Assertion `:-` Adding inert gas at equilibrium to dissociation of `PCL_(3)` at constant pressure increases the degree of dissociation.
Reason `:-` Since degree of dissociation `x` `alphasqrt(v)`

A 5% solution of anhydrous CaCI_(2) at 0^(@)C developed 15 atm osmotic pressure. What is the degree of dissociation of CaCI_(2) .

The van't Hoff factor for 0.1 M Ba(NO_(3))_(2) solution is 2.74 . The degree of dissociation is

At 35^(@)C , the value of K_(p) for the equilibrium reaction N_(2)O_(4)hArr2NO_(2) is 0.3174 , Calculate the degree of dissociation when P is 0.2382 atm

Acetic acid tends to form dimer due to formation of intermolcular hydrogen bonding. 2CH_(2)COOHhArr(CH_(3)COOH)_(2) The equilibrium constant for this reaction is 1.5xx10^(2)M^(-1) in benzene solution and 3.6xx10^(-2) in water. In benzene, monomer does not dissociate but it water, monomer dissociation simultaneously with acid dissociation constant 2.0xx10^(-5) M. Dimer does not dissociate in benzene as well as water. The molar ration of dimer to monomer for 0.1 M acetic acid in benzene is equal to :

The pressure P and volume V of a gas are related as PV^(3//2)=K where K is a constant. The percentage increase in the pressure for a diminution of 0.5% of the volume is

In 1 litre volume reaction vessel, the equilibrium constant K_(c) of the reaction PCl_(5)hArrPCl_(3)+Cl_(2) is 2xx10^(-4)" lit"^(-1) . What will be the degree of dissociation assuming only a small of 1 mole of PCl_(5) has dissociated ?

Acetic acid tends to form dimer due to formation of intermolcular hydrogen bonding. 2CH_(2)COOHhArr(CH_(3)COOH)_(2) The equilibrium constant for this reaction is 1.5xx10^(2)M^(-1) in benzene solution and 3.6xx10^(-2) in water. In benzene, monomer does not dissociate but it water, monomer dissociation simultaneously with acid dissociation constant 2.0xx10^(-5) M. Dimer does not dissociate in benzene as well as water. The pH of 0.1M acetic acid solution in water, considering the simultaneous dimerisation and dissociation of acid is :