Synthetic rubber and the need for sustainability
22/03/2022
Synthetic rubber refers to any artificial rubber synthesized from monomers derived from petroleum by-products or those of natural origin. The former however made-up bulk of the synthetic rubbers that are in use today. Since the first successful synthesis of synthetic polyisoprene in 1887, there were many variations of synthetic rubbers developed throughout history. The brief timeline of the development of synthetic rubbers is shown in Fig. 1. Until today, there are more than 20 types of synthetic rubbers that are widely available in the market. Fig. 2 shows the data on demand and distribution of synthetic rubber by application in the year 2020, while a summary of the industrial production methods and properties of some commonly used synthetic rubbers is given in Table 1. Synthetic rubbers not only share many similar applications as natural rubber, but also provide an extended range of applications. The primary cause is that synthetic rubber is made using a wide range of monomers, resulting in a variety of rubber properties to be engineered, as opposed to natural rubber, which typically has just one chemical structure. For example, NBR has excellent oil resistance contributed by the polar nitrile group from acrylonitrile moiety in the rubber. The mechanical properties, oil, and chemical resistance of the rubber could be altered by manipulating the ratio of butadiene to acrylonitrile repeating units. Over the decades, the oils and gas industry has optimized the extraction and processing of crude oil and natural gas, resulting in the availability of cost-effective raw materials for synthetic rubbers. This is presumably one of the reasons to most of the synthetic rubber formulations and processing technologies used in the rubber industries today are still largely similar to those that were developed in the early days of synthetic rubber discovery.
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| Fig. 2 Demand for synthetic rubber in 2020 according to rubber types, and their respective applications. | ||
Table 1 General description, properties, and applications of conventional synthetic rubbers
| Rubber | Monomers | Industrial synthesis method | Properties | Applications |
| Styrene butadiene rubber (SBR) | Styrene | Hot emulsion polymerization | More branched, lower molecular weight chain | Lightweight vehicle tire (passenger car, radical car, motorcycle thread), electrical insulation, hoses, seals, haul-off pads, shoe soles |
| Butadiene | Higher Tg than cold & S-SBR | |||
| Good dimensional stability | ||||
| Good extrusion characteristics | ||||
| Cold emulsion polymerization | Better abrasion resistance, tensile strength than hot e-SBR | |||
| Anionic solution polymerization | High molecular weight linear chain | |||
| Narrow molecular weight distribution | ||||
| Excellent abrasion and fatigue resistance, mechanical properties | ||||
| Better tire tread traction properties | ||||
| Chloroprene (Neoprene) | 2-Chlorobutadiene | Emulsion polymerization | High oil and solvent resistance | Gloves, shock absorber seals, electrical insulation, asphalt, wetsuits, bearing pads |
| Good thermal, weather, ozone and aging resistance | ||||
| High strength and stiffness resulted from stress-crystallization | ||||
| Butyl rubber (IIR) | Isobutylene | Cationic slurry polymerization | Excellent water, air and gas permeability resistance | Stopper, gas masks, sealant, gasket, hoses, o-rings, chewing gum base, waterproof liners |
| Isoprene | Good low temperature flexibility | |||
| Low compatibility with other polymers, improved by halogenation (CIIR & BIIR) | ||||
| Nitrile rubber (NBR) | Acrylonitrile | Hot emulsion polymerization | Excellent oil and solvent resistance | Engine hoses, seals, gloves, oil and hydraulic seals, o-rings, waterproof fabrics, adhesives, pigment binder |
| Butadiene | High green strength, low flexibility | |||
| Cold emulsion polymerization | Less branching chain than hot polymerized | |||
| Better processability than hot-NBR | ||||
| Ethylene propylene diene rubber (EPDM) | Ethylene | Solution polymerization | Wide temperature range of application | Roofings, radiator hoses, door seals, gaskets, electrical connectors & insulators, water tank liners |
| Propylene | Good weather, UV, ozone and aging resistance | |||
| Dienes (1,4-hexadiene etc.) | Good resistance to polar fluids, low non-polar solvent resistance | |||
| Low compatibility with other pol |
