The equilibrium constant `K_(p)` for the reaction
`H_(2)(g)+CO_(2)(g)hArrH_(2)(g)+CO(g)`
is 4.0 at `1660^(@)C` Inittally 0.80`H_(2) and 0.80 mole CO_(2)` are injecteed into a 5.0 litre flask what is the equilibrium concentraton of `CO_(2)(g)`?

The equilibrium constant K_(c) for the reaction, 2NaHCO_(3)(s)hArrNa_(2)CO_(3)(s)+CO_(2)(g)+H_(2)O(g)

The value of K for H_(2)(g)+CO_(2)(g)hArr H_(2)O(g)+CO(g) is 1.80 at 1000^(@)C . If 1.0 mole of each H_(2) and CO_(2) placed in 1 litre flask, the final equilibrium concentration of CO at 1000^(@)C will be

For the equilibrium H_(2)(g)+CO_(2)(g)hArr hArr H_(2)O(g)+CO(g), K_(c)=16 at 1000 K. If 1.0 mole of CO_(2) and 1.0 mole of H_(2) are taken in a l L flask, the final equilibrium concentration of CO at 1000 K will be

At a certain temperature , the equilibrium constant (K_(c)) is 4//9 for the reaction : CO(g)+H_(2)O(g) hArr CO_(2)(g)+H_(2)(g) If we take 10 mole of each of the four gases in a one - litre container, what would be the equilibrium mole percent of H_(2)(g) ?

For the reaction CO(g) + 0.5O_(2)(g) rarr CO_(2)(g) K_(P)//K_(c) is equal to

Which of the following graphs are correct for the given reaction? H_(2(g))+CO_(2(g))hArrH_(2)O_((g))+CO_((g)) Assume initially only H_(2) and CO_(2) are present:

The equilibrium constant for the reaction CO(g) + H_(2)O(g)hArrCO_(2)(g) + H_(2)(g) is 3 at 500 K. In a 2 litre vessel 60 gm of water gas [equimolar mixture of CO(g) and H_(2) (g)] and 90 gm of steam is initially taken. What is the equilibrium concentration of H_(2)(g) at equilibrium (mole/L) ?