s Block Elements

S - BLOCK ELEMENTS

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Introduction

-The elements if IA group i.e. alkali metals and IIA group i.e. alkaline earth metals, are known as s-block elements. The s-block elements can have outer electronic configuration ns1 _{or ns}2_{, where, n = number of outer electrons.}

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Electronic configuration -

♦

Group IA

:-Outer electronic configuration of Group IA is ns1_{. Due to the identical outer electronic}

configuration, they show similar properties.

At.No. Symbol Name Electronic configuration

3 11 19 37 55 87 Li Na K Rb Cs Fr Lithium Sodium Potassium Rubidium Caesium Francium 1s2 _2s1 1s2 _2s2 _2p6 _3s1 1s2 _2s2 _2p6 _3s2 _3p6 _4s1 1s2 _2s2 _2p6 _3s2 _3p6 _4s2 _3d10 _4p6 _5s1 1s2 _2s2 _2p6 _3s2 _3p6 _4s2 _3d10 _4p6 _5s2 _4d10 _5p6 _6s1 1s2 _2s2 _2p6 _3s2 _3p6 _4s2 _3d10 _4p6 _5s2 _4d10 _5p6 _6s2 _4f14 _5d10 _6p6 _7s1

♦

:-Outer electronic configuration of Group IIA is ns2_{. Due to the identical outer}

electronic configuration, they show similar properties. At.No. Symbol Name Electronic configuration

4 12 20 38 56 88 Be Mg Ca Sr Ba Ra Beryllium Magnesium Calcium Strontium Barium Radium 1s2 _2s2 1s2 _2s2 _2p6 _3s2 1s2 _2s2 _2p6 _3s2 _3p6 _4s2 1s2 _2s2 _2p6 _3s2 _3p6 _4s2 _3d10 _4p6 _5s2 1s2 _2s2 _2p6 _3s2 _3p6 _4s2 _3d10 _4p6 _5s2 _4d10 _5p6 _6s2 1s2 _2s2 _2p6 _3s2 _3p6 _4s2 _3d10 _4p6 _5s2 _4d10 _5p6 _6s2 _4f14 _5d10 _6p6 _7s2

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Comparative study of groups

-In s-block elements, only francium and radium are radioactive. They disintegrate into other elements and therefore do not occur in nature in large amount.

-i) Size -

Alkali metals - Alkali metals are largest in the corresponding period. The ions are smaller than the atoms. Atomic and ionic radii increase

from Li to Fr. Alkaline earth metals - Their atoms and ions are

larger, but smaller than corresponding alkali metals. Atomic radii and ionic radii, increases from Be to Ra.

ii) Ionization potential (Ionization energy) -

Alkali metals - In alkali metals, ionization potential is lowest. As size increases, ionization potential decreases from top to bottom, from Li to Fr. Alkaline earth metals - In alkaline earth metals, ionization potential is lower and it decreases from top to bottom, from Be to Ra. Their ionization potential is higher than the ionization potential of corresponding alkali metals.

iii) Electronegativity -

Alkali metals - Alkali metals show very low electronegativity i.e. they have lowest tendency to attract electrons.

Alkaline earth metals - They also have low electronegativity but not lower than the alkali metals.

iv) Electropositivity -

Alkali metals - Alkali metals are highly electropositive and their electropositive character increases from Li to Cs.

Alkaline earth metals - They are also electropositive, but their electropositivity is lower than the corresponding alkali metals. Their electropositive character increases from Be to Ra.

v) Reactivity - Both alkali metals and alkaline earth metals are very reactive, due to low ionization potential and high electropositive character.

vi) Melting point and boiling point

Alkali metals - Alkali metals have low melting and boiling points. Due to less number of valence electrons, the binding is weak and so they have low melting and boiling points. Their M.P. and B.P. decreases from Li to Fr.

Alkaline earth metals - They have higher melting and boiling points than those of corresponding alkali metals.

vii) Flame colour - The s- block elements and their salts, give colour to the flame, if introduced in the flame. In Be and Mg, electrons are bound strongly due to

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Chemical Properties

-Alkali Metals - They have low ionization potential and therefore high chemical reactivity.

i. Action of air - On exposure to air, alkali metals react readily with oxygen to form their oxides. So they are stored in kerosene.

4Li + O2 2Li2O

Sodium gives peroxide Na2O2

while Rb and Cs give superoxides.

ii. Action of water – The alkali metals react readily with water forming their hydroxides MOH with evolution of hydrogen gas.

4Li + H2O 2LiOH + H2

The reactivity with water increases from Li to Cs.

iii. Action with hydrogen - The alkali metals react with hydrogen to form their hydrides MH.

2Na + H2 2NaH

iv. Action with halogen – Alkali metals react with halogen to form halides MX. These halides are ionic compounds. Sodium reacts with halogens to form halides like NaCl, NaBr, NaI, etc. While potassium forms KCl, KBr, KI.

2Na + Cl2 2NaCl

Alkali Metals Alkaline earth metals

Li - Crimson red Na - Golden yellow K - Lilac

Rb - Violet Cs - Violet

Be - do not give colour Mg - do not give colour Ca - Brick red

Sr - Crimson red Ba - Apple green

v. Action with mercury – Alkali metals combine readily with mercury to form amalgam. e.g. Na-Hg (sodium amalgam)

vi. Complexes of alkali metals – Alkali metals are smaller in size, they have lower charges on their cations, so they do not form stable complexes with simple ligands. However, they can form complexes with bidentate ligands.

vii. Anomalous properties of Lithium – Lithium has highest ionization potential as compared to other alkali metals. Its atomic and ionic sizes (Li & Li+_{) are also is smallest, so Li}+ _{have greatest polarizing power, as compared to other}

elements of IA group. Due to this Lithium shows slightly different properties than other IA gr. elements.

Alkaline earth Metals – Alkaline earth metals are less reactive than alkali metals.

i. Action of air - On exposure to air, alkaline earth

metals slowly oxidize to form their oxides.

2Ca + O2 CaO

The reactivity increases from Be to Ra.

ii. Action of water – The alkaline earth metals react

slowly with water to form their hydroxides M(OH)2 with evolution of hydrogen gas.

Ca + 2H2O

Ca(OH)2 + H2

iii. Action with hydrogen – Except Beryllium, all

other alkaline earth metals combine directly with hydrogen to form their hydrides MH2.

BeH2 is covalent, while other hydrides are electrovalent.

Mg

+ H2 MgH2

iv. Action with halogen – Alkaline earth metals react

with halogen at higher temperatures to form halides MX2. BeH2 is covalent, while other

halides are electrovalent.

Mg + Cl2 MgCl2

v. Action of acids – Alkaline earth metals react

readily with acids to form their halides along with liberation of hydrogen gas.

vi. Complexes of alkaline earth metals – Alkaline earth metals form stable complexes with oxygen and nitrogen donor ligands. The tendency to form complexes decreases from Be to Ba. Thus, Be shows greatest tendency to form complexes while, Ba forms less number of complex compounds.

vii. Anomalous properties of Beryllium – Beryllium

shows slightly different properties than other alkaline earth metals, due to its smaller size and high electronegativity.

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Halides

-Alkali Metal halides -

Alkali metals form MX type compounds with halogens. These compounds are called as alkali metal halides. e.g. LiCl, LiF, NaCl, KCl, KI, KF,etc.

Preparation : Alkali metals combine with halogens to from halides, along with the evolution of heat.

e.g. 2Li + Cl2 2LiCl

Properties :

1. Alkali metal halides are ionic compounds.

They are good conductors and completely soluble in water.

2. They form crystal lattices with FCC, BCC

type structures.

3. They are thermally stable.

4. They have high melting and boiling points.

5. The ionic character of these halides increases

from Li-halides to Cs-halides. Applications :

1. LiF solutions are used in the enamel industries. 2. LiCl is used in air–conditioning plants.

3. KBr is used in the photography.

Alkaline Earth Metal halides -

Alkaline earth metals form MX2 type compounds with halogens. These compounds are

Preparation : Alkaline earth metals combine with halogens to from halides.

e.g. Mg + Cl2 MgCl2

Properties :

1. Alkaline earth metal halides are covalent and polymeric compounds. 2. They are good conductors in molten state.

3. They are soluble in the organic solvents.

4. They form polymeric structure.

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Hydroxides

-Alkali Metal hydroxides -

Alkali metals form hydroxides MOH.

Preparation : Alkali metal hydroxides are prepared by the action of water on metals or metal oxides.

e.g. 2Na + H2O 2NaOH + H2

Na2O + H2O 2NaOH

Properties :

1. Alkali metal hydroxides are ionic compounds. They are completely soluble in water.

2. They are basic in nature. Their basic nature increases from

LiOH to CsOH.

3. In molten state these hydroxides are good conductors.

4. On sublimation they form dimmers.

5. The ionization increases from LiOH to CsOH, as size of

cation increases. Applications :

1. They are used as bases in number of chemical

reactions.

2. LiOH is used in the production of

photographic developer.

3. NaOH absorbs CO2 to form Na2CO3, sodium

carbonate.

4. Alcoholic solution of KOH is an important

Alkaline Earth Metal hydroxides -

Alkaline earth metals form hydroxides M(OH)2

Preparation : Alkaline earth metal hydroxides are prepared by the action of water on metals or metal oxides.

e.g. 2Ca + 2H2O 2Ca(OH)2 + H2

CaO + H2O Ca(OH)2

Properties :

1. Beryllium hydroxide Be(OH)2 is amphoteric in nature, while other hydroxides are basic in

nature.

2. Be(OH)2 is covalent while other hydroxides are ionic.

3. Be(OH)2 and Mg(OH)2 are insoluble in water. Solubility increases further and Ba(OH)2 is

most water soluble.

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Diagonal Relationship –

The first element of a group show similar properties with the second element of the next group. This is known as diagonal relationship.

Reason – In the periodic table, while moving from left to right atomic and ionic size decreases and polarizing power increases. While on moving from top to bottom, atomic and ionic size increases and polarizing power decreases. Thus when we consider these properties, the elements which are present diagonally show similar properties. This is called as diagonal relationship. The elements showing diagonal relationship are,

Groups IA IIA IIIA IVA VA VIA VIIA

Li Be B C N O F

Na Mg Al S P S Cl

Diagonal Relationship between Li and Mg –

i) Electronegativities of Li & Mg are 1.0 and 1.2 respectively. ii) Atomic radius of Li & Mg are 134 pm and 136 pm respectively.

iii) Ionic Radius of Li+ _{& Mg}+2 _{is 60 and 65 respectively.}

iv) They are hardest elements in their groups.

v) On heating with air or oxygen, they form monoxides Li2O and Mg2O

vi) They show comparable enthalpies of vaporization.

vii) They form ionic nitrides Li3N and Mg3N2

ix) Their carbonates, hydroxides and nitrates decompose on heating to form their oxides.

x) They form less soluble, less basic hydroxides LiOH & Mg(OH)2

xi) Their halides are soluble in alcohol and undergo hydrolysis in water. Diagonal Relationship between Be and Al –

i) Ionic Radius of Be+2 _{and Al}+3 _{is 30 pm and 50 pm resp.}

ii) Charge/radius ratio for both Be & Al is 6. iii) Electronegativity of Be & Al is 1.5

iv) Be & Al has same heat of vaporization.

v) They form covalent compounds due to their smaller size & high charge density. vi) Both Be & Al are resistant to acids.

vii) Both Be & Al become passive on reaction with nitric acid.

viii) Both Be & Al form stable complexes & they form dimers. Their dimmers are bridged compounds.

ix) They dissolve in strong alkali to form soluble complexes beryllates & aluminates.

x) Their oxides BeO and Al2O3 are amphoteric in nature.

xi) Be & Al reacts with NaOH & liberate hydrogen gas. xii) They form stable complexes.

xiii) Anhydrous chlorides of Be & Mg dissolve in organic solvents.