For the reaction 2HI(g)hArrH(2)(g)+I(2...

For the reaction
`2HI(g)hArrH_(2)(g)+I_(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)))`

Similar Questions

Explore conceptually related problems

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)))

For the reaction 2AB(g)hArrA_(2)(g)+B_(2)(g) The degree of dissociation (alpha) of HI(g) is related to equilibrium constant K_(p) by the expression

For the reaction, 2HI(g) iff H_2(g) +I_2 (g) the degree of dissociation ( alpha ) of HI (g) is related to the equilibrium constant, K_p by expression

In the reversible reaction, 2HI(g) hArr H_(2)(g)+I_(2)(g), K_(p) is

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

For reaction H_(2)(g) +I_(2)(g) hArr 2HI (g) The value of K_(p) changes with

For the reaction `2HI(g)hArrH_(2)(g)+I_(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)))`

Similar Questions

Recommended Questions

For the reaction
`2HI(g)hArrH_(2)(g)+I_(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)))`