For the dissociation reaction `N_(2)O_(4) (g)hArr 2NO_(2)(g)`, the degree of dissociation `(alpha)`interms of `K_(p)` and total equilibrium pressure P is:

For the reaction, N_(2)O_(4)(g)hArr 2NO_(2)(g) the reaction connecting the degree of dissociation (alpha) of N_(2)O_(4)(g) with eqilibrium constant K_(p) is where P_(tau) is the total equilibrium pressure.

For the reaction, N_(2)O_(4)(g)hArr 2NO_(2)(g) the degree of dissociation at equilibrium is 0.l4 at a pressure of 1 atm. The value of K_(p) is

For the reaction N_(2)O_(4)(g)hArr2NO_(2)(g) , the degree of dissociation at equilibrium is 0.2 at 1 atm pressure. The equilibrium constant K_(p) will be

For the dissociation reaction N_(2)O_(4)(g)hArr2NO_(2)(g), the equilibrium constant K_(P) is 0.120 atm at 298 K and total pressure of system is 2 atm. Calculate the degree of dissociation of N_(2)O_(4) .

If in the reaction, N_(2)O_(4)(g)hArr2NO_(2)(g), alpha is the degree of dissociation of N_(2)O_(4) , then the number of moles at equilibrium will be

In the dissociation of PCl_(5) as PCl_(5)(g) hArr PCl_(3)(g)+Cl_(2)(g) If the degree of dissociation is alpha at equilibrium pressure P, then the equilibrium constant for the reaction is

The equilibrium constant (K_(p)) for the decomposition of gaseous H_(2)O H_(2)O(g)hArr H_(2)(g)+(1)/(2)O_(2)(g) is related to the degree of dissociation alpha at a total pressure P by

For the reaction 2HI(g)hArrH_(2)(g)+I_(2)(g) The degree of dissociation (alpha) of HI(g) is related to equilibrium constant K_(p) by the expression a. (1+2sqrt(K_(p)))/2 , b. sqrt((1+2K_(p))/2) c. sqrt((2K_(p))/(1+2K_(p))) , d. (2sqrt(K_(p)))/(1+2sqrt(K_(p)))

The equilibrium constant for the decomposition of water H_2O(g) hArr H_2(g)+1/2O_2(g) is given by : ( alpha =degree of dissociation of H_2O (g) p=Total equilibrium pressure)

For the reaction PCl_(5)(g)hArr PCl_(3)(g)+Cl_(2)(g) , the equation connecting the degree of dissociation (alpha) of PCl_(5)(g) with the equilibrium constant K_(p) is