One mole of `H_(2)` and 2 moles of `I_(2) ` are taken initially in a two litre vessel. The number of moles of `H_(2)` at equilibrium is 0.2. Then the number of moles of `I_(2)` and `HI` at equilibrium is

1 mol of hydrogen and 2 mol of iodine are taken initially in a 2L vessel. The number of moles of hydrogen at equilibrium is 0.2 . Then the number of moles of iodine and hydrogen iodide at equilibrium are

Consider the following reaction equilibrium N_(2)(g) + 3H_(2)(g) hArr 2NH_(3)(g) Initially, 1 mole of N_(2) and 3 moles of H_(2) are taken in a 2 flask. At equilibrium state if, the number of moles of N_(2) is 0.6, what is the total number of moles of all gases present in the flask ?

In 5 litre container 1 mole of H_(2) and 1 mole of I_(2) are taken initially and at equilibrium of HI is 40% . Then K_(p) will be

Hydrogen (a moles ) and iodine (b moles ) react to give 2x moles of the HI at equilibrium . The total number of moles at equilibrium is

2 mole of H_(2) and "1 mole of "I_(2) are heated in a closed 1 litre vessel. At equilibrium, the vessel contains 0.5 mole HI. The degree of dissociation of H_(2) is

15 moles of H_(2) and 5.2 moles of I_(2) are mixed and allowed to attain equilibrium at 500^(@)C . At equilibrium, the number of moles of HI is found to be 10 mole. The equilibrium constant for the formation of HI is

5 moles of SO_(2) and 5 moles of O_(2) react in a closed vessel. At equilibrium 60% of the SO_(2) is consumed . The total number of gaseous moles (SO_(2),O_(2)andSO_(3)) in the vessel is :-

Number of moles of H_(2) formed in the hydrolysis of a mole of borazole is :