One mole of A (g) is heated to `200^@` C in a one litre closed flask, till the following equilibrium is reached.
`A(g) leftrightarrow B(g)`
The rate of forward reaction, at equilibrium, is 0.02 ` mol L^(-1) mi n^(-1)`. What is the rate (in ` mol L^(-1)mi n^(-1)`) of the backward reaction at equilibrium?

1 mole of A_((g)) is heated to 200^@ C in a one litre closed flask, till the following equilibrium is reached. A_((g)) Leftrightarrow B_(g)) . The rate of forward reaction at equilibrium is 0.02 mol lit ""^(-1) "min"^(-1) . What is the rate ("mol. Lit"^(-1)" min"^(-1)) of the backward reaction at equilibrium?

Observe the following reaction: A(g) + 3B(g) rarr 2C(g) The rate of this reaction {(-d[A])/(d t)} is 3 xx 10^(-3) "mol litre"^(-1) "min"^(-1) . What is the value of (-d[B])/(d t) in mol "litre"^(-1) "min"^(-1) ?

Equilibrium constant for the reaction H_(2)O_((g))+CO_((g)) Leftrightarrow H_(2(g))+CO_(2(g)) is 81. If the rate constant of the forward reaction is 162 lit mol^(-1), sec^(-1) , what is the velocity constnat ("in lit." mole"^(-1) sec^(-1)) for the backward reaction?

9.2gm of N_(2)O_(4) (g) is taken is a closed one litre vessel and heated till the following equilibrium is reached N_(2)O_(4) (g) harr 2 NO_(2) (g) . At equilibrium 50% of N_(2)O_(4)(g) is dissociated. What is the equilibrium constant (in mole lit^(-1) ) ?.(M.wt.of N_(2)O_(4) is 92)

The equilibrium constant for the reaction is H_(2)O_((l))+CO_((g)) Leftrightarrow H_(2(g))+CO_(2(g)) is 64. If the rate constant for the forward reaction is 160, the rate constant for the backward reaction is

9.2 grams of N_(2)O_(4(g)) is taken in a closed one litre vessel and heated till the following equilibrium is reached N_(2)O_(4(g))hArr2NO_(2(g)) . At equilibrium, 50% N_(2)O_(4(g)) is dissociated. What is the equilibrium constant (in mol litre^(-1) ) (Moleculatr weight of N_(2)O_(4) = 92 ) ?