`3O_(2)(g) hArr 2O_3 (g)`
for the above reaction at 298 K, K, is found to be `3.0xx10^(-59)` . If the concentration of `O_2` at equilibrium is 0.040 M then concentration of `O_3` in M is

The value of K_(c ) for the reaction 3O_(2)(g) hArr 2O_(3)(g) is 2.0xx10^(-50) at 25^(@)C . If the equilibrium aoncentration of O_(2) in air at 25^(@)C is 1.6xx10^(-2) , what is the concentration of O_(3) ?

The value of K_(c) " for the reaction , " 3 O_(2) (g) hArr 2 O_(3) (g) , "is " 2*0 xx 10^(-50) " at " 25^(@)C. " If the equilibrium concentration of " O_(2) " in air at " 25^(@)C " is " 1*6 xx 10^(-2), " What is the concentration of " O_(3) ?

When N_(2)O_(5) is heated at certain temperature, it dissociates as N_(2)O_(5)(g)hArrN_(2)O_(3)(g)+O_(2)(g),K_(c)=2.5 At the same time N_(2)O_(3) also decomposes as : N_(2)O_(3)(g)hArrN_(2)O(g)+O_(2)(g). "If initially" 4.0 moles of N_(2)O_(5) "are taken in" 1.0 litre flask and alowed to dissociate. Concentration of O_(2) at equilibrium is 2.5 M. "Equilibrium concentratio of " N_(2)O_(5) is :

The equilibrium constant for the reaction H_(2)(g)+I_(2)(g)hArr 2HI(g) is 32 at a given temperature. The equilibrium concentration of I_(2) and HI are 0.5xx10^(-3) and 8xx10^(-3)M respectively. The equilibrium concentration of H_(2) is