What is Synthetic Rubber?
Synthetic rubber is defined as any artificial elastomer. It is usually derived from the polyene monomers additional polymers and unless the synthetic rubber gets disclosed as a polysulfide rubber, and the laminates containing such a layer can be classified with additional polymers.
About Elastomer
Elastomer is described as the material with the mechanical property that can undergo much more elastic deformation, under stress compared to most of the materials and still return to its previous size without any permanent deformation. Synthetic rubber also serves as a substitute for natural rubber in several cases, especially when the improved material properties are needed.
History of Synthetic Rubber
The motor vehicles expanded use, especially the motor vehicle tires, starting in the 1890s, created an increased demand for rubber. Also, in 1909, a team headed by Fritz Hofmann working at the Bayer laboratory in Elberfeld, Germany has succeeded in the polymerization of Isoprene, which is the first synthetic rubber.
By 1940, the United States was effectively stockpiling natural rubber, doubling its normal imported quantity of around a half million tons a year. And, in 1941, Japan occupied South-East Asia by cutting off the natural rubber supplies to the United States. In the first response to its supply crisis, the U.S. government has ordered planting tens of thousands of acres of guayule. This shrub, which thrives in the western parts of the United States and Mexico, also has rubber latex. It also has the disadvantage of rubber yielding only with difficulty; the plant should be ground up and extracted, hence requiring a constant supply of new plants.
By the end of this war, petroleum served as the base for synthetic rubber, since it would present in the postwar years. Whereas the manufacturing process of petroleum usage was more complex, but on average, petroleum chemical was also cheaper, and the progress was rapid. B.F.Goodrich has done his early work in synthesis and became the largest successive producer of synthetic rubber during the war. The U.S. firms built 51 synthetic rubber factories in the period between 1942 and 1945. During that period, production has increased from 24,640 tons of synthetic rubber to more than 784000 tons from 1942 to 1945.
Synthetic Rubber vs Natural Rubber
Let us look at the major differences between Synthetic rubber and Natural rubber.
In November 1948, natural rubber became freely available at a lower price. Also, it remains to be seen if synthetic rubber, on uniformity and quality basis will continue to be voluntarily consumed under the present price relationship of natural rubber and synthetic rubber.
Other synthetic rubber examples can be listed as follows:
chloroprene, which is prepared by the polymerization of 2-chlorobutadiene
polyisoprene, which is prepared by the polymerization of synthetic isoprene
nitrile rubber, which is made from 2-propenenitrile and butadiene or cyanobutadiene
A considerable lag is there between the time of purchase to the time of consumption and prices may substantially vary in that period. Also, the test will come when the less priced natural rubber becomes more readily available and starts to enter into quantity consumption in the manufacturing establishments.
A widely used elastomer for external sheets like roof coverings is chlorosulphonated polyethylene or Hypalon. A new class of synthetic rubber is described as the thermoplastic elastomers that are moulded easily unlike conventional N.R. vulcanized rubber.
Their structure can be stabilized by cross-linking by the crystallites either in the case of SBS block copolymers or in the case of polyurethanes or by amorphous domains. Silicone rubber is defined as an inorganic polymer which is resistant to both very low and higher temperatures and can be widely used for catheters and also for other medical devices or equipment. However, its tensile strength is low compared with other synthetic rubbers.
Different Types of Synthetic Rubber
The different types of synthetic rubber are Buna rubbers, butyl rubbers, and neoprene, and they are generally developed for specialized applications having specific properties. Butadiene rubber and styrene-butadiene (where both are Buna rubbers) are generally used in tire production.
Uses of Synthetic Rubber
Let us look at the uses of synthetic rubber as listed below:
Synthetic rubber can be preferred over natural rubber for a few uses if the price differential is not greater.
The transport industry is one of the largest users of rubber for tire production.
Rubber can also be used by the construction industry in hoses, tubes, elevator belts, seismic bearings, and more.
Industries that produce consumer goods make use of rubber in making erasers, good footwear, sports items, and more.
Polyisoprene synthesis is given as the artificial rubber that has the same properties as those of the natural rubber in the chemical composition of ingredients which is used in its manufacture.
FAQs on Synthetic Rubber
1. What is synthetic rubber and how is it generally prepared?
Synthetic rubber is an artificial elastomer, which is a polymer that has the elastic properties of natural rubber. It is synthesised from petroleum-based monomers. The general preparation process begins with processing hydrocarbons like oil or coal to produce naphtha. This naphtha is then mixed with natural gas to create monomers such as isoprene, chloroprene, or butadiene. These monomers undergo a process called addition polymerisation to form long polymer chains, resulting in different types of synthetic rubber.
2. What are the main types of synthetic rubbers as per the NCERT syllabus?
As per the CBSE/NCERT curriculum for Chemistry, the main types of synthetic rubbers students should know are:
- Neoprene (Polychloroprene): Formed by the free-radical polymerisation of chloroprene. It has superior resistance to vegetable and mineral oils.
- Buna-S (Styrene-Butadiene Rubber): A copolymer of butadiene and styrene. It is a tough rubber used extensively in the manufacture of tyres and footwear.
- Buna-N (Nitrile Rubber): A copolymer of butadiene and acrylonitrile. It is known for its high resistance to petrol, lubricating oils, and organic solvents.
3. What are the key differences between synthetic rubber and natural rubber?
The key differences between synthetic and natural rubber lie in their origin, properties, and structure:
- Origin: Natural rubber is a polymer of isoprene obtained from the latex of rubber trees, making it a renewable resource. Synthetic rubber is artificially produced from petroleum byproducts.
- Properties: Synthetic rubbers can be engineered for specific properties. For example, they often have better resistance to heat, ageing, chemicals, and abrasion than natural rubber. Natural rubber, however, generally has higher tensile strength and tear resistance.
- Purity: Synthetic rubber is more uniform in its composition, while natural rubber contains impurities from the plant source.
4. How does the process of vulcanization improve the properties of synthetic rubber?
Vulcanization is a crucial chemical process that enhances the properties of both natural and synthetic rubbers. Raw rubber is soft and sticky, with low tensile strength. During vulcanization, the rubber is heated with a curing agent, typically sulphur. This creates strong cross-links between the individual polymer chains. These cross-links prevent the chains from slipping past each other when stretched, making the rubber much stronger, more elastic, and more resistant to temperature changes and chemical attack.
5. What are some important industrial applications of specific synthetic rubbers like Neoprene and Buna-N?
The specific properties of different synthetic rubbers make them suitable for distinct industrial applications:
- Neoprene: Due to its excellent resistance to oils, ozone, and weathering, Neoprene is used for making industrial hoses, gaskets, conveyor belts, and wet suits.
- Buna-N (Nitrile Rubber): Its high resistance to petrol and lubricating oils makes it the ideal choice for manufacturing fuel hoses, seals, O-rings, and gloves for the automotive and aeronautical industries.
6. Why can't a single type of synthetic rubber be used for all applications?
A single type of synthetic rubber cannot be used for all applications because each type is designed with a unique chemical structure that gives it a specific set of properties. For example:
- Buna-S is tough and abrasion-resistant, making it perfect for car tyres, but it has poor resistance to oil.
- Buna-N is highly oil-resistant, which is essential for fuel seals, but it may not have the same toughness as Buna-S.
- Silicone rubber can withstand extreme temperatures but has low tensile strength.
Therefore, the choice of rubber depends on the specific requirements of the application, such as temperature range, chemical exposure, and mechanical stress.
