A Since ancient Roman times (or before), it has been known (in somewhat differen
ID: 959830 • Letter: A
Question
Explanation / Answer
Solution 1:
Na2O and CaO are basic oxides and SiO2 is an acidic oxide
Thus, there exists an acid base reaction between Na2O and SiO2 to form Na2SiO3.
i.e., Na2O + SiO2 à Na2SiO3.
(we can also explain this reaction by using Lewis theory of acid basesas follows;
Na2O à 2 Na+ + O – 2
O – 2 (electron pair donor:base)+ SiO2 (electron pair acceptor: acid)à SiO3– 2
2Na+ + SiO3– 2 à Na2SiO3.
Similarly, CaO + SiO2 à CaSiO3.
Solution 2:
PH2– 1 + AsH3 à PH3 + AsH2– 1
In this reaction PH2– 1 is accepting proton from AsH3 , thus PH2- is a base and AsH3 is an acid according to Lowry and Bronsted theory.
According to Lowry and Bronsted theory, strong acid produced a conjugate weak base and weak base produces a conjugate strong acid
PH3 is a weak base with Ka = 10 – 28 and it is produced from PH2-1, thus PH2-1 is a strong acid.
As we know AsH3 is a weak base and thus its conjugate acid AsH2– 1 is strong acid.
Conclusions:
PH2– 1 - strong acid
PH3 – weak base
AsH3 – weak base
AsH2– 1 - Strong acid
PH2– 1 acting as a strong acid is un-usual trend here. However, this is a active species produced by liquid ammonia (as solvent) and Na metal at – 20°C upon reaction with phosphine (PH3).