History of chemical industry

Chemical industry

History of chemical industry

Sulfuric Acid

sulfuric acid, chemical compound, H2SO4, colorless, odorless, extremely corrosive, oily liquid. It is sometimes called oil of vitriol.

1749: The Sulfuric Acid began to be produced and manufactured with the use and application of the Leaden Condensing Chambers.

In 1746 John Roebuck developed the lead chamber process for the manufacture of sulfuric acid. Prior to this time, sulfuric acid had been produced in glass bottles several pounds at a time. But the lead chamber process could produce sulfuric acid by the ton.

In the original lead chamber process, sulfur and potassium nitrate are ignited in a room lined with lead foil. Potassium nitrate, or saltpeter is an oxidizing agent oxidizes the sulfur to sulfur trioxide according to the reaction:

6 KNO₃(s) + 7 S(s) -----> 3 K₂S + 6 NO(g) + 4 SO₃(g)

The floor of the room was covered with water. When the sulfur trioxide reacted with the water, sulfuric acid was produced:

SO₃(g) + H₂O(l) -----> H₂SO₄(aq)

This process was a batch process and resulted in the consumption of potassium nitrate

In 1835, Joseph Gay-Lussac invented a process for recovering the nitrogen in nitrogen monoxide and recycling it to replace the saltpeter as a source of nitrogen.

4 NO(g) + O₂(g) + 2 H₂O(l) -----> 4 HNO₂(l)

4 HNO₂(l) + 2 SO₂(g) -----> 2 H₂SO₄(aq) + 4 NO(g)

This accomplished two things simultaneously: it reduced the dependence on expensive saltpeter and at the same time sharply reduced nitrogen monoxide emissions. The only

requirement now for saltpeter was to make up for the lost nitrogen monoxide.

Lead Chamber Process

In the lead chamber process hot sulfur dioxide gas enters the bottom of a reactor called a Glover tower where it is washed with nitrous vitriol (sulfuric acid with nitric oxide, NO, and nitrogen dioxide, NO 2, dissolved in it) and mixed with nitric oxide and nitrogen dioxide gases; some of the sulfur dioxide is oxidized to sulfur trioxide and dissolved in the acid wash to form tower acid or Glover acid (about 78% H 2SO 4). From the Glover tower a mixture of gases (including sulfur dioxide and trioxide, nitrogen oxides, nitrogen, oxygen, and steam) is transferred to a lead-lined chamber where it is reacted with more water. The chamber may be a large, boxlike room or an enclosure in the form of a truncated cone. Sulfuric acid is formed by a complex series of reactions; it condenses on the walls and collects on the floor of the chamber. There may be from three to twelve chambers in a series; the gases pass through each in succession. The acid produced in the chambers, often called chamber acid or fertilizer acid, contains 62% to 68% H 2SO 4. After the gases have passed through the chambers they are passed into a reactor called the Gay-Lussac tower where they are washed with cooled concentrated acid (from the Glover tower); the nitrogen oxides and unreacted sulfur dioxide dissolve in the acid to form the nitrous vitriol used in the Glover tower. Remaining waste gases are usually discharged into the atmosphere.

Contact Process

In the contact process, purified sulfur dioxide and air are mixed, heated to about 450°C, and passed over a catalyst; the sulfur dioxide is oxidized to sulfur trioxide. The catalyst is usually platinum on a silica or asbestos carrier or vanadium pentoxide on a silica carrier. The sulfur trioxide is cooled and passed through two towers. In the first tower it is washed with oleum (fuming sulfuric acid, 100% sulfuric acid with sulfur trioxide dissolved in it). In the second tower it is washed with 97% sulfuric acid; 98% sulfuric acid is usually produced in this tower. Waste gases are usually discharged into the atmosphere. Acid of any desired concentration may be produced by mixing or diluting the products of this process.

1791: Nicolas LeBlanc patented the Leblac process, which was an industrial process for the production of soda ash (sodium carbonate) from sea salt (sodium chloride). In 1823, production of Soda Ash was started by a British Entrepreneur.

The Leblanc process was a batch process in which sodium chloride was subjected to a series of treatments, eventually producing sodium carbonate. In the first step, the sodium chloride was heated with sulfuric acid to produce sodium sulfate (called the salt cake) and hydrochloric acid gas according to the chemical equation

2 NaCl + H₂SO₄ → Na₂SO₄ + 2HCl

This chemical reaction had been discovered in 1772 by the Swedish chemist Carl Wilhelm Scheele. Leblanc's contribution was the second step, in which the salt cake was mixed with crushed limestone (calcium carbonate) and coal and fired. In the ensuing chemical reaction, the coal (carbon) was oxidized to carbon dioxide, reducing the sulfate to sulfide and leaving behind a solid mixture of sodium carbonate and calcium sulfide, called black ash.

Na₂SO₄ + CaCO₃ + 2 C → Na₂CO₃ + CaS + 2 CO₂

Because sodium carbonate is soluble in water, but neither calcium carbonate nor calcium sulfide is, the soda ash was then separated from the black ash by washing it with water. The wash water was then evaporated to yield solid sodium carbonate. This extraction process was termed lixiviation.

1804: St. Rollox Chemical Works produced almost 10,000 tons of bleaching powder, improving exponentially its production of 52 tons in 1799. Created by Charles Tennant (who discovered the bleaching powder), it was considered as the first biggest chemical enterprise in the world.

The most common chlorine-based bleaches are:

Sodium hypochlorite (NaClO), usually as a 3–6% solution in water, usually called "liquid bleach" or just "bleach". Historically called "Javel water". It is used in many households to whiten laundry, disinfect hard surfaces in kitchens and bathrooms, treat water for drinking and keep swimming pools free of infectious agents.
Bleaching powder (formerly known as "chlorinated lime"), usually a mixture of calcium hypochlorite(Ca(ClO)
2), calcium hydroxide (lime, Ca(OH)
2), and calcium chloride (CaCl
2) in variable amounts.
Sold as a white powder or in tablets, is used in many of the same applications as sodium hypochlorite, but is more stable and contains more available chlorine.

1859: The first oil well is drilled successfully near Titusville, Pennsylvania. This oil well of 70 feet marked the beginning of the Petroleum Industry.

1855: Bejamín Silliman, from New Haven, Conneticut, obtained valuable products from the destillation of petroleum. Between these valuable products were the naphthalene, gasoline, tar and other solvents.

1918: Fritz Haber won and received the Nobel Prize for his work in the synthesis of ammonia.  Nevertheless, this method was adapted for its commercial use until 1930 by the german chemist Carl Bosh

1931: First appearance of the first synthetic rubber.

1933: The Imperial Chemical Industries, England, discovered the polyethylene.

1935: Wallace H. Carothers, Du Pont, discovered the nylon.

1937: Dow Chemical began to commercialize the polystyrene

1940: In United States the first synthetic rubber tire was produced

1943: USA produced the DDT (dichlorodiphenyltrichloroethane), which was used for its insecticidal properties

Sulfuric acid

Sulfuric acid is by far the largest single product of the chemical industry.

Chamber process for Sulphuric acid

When sulfur is burned in air, sulfur dioxide is formed, and this, when combined with water, gives sulfurous acid. To form sulfuric acid, the dioxide is combined with oxygen to form the trioxide, which is then combined with water. A technique to form the trioxide, called the chamber process, developed in the early days of the operation of the Leblanc process. In this technique the reaction between sulfur dioxide and oxygen takes place in the presence of water and of oxides of nitrogen. Because the reaction is rather slow, sufficient residence time must be provided for the mixed gases to react. This gaseous mixture is highly corrosive, and the reaction must be carried out in containers made of lead.

SO 2 + NO 2 + H 2 O → H 2 SO 4 + NO

NO + 1/2 O 2 → NO2

Sodium carbonate

In 1775 the French Academy of Sciences offered an award for a practical method for converting common salt, sodium chloride, into sodium carbonate, a chemical needed in substantial amounts for the manufacture of both soap and glass. Nicolas Leblanc, a surgeon with a bent for practical chemistry, invented such a process. His patron, the duc d’Orléans, set up a factory for the process in 1791, but work was interrupted by the French Revolution. The process was not finally put into industrial operation until 1823 in England, after which it continued to be used to prepare sodium carbonate for almost 100 years.

Leblanc process

The first step in the Leblanc process was to treat sodium chloride with sulfuric acid. This treatment produced sodium sulfate and hydrogen chloride. The sodium sulfate was then heated with limestone and coal to produce black ash, which contained the desired sodium carbonate, mixed with calcium sulfide and some unreacted coal. Solution of the sodium carbonate in water removed it from the black ash, and the solution was then crystallized. From this operation derives the expression soda ash that is still used for sodium carbonate.

2 NaCl + H 2 SO 4 → Na 2 SO 4 + 2 HCl

followed by conversion of the sulfate to soda with charcoal and chalk

Na 2 SO 4 + 2 C + CaCO 3 → Na 2 CO 3 + CaS + 2 CO2

It was soon found that when hydrogen chloride was allowed to escape into the atmosphere, it caused severe damage to vegetation over a wide area. To eliminate the pollutionproblem, methods to convert the dissolved hydrogen chloride to elemental chlorine were developed. The chlorine, absorbed in lime, was used to make bleaching powder, for which there was a growing demand.

Because calcium sulfide contained in the black ash had a highly unpleasant odour, methods were developed to remove it by recovering the sulfur, thereby providing at least part of the raw material for the sulfuric acid required in the first part of the process. Thus the Leblanc process demonstrated, at the very beginning, the typical ability of the chemical industry to develop new processes and new products, and often in so doing to turn a liability into an asset.

The ammonia-soda (Solvay) process

The Leblanc process was eventually replaced by the ammonia-soda process (called the Solvay process), which was first practiced successfully in Belgium in the 1860s. In this process, sodium chloride as a strong brine is treated with ammonia and carbon dioxide to give sodium bicarbonate and ammonium chloride. The desired sodium carbonate is easily obtained from the bicarbonate by heating. Then, when the ammonium chloride is treated with lime, it gives calcium chloride and ammonia. Thus, the chlorine that was in the original sodium chloride appears as calcium chloride, which is largely discarded (among the few uses for this compound is to melt snow and ice from roads and sidewalks). The ammonia thus regenerated is fed back into the first part of the process. Efficient recovery of nearly all the ammonia is essential to the economic operation of the process, the loss of ammonia in a well-run operation being no more than 0.1 percent of the weight of the product.

NH 3 + H 2 O + CO 2 → NH 4 HCO 3

NaCl + NH 4 HCO 3 → NaHCO 3 + NH 4 Cl

2 NaHCO 3 → Na 2 CO 3 + H 2 O + CO2

Electrolytic process

Later in the 19th century the development of electrical power generation made possible the electrochemical industry. This not clearly identifiable branch of the chemical industry includes a number of applications in which electrolysis, the breaking down of a compound in solution into its elements by means of an electric current, is used to bring about a chemical change. Electrolysis of sodium chloride can lead to chlorine and either sodium hydroxide (if the NaCl was in solution) or metallic sodium (if the NaCl was fused). Sodium hydroxide, an alkali like sodium carbonate, in some cases competes with it for the same applications, and in any case the two are interconvertible by rather simple processes. Sodium chloride can be made into an alkali by either of the two processes, the difference between them being that the ammonia-soda process gives the chlorine in the form of calcium chloride, a compound of small economic value, while the electrolytic processes produce elemental chlorine, which has nearly innumerable uses in the chemical industry, including the manufacture of plastic polyvinyl chloride, the plastic material produced in the largest volume. For this reason the ammonia-soda process, having displaced the Leblanc process, has found itself being displaced, the older ammonia-soda plants continuing to operate very efficiently but no new ammonia-soda plants being built.

Contact process

Lead is a material awkward to use in construction, and the process cannot deliver acid more concentrated than about 78 percent without special treatment. Therefore, the chamber process has been largely replaced by the contact process, in which the reaction takes place in a hot reactor, over a platinum or vanadium compound catalyst, a substance that increases the speed of the reaction without becoming chemically involved.

Sulfuric acid is manufactured in three stages

2 SO 2 + O 2 → 2SO 3

SO 3 + H 2 O → H 2 SO 4

Since the reaction of sulfur with dry air is exothermic, the sulfur dioxide must be cooled to remove excess heat and avoid reversal of the reaction

Carbon disulfide

Carbon disulfide is made by the reaction of carbon and sulfur. Carbon comes from natural gas, and the sulfur may be supplied in the elemental form, as hydrogen sulfide, or as sulfur dioxide. The chief uses of carbon disulfide are for the manufacture of rayon and for regenerated cellulose film. These two products are made in such large quantity that carbon disulfide is a heavy chemical, by any standard.

Nitric acid

By far the most important use of ammonia within the chemical industry is to produce nitric acid (HNO3). Nitrogen and oxygen can be made to combine directly with one another only with considerable difficulty. A process based on such a direct combination, but employing large quantities of electrical power, was in use in the 1920s and 1930s in Norway, where hydroelectric power is readily available. It has not proved economical in modern conditions.

Ammonia burns in air, or in oxygen, causing the hydrogen atoms to burn off, forming water and leaving free nitrogen. With the aid of a catalyst, platinum with a small percentage of the related metal rhodium, ammonia is oxidized to oxides of nitrogen that can be made to react with water to form nitric acid.

Nitric acid treated with ammonia gives ammonium nitrate, a most important fertilizer. Ammonium nitrate, moreover, is also an important constituent of many explosives. Three fundamental explosive materials are obtained by nitrating (treating with nitric acid, often in a mixture with sulfuric acid): cellulose, obtained from wood, gives cellulose nitrate (formerly called nitrocellulose); glycerol gives glyceryl trinitrate (formerly called nitroglycerin); and toluene gives trinitrotoluene, or TNT. Another explosive ingredient is ammonium picrate, derived from picric acid, the relationship of which appears more clearly in its systematic name, 2,4,6-trinitrophenol.

A minor but still important segment of the explosives industry is the production of detonating agents, or such priming compositions as lead azide [Pb(N3)2], silver azide (AgN3), and mercury fulminate [Hg(ONC)2]. These are not nitrates or nitro compounds, although some other detonators are, but they all contain nitrogen, and nitric acid is involved in their manufacture.