Group II element
Atomic and physical properties
Atomic size:
The average distance between a nucleus and valence orbit of an atom or ion is call atomic or ionic radius.
Trend
As we move from top to bottom in second group, atomic or ionic radius increases.
Reason: This is because an extra shell of electron is added in each element . The other factor is shielding affect. Due to increase atomic radius, shielding effect also increases. The atomic radii of these elements are however smaller than those of alkali metals in the same period. This is due to fact that alkaline earth metal have greater nuclear charge with tend to withdraw the electrons more towards the nucleus. Hence the atomic radii of alkaline earth metals are smaller than corresponding alkali metals in the same period.
Ionization energy
It may be defined as ''the minimum amount of energy required remove one mole of valance electrons to from one mole of gaseous uni-posive ions is called ionization energy''.
X --------> X+ + e- ionization energy
Trend
In group:
In the second group, on going from top bottom, the distance of ns2 electron from the nucleus increases and removal of valance electrons become more and more easy.
The other factor is the shielding effect. As we move from top to bottom, shielding increases that decreasesthe force of attraction between valance two electron and nucleus of an atom.
The value of ionization ionization energy of radon is slightly higher than barium.
Electronegativity
Electronegativity is a measure of tendency to attract a shared pair of electrons towards itself.
Units
No unit for electronegativity.
Trend
In group
On moving from to bottom in a group of element, electronegativity decrease.
Reason: In a group, atomic size of an atom increase due to the addition of extra shell so attraction between nucleus and valance electron decreases.
Melting and boiling Points
Melting and boiling points indicate about the strength of forces present among atoms, ions, molecule within a substance. in case of elements the value of melting and boiling points are according to inter atomic forces.
Trend
All moving from top to bottom in alkaline earth metal groups, melting point increases. Reason: This is because metallic character of elements increases down the group.
Therefore, melting and boiling points of alkaline earth metals are greater than alkali metals. The reason is that the group II elements have stronger metallic bond due to presence of two electrons.
Trend in reactivity with water
The group two elements are more reactive towards water as we go down the group then group one elements.
Be: No reaction with water
Mg:
Mg + H2O -----------> MgO + H2
Mg + H2O (cold( --------------> Mg(OH)2 + H2
M : Ca, Sr, Ba
M + H2O ---------------> M(OH)2 + H2
Reaction with oxygen and nitrogen
Formation of normal oxide
Alkaline earth metals from normal oxides by direct heating with oxygen are by heating their carbonates.
2M + O2 ----------> 2MO
M: Mg, Ca, Sr, Ba
MCO3 -----'> MO + CO2 (heat)
Properties of Alkaline earth metals oxides
I. These oxides are white crystalline solid and highly stable.
ii. BeO and MgO are quiet insoluble and water while other oxides react with water to produce metal hydroxide prelim oxide is amphoteric in nature
Reactions
BeO + 2HCl ------------>BeCl2 + H2O
BeO + 2NaOH------------>NaBeO2 + 2H2O
BeO is covalent due to small size of be2 + while other oxides are ionic all the Brazilian oxide is covalent it has higher melting point then outside of other metal believe oxide is harder than sides of other metal outside
Reason: as briley oxide is a polymeric in nature and each brillium is data hardly coordinated bounded with four other oxygen atoms.
Formation of peroxides
MO + O ----'----> MO2
Reaction with nitrogen
M + N2 -----------> M3N2
Mg + N2 -----------> Mg3N2
Ca + N2 -----------> Ca3N2
Sr + N2 -----------> Sr3N2
Ba + N2 -----------> Ba3N2
Friend insolubility in Hydroxide sulphate and carbonate
Solubility of hydroxide
Group 2 metal Hydroxide become more soluble as we move from top to bottom in the group.
Be(OH)2 and Mg(OH)2 almost insoluble in water.
Mg(OH)2 is known as milk of magnesia and used as an antacid.
Ca(OH)2 is slightly soluble in water (1g/L) and also known as lime water.
Ba(OH)2 is enough soluble in water (0.1 mole/L).
Solubility of sulphatej
Group II metal sulphates become less soluble as we move from top to bottom in a group. e.g. BeSO4, MgSO4 are fairly soluble in water.
CaSO4 is sufficiently soluble in water.
SrSO4 and BaSO4 aren't soluble in water. of carbonates
Solubility of carbonates
Group 2 metal carbonates become less soluble as we go from top to bottom in a group they are soluble and water containing CO2.
CaCO3 + CO2 + H2O ------'------> Ca(HCO3)2
Friends in thermal stability of carbonate and nitrates of group 2 elements
Group 2 elements carbonates
Effect of heat
All Metal carbonates decompose on heating.
MCO3----------------> MO + CO2
M : Ba, Mg, Ca, Sr, Ba
Thermal stability of group II elements increases on moving from top bottom.
BeCO3 decomposes at 25oC
MgCO3 decomposes at 540 oC
CaCO3 decomposes at 900 oC
SrCO3 decomposes at 1290 oC
BaCO3 decomposes at 1360 oC
Question: Why carbonates of IA group elements are more stable than IIA group elements?
Answer.
Reason: Cations of of IIA group are smaller in size so their charge densities are greater than IA group elements. The cations of small size and higher charge density have greater ability to polarise carbonate ion and hence facilities the decomposition.
Thus IIA group elements carbonates are less stable than IA group element carbonates.
Effect of heat on group second nitrates
All nitrates of elements undergo thermal decomposition to give metal oxide
M(NO3)2 ------------->MO + NO2 + O2
Be(NO3)2 ------------->MO + NO2 + O2
Mg(NO3)2 ------------->MO + NO2 + O2
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