What volume of `H_(2)(g)` is produced by decomposition of `2.4 L NH_(3) (g)` ? .

What volume of CO_2 at STP is obtained by thermal decomposition of 20g KHCO_3 ? [Atomic weight of K=39 g mol ^(−1) ] 2 KHCO_3(s)⟶K_2O(s)+2CO_2 (g)+H_2O(g)

What volume of H_(2) at NTP is required to convert 2.8 g of N_(2) into NH_(3) ?

The mass of N_(2)F_(4) produced by the reaction of 2.0 g of NH_(3) and 8.0 g F_(2) is 3.56 g. What is the per cent yield ?

N_(2)(g)+3H_(2)(g) hArr 2NH_(3)(g), DeltaH^(ɵ)=-22.4 kJ The pressure inside the chamber is 100 atm and temperature at 300 K If K_(p) for the reaction is 1.44xx10^(-5) , then the value of K_(p) for the decomposition of NH_(3) 2NH_(3)(g) hArr N_(2)(g)+3H_(2)(g) will be:

Use equation 2H_(2)O(l) to 2H_(2)(g) to answer the following What volume of O_(2) will be produced if the volume of H_(2) produced is 2500 cm^(3) under similar conditions?

What mass of CH_(3)OH ("methanol") will be produced by reacting 1120L of H_(2)(g) at STP with excess CO(g) ? .

The mass of N_2F_4 produced by the reaction of 2.0g of NH_3 and 8.0g of F_2 is 3.56g . What is the per cent yield ?

What total volume , in litre at 627^(@) C and 0.821 atm, could be formed by the decomposition of 16 gm of NH_(3)NO_(3) ?Reaction : 2NH_(4)NO_(3) to 2N_(2) + O_(2) + 4H_(2)O_((g)) .

One "mole" of NH_(4)HS(s) was allowed to decompose in a 1-L container at 200^(@)C . It decomposes reversibly to NH_(3)(g) and H_(2)S(g). NH_(3)(g) further undergoes decomposition to form N_(2)(g) and H_(2)(g) . Finally, when equilibrium was set up, the ratio between the number of moles of NH_(3)(g) and H_(2)(g) was found to be 3 . NH_(4)HS(s) hArr NH_(3)(g)+H_(2)S(g), K_(c)=8.91xx10^(-2) M^(2) 2NH_(3)(g) hArr N_(2)(g)+3H_(2)(g), K_(c)=3xx10^(-4) M^(2) Answer the following: What is the "mole" fraction of hydrogen gas in the equilibrium mixture in the gas phase?

One "mole" of NH_(4)HS(s) was allowed to decompose in a 1-L container at 200^(@)C . It decomposes reversibly to NH_(3)(g) and H_(2)S(g). NH_(3)(g) further undergoes decomposition to form N_(2)(g) and H_(2)(g) . Finally, when equilibrium was set up, the ratio between the number of moles of NH_(3)(g) and H_(2)(g) was found to be 3 . NH_(4)HS(s) hArr NH_(3)(g)+H_(2)S(g), K_(c)=8.91xx10^(-2) M^(2) 2NH_(3)(g) hArr N_(2)(g)+3H_(2)(g), K_(c)=3xx10^(-4) M^(2) Answer the following: To attain equilibrium, how much % by weight of folid NH_(4)HS got dissociated?