For , A + B `hArr` C. the equilibrium concentration of A and B at a temperäture are 15 mol `lit^(-1)` When volume is doubled the reaction has equilibrium concentration of A as 10 mol `lit^(-1)` then

For A+BhArrC , the equilibrium concentrations of A and B at a temperature are 15 "mol" L^(-1) . When volume is doubled the reaction has equilibrium concentration of A is 10 "mol" L^(-1) . Calculate a. K_(c) b concentration of C in original equilibrium.

The equilibrium conatant for the reaction H_(2(g)) + I_(2(g)) hArr 2HI_((g)) is 2 at a certain temperature. The equilibrium concentrations of H_(2) and HI are 2 mole . lit^(-1) . What is the equilibrium concentration (in mole lit^(-1) ) of I_(2) ?

At 300 K, the equilibrium constant for a reaction is 10. the standard free energy change (in kJ mol^(-1) ) for the reaction is

The initial concentrations of A and B are same for A +2B harr 3C and when equilibrium concentrations of B and C are same then K_(c) is

The equilibrium constant for the reaction, H_(2)(g) + I_(2)(g) hArr 2HI(g) is 64 at a certain temperature. The equilibrium concentrations of H_(2) and HI are 2 mol//L and 16 mol//L respectively. What is the equilibrium concentration ( "in "mol//L ) of I_(2) ?

At a given temperature, for a reversible reaction, if the concentration of reactants is doubled then the equilibrium constant will

A to products. The concentration of A changes from 0.2 to 0.15 mol L^(-1) in 10 min. Calculate the average rate.