Calculate `K_(c )` for the reaction `KI + I_(2) hArr KI_(3)`. Given that initial weight of `KI` is `1.326 g` weight of `KI_(3)` is `0.105 g` and number of moles of free `I_(2)` is `0.0025` at equilibrium the volume of solution is `1-L`.

In the reaction 2CuSO_(4)+4KI rarr 2Cu_(2)I_(2)+I_(2)+2K_(2)SO_(4) the equivalent weight of CuSO_(4) will be:

The value of K_(c) for the reaction : H_(2)(g)+I_(2)(g)hArr 2HI(g) is 45.9 at 773 K. If one mole of H_(2) , two mole of I_(2) and three moles of HI are taken in a 1.0 L flask, the concentrations of HI at equilibrium at 773 K.

The value of K_(c) for the reaction: H_(2)(g)+I_(2)(g) hArr 2HI (g) is 48 at 773 K. If one mole of H_(2) , one mole of I_(2) and three moles of HI are taken in a 1L falsk, find the concentrations of I_(2) and HI at equilibrium at 773 K.

The value of K_(c) for the reaction H_(2)(g)+I_(2)(g) hArr 2HI(g) is 64 at 773K . If one "mole" of H_(2) , one mole of I_(2) , and three moles of HI are taken in a 1 L flask, find the concentrations of I_(2) and HI at equilibrium at 773 K .

K_(2)CrO_(4) oxidises KI in the presence of KCl to I_(2) . The equivalent weight of the K_(2)CrO_(4) is

K_2 CrO_4 oxidises KI in the presence of HCl to I_2 . The equivalent weight of the K_2 CrO_4 is.

FeCl_(3)+KI to Fe^(2+)(aq.)+KI + I_(2)

One mole of acidified K_(2)Cr_(2)O_(7) in reaction with excess KI will liberate …… moles of I_(2)