The preparation of NO₂ (g) from N₂ (g) and O₂ (g) is an endothermic reaction:

N₂ (g) + O₂ (g) → NO₂ (g) (unbalanced)

The enthalpy change of reaction for the balanced equation (with lowest whole number coefficients) is ΔH = 67.7kJ.

If 2.50 × 10²mL N₂ (g) at 100.°C and 3.50atm and 4.50 × 10² mL O₂ (g) at 100.°C and 3.50 atm are mixed, what amount of heat is necessary to synthesize the maximum yield of NO₂ (g)?

The preparation of NO_2(g) from N_2(g) and O_2(g) is an endothermic reaction:

The enthalpy change of reaction for the balanced equation (with the lowest whole number coefficients) is ΔH = 67.7 kJ. If 250 mL N_2(g) at 100°C and 3.50 atm and 450 mL O_2(g) at 100°C and 3.50 atm are mixed, what amount of heat is necessary to synthesize the maximum yield of NO_2(g)? 

Please show work and all parts. Thanks!

Nitric acid may be produced by oxidizing ammonia to nitric oxide over a platinum-rhodium catalyst, then oxidizing the nitric oxide to nitrogen dioxide in a separate unit where it is absorbed in water to form an aqueous solution of nitric acid. The three key reactions in the synthesis are the oxidation of the ammonia to nitric oxide and of nitric oxide to nitrogen dioxide, followed by dissolution of the NO₂ in water:

4NH₃(g)+ 5O₂(g)→ 4NO(g)+ 6H₂O(g)

2NO(g) + O₂(g) → 2NO₂(g)

4NO₂ (g)+ 2H₂O(l) + O₂(g) → 4HNO₃(aq)

In this problem, you may neglect side reactions that would lower the product yield. This would include the side reaction in which ammonia is oxidized to form nitrogen and water which can lower product yield.

4NH₃ + 3O₂ → 2N₂ + 6H₂O

Thus, for this project the overall reaction may be represented from the three key reactions above as:

NH₃ + 2O₂ → H₂O + HNO₃

Ammonia vapor at 275^oC and 8 atm is mixed with air, also at 275^oC and 8 atm, and the combined stream is fed to a converter. Fresh air entering the system at 30^oC and 1 atm with a relative humidity of 50% is compressed to 100^oC and 8 atm, and the compressed air then exchanges heat with the product gas leaving the converter. The quantity of oxygen in the feed to the converter is 20% in excess of the amount theoretically required to convert all the ammonia to HNO₃. The entire process after the compressor may be taken to operate at a constant pressure of 8 atm.

In the converter, the ammonia is completely oxidized, with a negligible amount of NO₂ formed. The product gas leaves the converter at 850^oC and exchanges heat with the air leaving the system as described earlier. The product gas is then fed to a waste-heat boiler that produces superheated steam at 200^oC and 10 bar from liquid water at 35^oC. The product gas leaving the waste-heat boiler is cooled further to 35^oC and fed to an absorption column in which the NO is completely oxidized to NO₂ which in turn combines with water (some of which is present in the product gas). Water is fed to the absorber at 25^oC, at a rate sufficient to form a 55 wt% aqueous nitric acid solution. Any NO formed in the reaction of NO₂ to produce HNO₃ is oxidized and the NO₂ produced is hydrated to form still more HNO₃. The off-gas from the process may be taken to contain only N₂ and O₂ and at 25^oC and 1 atm.

b). Taking a basis of 100 kmol of ammonia fed to the process

(i) kmol of water fed to the absorber

(ii). Temperature of the product gas after it has exchanged heat with the air, assuming no heat is transferred between the heat exchanger and the surroundings