Two substance `A_(2)(g) ` and `B_(2)(g)` are allowed to react to form either of `A_(2)B_(2)(l), A_(2)B_(4)(g)` or both depending on relative amount.
Answer the following the following question, if 75 g `A_(2)` and `200g B_(2)` are mixed and no reactant is left.
[Given :At mass of A =25 , B=50]
What is the volume of all the gases present in the mixture after completion of reaction at 760 mm of Hg and `273^(@)` C?

A_(2) + 2B_(2) to A_(2)B_(4) and (3)/(2) A_(2) + 2B_(2) to A_(3) B_(4) Two substance A_(2) & B_(2) are allowed to react completely to from A_(2)B_(4) & A_(3)B_(4) mixture of leaving none of the reactants. Using this information calculate the composition of final mixture when mentioned amount of A_(2) & B_(2) are taken. (i) If (5)/(4) moles of A_(2) & 2 moles of B_(2) is taken (ii) If (7)/(2) moles of A_(2) & 6 moles of B_(2) is taken (iii) If 4 moles of A_(2) & 6 moles of B_(2) is taken

Substance A_(2)B(g) can undergo decomposition to form of set of products : if the molar ratio of A_(2)(g) to A(g) is 5 : 3 in a set of product gases, then energy involved in the decomposition of 1 mole of A_(2)B is :

When A_(2) and B_(2) are allowed to react, the equilibrium constant of the reaction at 27^(@)C is found (K_(C)=4).A_(2)(g)+B_(2)(g)hArr 2AB(g) What will be the equilibrium concentration of AB?

Te yield of product in the reaction A_(2(g))+B_(2(g))hArr2AB_((g)),DeltaH=+ve

In a reaction A_(2)(g)+4B_(2)(g) hArr 2AB_(4)(g), DeltaH lt 0 . The formation of AB_(4) is not favoured by

Substance A_(2)B(g) can undergo decomposition to form two set of products If the molar ratio of A_(2)(g)" to " A(g) is 5:3 in a set of product gases, then the energy involved in the decomposition of 1 mole of A_(2)B(g) is

Substance A_(2)B(g) can undergoes decomposition to form two set of products : If the molar ratio of A_(2)(g) to A(g) is 5 : 3 in a set of product gases, then the energy involved in the decomposition of 1 mole of A_(2)B(g) is :