K_c = 

There are four moles of reactants and two moles of products. Avogadro's law equates moles of gas with volume. Increasing the pressure will reduce the volume so making the position of equilibrium move to the side with less volume, i.e. increase the yield of ammonia.

It makes the catalyst more efficient by increasing the surface area.

As the reaction is exothermic heat is evolved (i.e. heat is a product), so increasing the temperature (adding heat) will lower the value of K_c to move the position of equilibrium to the reactant side..

3NO₂(g) + H₂O(l)  →  2HNO₃(aq) + NO(g) shows disproportionation as the oxidation state of N in NO₂ is +4 and it has been oxidized to form HNO₃ (oxidation state of N = +5) and reduced to form NO (oxidation state of N = +2). In the other two reactions both NH₃ and NO are oxidized but not also reduced.

The electron configuration of N is 1s²2s²2p³ and the electron configuration of O is 1s²2s²2p⁴. This means that NO contains an odd number of electrons, one of which must be unpaired, so it is a free radical.

Energy in: 12 x N−H  = 12 x 391 = 4692 kJ
                + 5 x O=O  =  5 x 498  = 2490 kJ

                Total  energy required to break bonds     = + 7182 kJ

Energy out:   4 x NO

                 + 12 x O−H  = 12 x 463 = 5556 kJ

                Total energy released when bonds are formed  =  (5556 + (4 x NO)) kJ

ΔH = – 905 kJ so more energy is released than taken in

(5556 + 4NO) − 7182  = 905

4 x NO = 2531 kJ so NO bond enthalpy = 2531/4 = 633 kJ

N has five valence electrons and O has six valence electrons. This means that the bond between N and O is not a simple double bond as although the O atoms would then achieve its octet the N atom only has a share in 7 electrons. Alternatively if there is a triple bond N achieves its octet but O would have a share in 9 electrons. This means that the 'double bond' is actually stronger than a normal double bond, so the bond enthalpy is greater than the N=O bond.

NH₃ + HNO₃ → NH₄NO₃

1 tonne = 10⁶ g; M_r(NH₄NO₃) = (2 x 14.01) + (4 x 1.01) + (3 x 16.00) = 80.06

Amount of ammonium nitrate in 2750 tonnes = (2.750 x 10⁹) ÷ 80.06 = 3.435 x 10⁷ mol

1 mol of NH₃ required to produce 1 mol of NH₄⁺ and 1 mol of NH₃ required to produce NO₃⁻ (assuming all the NO in the third step of the Ostwald process is recycled) so amount of NH₃ required = 2 x 3.435 x 10⁷ mol

M_r(NH₃) = 14.01 + 3.03 = 17.04 so mass of ammonia required = 17.04 x 2 x 3.435 x 10⁷ = 1.171 x 10⁹ g = 1171 tonnes.

1 mol of NH₃ required to produce 1 mol of NH₄⁺

From equation (3):  1.5 mol of NO₂ required to produce 1 mol of HNO₃
From equation (2): 1.5 mol of NO required to produce 1.5 mol of NO₂
From equation (1): 1.5 mol of NH₃ required to produce 1.5 mol of NO
so 1.5 mol of NH₃ required to produce 1 mol of NO₃⁻

Total amount of NH₃ required to produce 2750 tonnes (3.435 x 10⁷ mol) of NH₄NO₃ = 2.5 x 3.435 x 10⁷ mol

Mass of ammonia required = 2.5 x 17.04 x 3.435 x 10⁷ = 1.463 x 10⁹ g = 1463 tonnes.

More energy is required to overcome the attraction between the NH₄⁺ and NO₃⁻ ions in the crystal lattice than is given out when the ions become hydrated. The extra energy required to dissolve the salt is taken from the water so the temperature goes down.

It is acidic as the salt is made from a strong acid and a weak base. OH⁻ ions will recombine with NH₄⁺ ions to form undissociated NH₃(aq) and H₂O leaving excess H⁺(aq) ions in solution.

Conjugate acid : NH₄⁺ 

Conjugate base: NH₂⁻

It will be positive as two moles of liquid (molten ammonium nitrate) become seven moles of gaseous products.

ΔG^⦵ = ΔH^⦵ –TΔS^⦵.  Since both ΔH^⦵ and –TΔS^⦵ have negative values, ΔG^⦵ will be negative for all values of T and so the reaction will be spontaneous at all temperatures.

Once sufficient energy has been provided (by a fire or through friction)  to provide the activation energy, the fast rate of the spontaneous reaction, the huge change in volume that takes place and the large amount of Gibbs energy released will all combine together to cause an explosion.

Fritz Haber only discovered the way to fix nitrogen from the air with hydrogen industrially in 1913 so the large scale mIB Docs (2) Teamfacture of ammonium nitrate was not possible before that date. (Some historians think that World War 1 would have not lasted so long if this discovery had not been made as the supply of nitrates from S. America required to make bombs and ammunition could have been blockaded).

Nitrogen dioxide, NO₂, a brown poisonous gas (which smells like chlorine) formed by the combination of NO(g) and O₂(g) at high temperatures.