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 `0.5 xx 10^(-3) and 8xx 10^^(-3)` M respectively . The equilibrium concentration of `H_2` 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

The equilibrium constant K_(p) for the reaction H_(2)(g)+I_(2)(g) hArr 2HI(g) changes if:

The equilibrium constant for the reaction: H 2 ​ (g)+I 2 ​ (g)⇔2HI(g) is 64, at certain temperature.The equilibrium concentrations of H2 and HI are 2 and 16 mollit −1 respectively. The equilibrium concentration (in molLit −1 ) of I2 ​ is ?

Equilibrium concentration of HI, I_(2) and H_(2) is 0.7, 0.1 and 0.1 M respectively. The equilibrium constant for the reaction, I_(2)+H_(2)hArr 2HI is :

The equilibrium constants for A_2 (g) hArr 2A(g) at 400 k and 600 k are 1xx 10^(-8) and 1 xx 10^(-2) respectively . The reaction is

The equilibrium constant at 717 K for the reaction: H_(2(g))+I_(2(g))lArr2HI_((g)) is 50. The equilibrium constant for the reaction: 2HI_(2(g))lArrH_(2(g))+I_(2(g)) is

For the reaction H_(2)(g)+I_(2)(g) hArr 2HI(g) , the rate of reaction is expressed as

On a given condition, the equilibrium concentration of HI , H_(2) and I_(2) are 0.80 , 0.10 and 0.10 mole/litre. The equilibrium constant for the reaction H_(2) + I_(2) hArr 2HI will be

At 500 K, the equilibrium costant for the reaction H_(2(g))+I_(2(g))hArr2HI_((g))" is "24.8" If "(1)/(2)mol//L of HI is present at equilibrium, what are the concentrations of H_(2)andI_(2) , assuming that we started by taking HI and reached the equilibrium at 500 K ?

Equilibrium concentration of HI,I2 and H2 is 0.7,0.1 and 0.1M respectively , Find Kc