁺+ 3e    -         +1.66      +0.56    +0.34    +1.26

E⁰op for M → M⁺ + e       -         +0.55          -         +0.18    +0.34

         (ii) Though Boron does not form positive ions in aqueous solution and has very low oxidation potential.

         (iii) Higher values of the standard oxidation potentials are because of higher heats of the hydration on account of smaller size of the trivalent cations.

         (iv) Aluminium is quite strong reducing agent and can reduce oxides which are not reduced even by carbon. This is because of lower ionisation energy of aluminium than carbon. The reducing nature of these elements can be given as Al > Ga > In > Tl.

         (14) Complex formation : On account of their smaller size and more effective nuclear charge as well as vacant orbitals to accept elements, these elements have more tendency to form complexes than-s block elements.

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