[" 1.3.Given the reaction between "2" gases represented "],[" by "A_(2)" and "B_(2)" to give the compound "AB(g)" ."],[A_(2(d))+B_(2(j))=2AB_((d))" ."],[" At equilibrium,the concentration "]

Given the reaction between 2 gases represented by A_(2) and B_(2) to given the compound AB(g). A_(2)(g) + B_(2)(g)hArr 2AB(g) At equilibrium, the concentrtation of A_(2) = 3.0xx10^(-3) M of B_(2) = 4.2xx10^(-3) M of AB = 2.8xx10^(-3) M If the reaction takes place in a sealed vessel at 527^(@)C . then the value of K_(c) will be

Given the reaction between 2 gases represented by A_(2) and B_(2) to given the compound AB(g). A_(2)(g) + B_(2)(g)hArr 2AB(g) At equilibrium, the concentrtation of A_(2) = 3.0xx10^(-3) M of B_(2) = 4.2xx10^(-3) M of AB = 2.8xx10^(-3) M If the reaction takes place in a sealed vessel at 527^(@)C . then the value of K_(c) will be

Given the reaction between 2 gases represented by A_(2) and B_(2) to given the compound AB(g). A_(2)(g) + B_(2)(g)hArr 2AB(g) At equilibrium, the concentrtation of A_(2) = 3.0xx10^(-3) M of B_(2) = 4.2xx10^(-3) M of AB = 2.8xx10^(-3) M If the reaction takes place in a sealed vessel at 527^(@)C . then the value of K_(c) will be

Given, the reaction between two gases represented by A_2 and B_2 to give the compound AB(g). A_2(g) + B_2(g) iff 2AB(g) At equilibrium, the concentration of A_2 = 3.0xx10^-3M of B_2 = 4.2 xx 10^-3M of AB = 2.8 xx 10^-3M If the reaction takes place in a sealed vessel at 527^@C , then the value of K_c will be

Given the reaction between 2 gases represented by A_2 and B_2 to give the compound AB(g) is A_2(g)+B_2(g) hArr 2AB(g) . At equilibrium, concentration of A_2=3.0xx10^(-3)(M) . If the reaction takes place in a sealed vessel at 527^(@)C , then value of K_c will be-

At constant temperature 80% AB dissociates into A_(2) and B_(2) then the equilibrium constant for 2AB_((g)) harr A_(2(g)) +B_(2(g))

The K_(c) for given reaction will be A_(2(g))+2B_((g))hArrC_((g))+2D_((g))