Polyester

Polyester is a category of polymers that contain one or two ester linkages in every repeat unit of their main chain. As a specific material, it most commonly refers to a type called polyethylene terephthalate. Polyesters include some naturally occurring chemicals, such as those found in plants and insects. Natural polyesters and a few synthetic ones are biodegradable, but most synthetic polyesters are not. Synthetic polyesters are used extensively in clothing.
Polyester fibers are sometimes spun together with natural fibers to produce a cloth with blended properties. Cotton-polyester blends can be strong, wrinkle- and tear-resistant, and reduce shrinking. Synthetic fibers using polyester have high water, wind, and environmental resistance compared to plant-derived fibers. They are less fire-resistant and can melt when ignited.
Liquid crystalline polyesters are among the first industrially used liquid crystal polymers. They are used for their mechanical properties and heat-resistance. These traits are also important in their application as an abradable seal in jet engines.

Types

Polyesters can contain one ester linkage per repeat unit of the polymer, as in polyhydroxyalkanoates like polylactic acid, or they may have two ester linkages per repeat unit, as in polyethylene terephthalate.
Polyesters are one of the most economically important classes of polymers, driven especially by PET, which is counted among the commodity plastics; in 2019 around 30.5 million metric tons were produced worldwide. There is a great variety of structures and properties in the polyester family, based on the varying nature of the R group.

Natural

Polyesters occurring in nature include the cutin component of plant cuticles, which consists of omega hydroxy acids and their derivatives, interlinked via ester bonds, forming polyester polymers of indeterminate size. Polyesters are also produced by bees in the genus Colletes, which secrete a cellophane-like polyester lining for their underground brood cells earning them the nickname "polyester bees".

Synthetic

The family of synthetic polyesters comprises

Linear aliphatic high molecular weight polyesters are low-melting semicrystalline polymers and exhibit relatively poor mechanical properties. Their inherent degradability, resulting from their hydrolytic instability, makes them suitable for applications where a possible environmental impact is a concern, e.g. packaging, disposable items or agricultural mulch films⁠ or in biomedical and pharmaceutical applications.
Aliphatic linear low-molar-mass hydroxy-terminated polyesters are used as macromonomers for the production of polyurethanes.
hyperbranched polyesters are used as rheology modifiers in thermoplastics or as crosslinkers in coatings due to their particularly low viscosity, good solubility and high functionality
Aliphatic–aromatic polyesters, including poly and poly, poly, poly, etc. are high-melting semicrystalline materials that and have benefited from engineering thermoplastics, fibers and films.
Wholly aromatic linear copolyesters present superior mechanical properties and heat resistance and are used in a number of high-performance applications.
Unsaturated polyesters are produced from multifunctional alcohols and unsaturated dibasic acids and are cross-linked thereafter; they are used as matrices in composite materials. Alkyd resins are made from polyfunctional alcohols and fatty acids and are used widely in the coating and composite industries as they can be cross-linked in the presence of oxygen. Also rubber-like polyesters exist, called thermoplastic polyester elastomers. Unsaturated polyesters are thermosetting resins. They are used in the liquid state as casting materials, in sheet molding compounds, as fiberglass laminating resins and in non-metallic auto-body fillers. They are also used as the thermoset polymer matrix in pre-pregs. Fiberglass-reinforced unsaturated polyesters find wide application in bodies of yachts and as body parts of cars.

Depending on the chemical structure, polyester can be a thermoplastic or thermoset. There are also polyester resins cured by hardeners; however, the most common polyesters are thermoplastics. The OH group is reacted with an Isocyanate functional compound in a 2 component system producing coatings which may optionally be pigmented. Polyesters as thermoplastics may change shape after the application of heat. While combustible at high temperatures, polyesters tend to shrink away from flames and self-extinguish upon ignition. Polyester fibers have high tenacity and E-modulus as well as low water absorption and minimal shrinkage in comparison with other industrial fibers.
Increasing the aromatic parts of polyesters increases their glass transition temperature, melting temperature, thermostability, chemical stability, and solvent resistance.
Polyesters can also be telechelic oligomers like the polycaprolactone diol and the polyethylene adipate diol. They are then used as prepolymers.

Aliphatic ''vs.'' aromatic polymers

Thermally stable polymers, which generally have a high proportion of aromatic structures, are also called high-performance plastics. This application-oriented classification compares such polymers with engineering plastics and commodity plastics. The continuous service temperature of high-performance plastics is generally stated as being higher than 150 °C, whereas engineering plastics are often defined as thermoplastics that retain their properties above 100 °C.⁠ Commodity plastics have in this respect even greater limitations, but they are manufactured in great amounts at low cost.
Poly contain an aromatic imide group in the repeat unit, the imide-based polymers have a high proportion of aromatic structures in the main chain and belong to the class of thermally stable polymers. Such polymers contain structures that impart high melting temperatures, resistance to oxidative degradation and stability to radiation and chemical reagents. Among the thermally stable polymers with commercial relevance are polyimides, polysulfones, polyetherketones, and polybenzimidazoles. Of these, polyimides are most widely applied. The polymers' structures result also in poor processing characteristics, in particular a high melting point and low solubility. The named properties are in particular based on a high percentage of aromatic carbons in the polymer backbone which produces a certain stiffness.⁠ Approaches for an improvement of processability include the incorporation of flexible spacers into the backbone, the attachment of stable pendent groups or the incorporation of non-symmetrical structures.⁠ Flexible spacers include, for example, ether or hexafluoroisopropylidene, carbonyl or aliphatic groups like isopropylidene; these groups allow bond rotation between aromatic rings. Less symmetrical structures, for example, based on meta- or ortho-linked monomers, introduce structural disorder, decreasing the crystallinity.
The generally poor processability of aromatic polymers also limits the available options for synthesis and may require strong electron-donating co-solvents like HFIP or TFA for analysis which themselves can introduce further practical limitations.

Uses and applications

Fabrics woven or knitted from polyester thread or yarn are used extensively in apparel and home furnishings, from shirts and pants to jackets and hats, bed sheets, blankets, upholstered furniture and computer mouse mats. Industrial polyester fibers, yarns and ropes are used in car tire reinforcements, fabrics for conveyor belts, safety belts, coated fabrics and plastic reinforcements with high-energy absorption. Polyester fiber is used as cushioning and insulating material in pillows, comforters, stuffed animals and characters, and upholstery padding. Polyester fabrics are highly stain-resistant since polyester is a hydrophobic material, and therefore has difficulty absorbing liquids. The only class of dyes which can be used to alter the color of polyester fabric are what are known as disperse dyes.
Polyesters are also used to make bottles, films, tarpaulin, sails, canoes, liquid crystal displays, holograms, filters, dielectric film for capacitors, film insulation for wire and insulating tapes. Polyesters are widely used as a finish on high-quality wood products such as guitars, pianos, and vehicle/yacht interiors. Thixotropic properties of spray-applicable polyesters make them ideal for use on open-grain timbers, as they can quickly fill wood grain, with a high-build film thickness per coat.
It can be used for fashionable dresses, but it is most admired for its ability to resist wrinkling and shrinking while washing the product. Its toughness makes it a frequent choice for children's wear. Polyester is often blended with other fibres like cotton to get the desirable properties of both materials.
Cured polyesters can be sanded and polished to a high-gloss, durable finish.

Production

Polyester is typically produced through a process known as polymerization. For polyethylene terephthalate, the production process involves the chemical reaction between two primary raw materials: purified terephthalic acid or dimethyl terephthalate and monoethylene glycol.
The production process includes the following steps:

Polycondensation Reaction: The reaction between PTA or DMT and MEG creates polyester polymer chains through a process called polycondensation. This reaction takes place at high temperatures and involves the removal of water or methanol byproducts.
Extrusion: Once the polymerization is complete, the molten polyester is extruded into long strands. These strands are then cooled and cut into small pellets or chips.
Spinning: To form fibers, these polyester chips are melted and extruded through spinnerets, forming fine strands of polyester filament. These filaments can be processed further to create continuous fibers, which are then woven into textiles.
Recycling: The production of polyester has evolved to include the recycling of PET, especially from post-consumer plastic bottles. Recycled PET is increasingly being used in textile production, reducing the environmental impact of polyester manufacturing.

Polyethylene terephthalate, the polyester with the greatest market share, is a synthetic polymer made of purified terephthalic acid or its dimethyl ester dimethyl terephthalate and monoethylene glycol. With 18% market share of all plastic materials produced, it ranges third after polyethylene and polypropylene and is counted as commodity plastic.
There are several reasons for the importance of polyethylene terephthalate:

The relatively easy accessible raw materials PTA or DMT and MEG
The very well understood and described simple chemical process of its synthesis
The low toxicity level of all raw materials and side products during production and processing
The possibility to produce PET in a closed loop at low emissions to the environment
The outstanding mechanical and chemical properties
The recyclability
The wide variety of intermediate and final products.

In the following table, the estimated world polyester production is shown. Main applications are textile polyester, bottle polyester resin, film polyester mainly for packaging and specialty polyesters for engineering plastics.

Product type	2002	2008
Textile-PET	20	39
Resin, bottle/A-PET	9	16
Film-PET	1.2	1.5
Special polyester	1	2.5
Total	31.2	59