What is sulfuric acid?
It is a mineral acid with the general formula H2SO4. In ancient times it was referred to as vitriol, vitriol oil, vitriolic acid and vitriol spirit.
It is a viscous, colorless, odorless liquid, soluble in water. It has a molecular mass of 98.079 g·mol-1. It has a density at 15 ºC of 1.8342 g·ml-1, a melting point of 10.5 ºC, and a boiling point of 274 ºC.
It has a strong acidic character that makes it very corrosive in high concentrations. It also has dehydrating and oxidizing properties. In addition, it is hygroscopic so it easily absorbs water vapor from the air.
|¡DANGER! «it is corrosive and causes severe chemical burns, even at even lower concentrations.«|
When we must dilute it with water, it is necessary to do it pouring the acid on the water, slowly and shaking.
Because of its acidic character, H2SO4 reacts with most bases to give the corresponding sulfate.
For example, cupric sulfate or copper (II) sulfate, which is used as a phytosanitary product, is prepared by the reaction of copper (II) oxide with sulfuric acid:
CuO (s) + H2SO4 (aq) → CuSO4 (aq) + H2O (l)
In addition, being a strong mineral acid, it has the ability to displace other weaker acids. For example, it displaces the salt of acetic acid (sodium acetate) when it reacts as follows to form sodium bisulfate:
H2SO4 + CH3COONa → NaHSO4 + CH3COOH
Similarly, the reaction of sulfuric acid with potassium nitrate produces nitric acid and a precipitate of potassium bisulfate.
In industry, sulfuric acid is a notable chemical, and countries' production data are used as an indicator of their industrial potential.
Therefore, it is an essential product in the chemical industry. It is widely used in the manufacture of fertilizers, explosives, mineral processing, wastewater treatment, petroleum refining, etc.
In addition, some of the most relevant end-use applications are: domestic drain uncloggers, electrolytes in lead batteries, cleaning agents, etc.
Aunque el ácido sulfúrico se descubrió en el siglo VIII, su producción solo se hizo económicamente viable en 1746, cuando el químico John Roebuck desarrolló una forma de producirlo a granel.
Nowadays, different H2SO4 production methods are used: such as the contact process, the wet sulfuric acid process, the lead chamber process, etc.
In the first stage of the process, sulfur is burned to obtain sulfur dioxide:
S (s) + O2 (g) → SO2 (g)
The sulfur dioxide is then oxidized to sulfur trioxide using oxygen and a vanadium catalyst. The reaction is exothermic and reversible.
2 SO2 (g) + O2 (g) ⇌ 2 SO3 (g) (in the presence of the V2O5 catalyst)
The sulfur trioxide is then absorbed in 97-98 % sulfuric acid to form disulfuric acid (H2S2O7), also known as fuming sulfuric acid. It is then diluted with water to obtain concentrated sulfuric acid.
H2SO4 (l) + SO3 (g)→ H2S2O7 (l)
H2S2O7 (l) + H2O (l) → 2 H2SO4 (l)
Directly dissolving SO3 in water is not practical, due to the very exothermic nature of the reaction. In addition, this reaction forms a corrosive aerosol, rather than a liquid, which is very difficult to separate.
SO3 (g) + H2O (l) → H2SO4 (l)