Given that `K_(c )` for equation (i) given below has a value of `256` at `1000 K`. Calculate the numerical values of `K_(c )` for other reactions `(ii), (iii),` and `(iv)`.
i.

Given that K for equation (i) has a value of 256 at 1000 K. Calculate the numerical values of K for other reactions (ii),(iii) and (iv). (i) 2SO_2(g) + O_2(g) hArr 2SO_3(g) (ii) 2SO_3(g) hArr 2SO_2(g) +O_2(g) (iii) SO_2(g) +1/2O_2(g) hArr SO_3(g) (iv) SO_3 hArr SO_2(g) +1/2O_2(g)

At 1000K, the pressure of iodine gas is found to be 0.112 atm due to partial dissociation of I_(2)(g) into I(g). Had there been no dissociation, the pressure would have been 0.074 atm. Calculate the value of K_(p) for the reaction: I_(2)(g) hArr 2I(g) .

If 3 = k (mod 2) then the remainder k is (i) 0 (ii)4 (iii)1 (iv) 3

At 1000K , the pressure of iodine gas is found to be 0.1 atm due to partial dissociation of I_(2)(g) into I(g) . Had there been no dissociation, the pressure would have been 0.07 atm . Calculate the value of K_(p) for the reaction: I_(2)(g)hArr2I(g) .

K_(p) for the reaction given below is 1.36 "at" 499K . Which of the following equations can be used to calculate K_(c) for this reaction? N_(2)O_(5(g))rarrNO_(2(g)+NO_(3))

For reaction HI hArr1//2 H_(2) + 1//2 I_(2) value of K_(c) is 1//8 , then value of K_(c) for H_(2) + I_(2) hArr2HI .

The value K_(c) of a reaction has a higher value at higher temperature. The reaction is axothermic in nature.