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Brief summary

The article explores the complexity of plastics, highlighting the diverse range of plastic polymers and their engineering for specific properties like strength, flexibility, or solvent resistance. Discover the origins of plastic production, tracing it back to natural gas, particularly ethane, which undergoes a series of processes, including cracking and polymerization, to become polyethylene. These processes involve high temperatures, pressures, and catalysts, ultimately leading to the formation of the versatile material we encounter in various everyday products.

Diverse Polymeric Possibilities

The term "plastic" suggests one material, but there are actually hundreds of different plastic polymers. Polymerization occurs when a chemical reaction causes molecules to react together to form polymer chains. These polymer chains can be engineered to control the specific physical properties of the resulting plastic resin, thus allowing the product to be designed for many different uses.
For example, some plastic products may require extra strength, some require maximum flexibility and others need to be resistant to solvents. All of these requirements can be accounted for by the polymers used in the process.
 

Origins, Labels, and Production Processes

Polyethylenes may be labeled as low-density or high-density polyethylenes (LDPE or HDPE), or other designations that can be seen at the bottom of household containers. Rarely a day goes by without coming into contact with items made of plastic.
We see it all around, in everything from food packaging, medical equipment, furniture and vehicles, to toys, computers and clothing. But most people don't realize that natural gas is where a lot of plastic production starts.
The first stop in processing natural gas to plastic is the cracker plant. Crackers turn either naphtha, a crude oil-based product, or ethane, a natural gas liquid, into ethylene, a starting point for a variety of chemical products.
Ethane is formed the same way other hydrocarbons (e.g. oil and gas) are generated. Hundreds of millions of years ago, organic material such as plankton fell to the bottom of a seabed.
 

From Natural Origins to Polymerization: The Journey of Ethane to Polyethylene

Over time, it was trapped in sediment in an anoxic environment (lacking oxygen to break these organic materials down completely). Pressure and temperature converted these materials into hydrocarbons. These hydrocarbon-bearing formations matured at different rates, even within the same formation, depending on temperature, time and pressure. Within a formation, one area may produce oil, another area “wet” natural gas (natural gas mixed with natural gas liquids) and yet another area only “dry” gas (almost pure methane).
Ethane, like all NGLs, is a liquid underground but becomes a gas under standard surface pressures and temperatures. Ethane is separated from the gas stream in a processing facility where different pressures and temperatures are applied to draw off each of the gases separately. De-ethanization occurs when the boiling point for only ethane is reached, turning it into a gas.
Purity ethane (at least 90% ethane, but usually higher) then travels in a pipeline to its destination, an ethane cracker plant. At the cracker plant, which has access to a large energy source, ethane is heated to about 1500 degrees Fahrenheit. This process is called cracking because heat energy is used to break apart or crack molecules to form new molecules.
At that temperature, ethane (C2H6) molecules lose two hydrogen molecules, which split off to form a separate, stable hydrogen molecule (H2), leaving molecules which are about 80 percent ethylene (C2H4).
The ethylene formed in the cracking process is next transported by pipeline to another facility to be converted to usable ethane cracking products, the most common of which is polyethylene.
At this point, ethylene is still a gas and needs pressure and a catalyst to turn it into polyethylene, a resin. The process by which polyethylene is made from ethylene is known as polymerization.



Credits: Daniel Brockett

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