Pyrolysis

During plastic pyrolysis, long-chain polymers are broken down into smaller hydrocarbons. The process involves heating plastics in the absence of oxygen at temperatures ranging from 300 to 800°C, producing gas, liquid and solid fractions, with the higher temperatures increasing gas yields. Pyrolysis gas has a high calorific value (22–30 MJ/m³) and can be used as a fuel either directly or after removing solid particles through cyclones and electrostatic separators. The resulting solid char, which contains both carbon and the mineral content of the original material, can be used for energy production or as a precursor for activated carbon. Waxes and liquids, typically accounting for 20–80% of the product, consist of a mixture of organic compounds (mostly C₅–C₂₀), with an increasing proportion of aromatics at higher temperatures due to their greater thermodynamic stability.

Plastic waste pyrolysis begins with feeding sorted, cleaned and dried plastic scraps or pellets, either in solid form via a screw conveyor system or in molten form. The feedstock may include mixed plastic types, sometimes blended with other materials such as sawdust or municipal solid waste. The feedstock is heated in the absence of oxygen in vessels, shaft reactors, rotary drums, or fluidized bed reactors, depending on the scale and operational parameters. For example, fluidized bed reactors offer higher productivity and more efficient heat transfer for high volume applications (Paavani et al., Reference Paavani, Agarwal, Alam, Dinda and Abrar2025). The residence times range from 10 to 60 minutes, although some systems proceed faster, particularly at higher temperatures.

Catalytic reactors are also being explored for plastic waste pyrolysis to improve product selectivity, increasing the yield of liquid hydrocarbons, and lowering reaction temperatures compared to conventional thermal pyrolysis. Catalytic processes typically produce lighter compounds. For instance, thermal pyrolysis of HDPE yields hydrocarbons primarily in the C₁₃–C₂₀ range, whereas catalytic pyrolysis generates products mainly in the C₇–C₁₂ range, with a significant proportion of gases (Anene et al., Reference Anene, Fredriksen, Sætre and Tokheim2018). The most commonly proposed catalysts for this process include zeolites, fluid catalytic cracking catalysts, clays and metal oxides (Budsaereechai et al., Reference Budsaereechai, Hunt and Ngernyen2019). The challenges of catalytic pyrolysis include catalyst deactivation due to coke formation and the high cost of catalysts, like other petrochemical catalytic processes.

Several commercial processes for plastic waste pyrolysis are currently in operation, with many companies specializing in technology licensing and projects at various development stages. A notable example is ExxonMobil, which has been operating its Exxtend technology at commercial scale since 2022 at its Baytown plant in Texas, where it processes approximately 40,000 t/yr. Plastic Energy uses its TAC process at its plants in Almería and Seville (Spain), which have been operational since 2016 and 2017, respectively. These plants handle 5,000 t/yr of highly contaminated, multi-layered plastic waste, primarily of agricultural origin, converting it into TACOIL, a hydrocarbon feedstock for further processing in steam crackers. 2GBiofuels, based in Ascó, Spain and operating since 2021, processes 9,000 t of plastic waste per year to produce pyrolytic oils for new plastic manufacturing under ISCC PLUS certification. Another recent development is the LyondellBasell Wesseling pyrolysis (MoReTec) plant, an industrial-scale demonstration unit that applies catalytic technology to process around 50,000 t of mixed plastic waste per year into feedstocks for new polymer production. Start-up is planned by the end of 2025, supported by a €40 million grant from the EU Innovation Fund.

The main challenges to the economic viability of commercial pyrolysis include the need for consistent feedstock quality and quantity, the incompatibility of certain plastic wastes with reactor designs, and the energy required to achieve complete conversion. This is why such plants are particularly suited to locations with a steady availability of uniform waste, such as agricultural byproducts in regions with industrial-scale agriculture. It is also the reason why most plants adopt a modular approach, progressing cautiously toward large-scale implementation (Saxena, Reference Saxena2025). Another challenge is the contamination of feedstocks with heavy metals and polyaromatic hydrocarbons. This necessitates either the use of cleaner input materials or additional petrochemical processing steps, which increase the cost of a process that was originally intended to handle low-value or marginal feedstocks (Quicker, Reference Quicker2023). Additionally, the scale-up of pyrolysis plants is challenging due to the complex kinetics of the processes involved (Chang, Reference Chang2023). Beyond these technical and operational limitations, political-economic factors further affect viability. Regulatory uncertainty in Europe, particularly the draft mass-balance rules under the Single-Use Plastics Directive, which might adopt a “fuel-use excluded” approach, could reduce the ability of chemical companies to credit pyrolysis outputs toward recycled content targets. As a result, many investors are postponing projects until the final implementation decision is released.

The fragmentation of hydrocarbon chains in plastics to produce fuel feedstocks is an obvious option, but transforming plastic waste into fuels is controversial as it might promote non-circular pathways, especially in regions with low recycling rates (Radhakrishnan et al., Reference Radhakrishnan, Senthil Kumar, Rangasamy, Praveen Perumal, Sanaulla, Nilavendhan, Manivasagan and Saranya2023). Additionally, as an energy-intensive process, pyrolysis has been criticized for potentially increasing GHG emissions. However, Life Cycle Analyses (LCA) show that pyrolysis can reduce GHG emissions compared to traditional waste disposal methods and the overall balance depends on the energy source and how pyrolysis products are used (Xayachak et al., Reference Xayachak, Haque, Lau, Parthasarathy and Pramanik2023). It is important to note that the products from plastic pyrolysis can be used as feedstock in petroleum refineries, where cracking and other processes may create new plastics or high-value products (Dai et al., Reference Dai, Zhou, Lv, Cheng, Wang, Liu, Cobb, Chen, Lei and Ruan2022). Pyrolysis can also be applied to bioplastics, particularly non-compostable ones, and is not limited to fossil-based hydrocarbons.

Gasification

When plastic waste is heated with steam in an oxygen-limited environment, it produces a gas mixture primarily composed of carbon monoxide, hydrogen and methane, known as syngas (synthetic gas), and the process is called gasification. Oxygen can be supplied via air, reducing costs but also lowering the calorific value of the resulting fuels due to the energy required to heat nitrogen. Steam is crucial, as it provides hydrogen, reduces tar formation and moderates temperature, preventing undesirable reactions or equipment damage. Additionally, steam plays a key role in adjusting the H₂/CO ratio in syngas, which is essential for chemical syntheses that require specific hydrogen-to-carbon monoxide ratios.

After cleaning, the first gasification step involves the production of cracking products, similar to those obtained in pyrolysis, which are then further reformed through partial oxidation and steam reforming reactions:

$$ {\mathrm{C}}_n{\mathrm{H}}_m\hskip0.33em +\hskip0.33em n\;{\mathrm{H}}_2\mathrm{O}\hskip0.33em \to \hskip0.33em n\;\mathrm{CO}\hskip0.33em +\hskip0.33em \left(\frac{m}{2}\hskip0.33em +\hskip0.33em n\right)\;{\mathrm{H}}_2\hskip0.82em \mathrm{endothermic} $$

$$ {\mathrm{C}}_n{\mathrm{H}}_m\hskip0.33em +\hskip0.33em \frac{n}{2}\;{\mathrm{O}}_2\hskip0.33em \to \hskip0.33em n\;\mathrm{CO}\hskip0.33em +\hskip0.33em \frac{m}{2}\;{\mathrm{H}}_2\mathrm{O}\hskip0.82em \mathrm{exothermic} $$

A large number of reactions occur simultaneously, involving all substances in the system. However, the balance between H₂, CO₂ and CO is primarily determined by the interplay between the exothermic water-gas shift reaction and the endothermic Boudouard reaction, both of which are governed by the gasification temperature, typically ranging from 600 to 1,500°C (Bashir et al., Reference Bashir, Ji, Weidman, Soong, Gray, Shi and Wang2025):

Water-gas shift equilibrium: $ \mathrm{CO}+{\mathrm{H}}_2\mathrm{O} $ ⇌ $ \mathrm{C}{\mathrm{O}}_2\hskip0.33em +\hskip0.33em {\mathrm{H}}_2\hskip1.12em \Delta \hskip0.1em {h}_{298\hskip0.1em \mathrm{K}}^{\circ }=-41.2\hskip0.33em \mathrm{kJ}/\mathrm{mol} $ .

Boudouard reaction: $ \mathrm{C}+\mathrm{C}{\mathrm{O}}_2\to 2\;\mathrm{CO}\hskip0.82em \Delta \hskip0.1em {h}_{298\hskip0.1em \mathrm{K}}^{\circ }=+170.4\hskip0.33em \mathrm{kJ}/\mathrm{mol} $ .

The lower temperature boundary for the process, 600°C, is the minimum required for char gasification: $ \mathrm{C}\hskip2pt +\hskip2pt {\mathrm{H}}_2\mathrm{O}\hskip2pt \to \hskip2pt \mathrm{C}\mathrm{O}\hskip2pt +\hskip2pt {\mathrm{H}}_2\Delta {h}_{298\hskip2pt \mathrm{K}}^{\circ }=+131.2\hskip2pt \mathrm{k}\mathrm{J}/\mathrm{m}\mathrm{o}\mathrm{l} $ .

Metal oxides and other impurities are recovered in the form of ash, which should be nearly carbon-free and can be used in construction. In industrial practice, plastic waste is typically gasified along with other waste streams in a two-stage process. The first stage uses a gasifier fed with oxygen and steam and operates at relatively low temperatures. In the second stage, with additional steam, the gas reaches approximately 1,500°C, yielding a gas primarily composed of H₂ and CO (Al-Salem et al., Reference Al-Salem, Lettieri and Baeyens2010). This gas is rapidly cooled to prevent dioxin formation, particles are removed using electrostatic precipitators, and hydrogen chloride (from chlorinated plastics) is removed in a gas scrubber. The resulting syngas can be used as fuel or as a raw material to produce methanol or ammonia through well-established processes. Methanol, in particular, serves as a key raw material for producing petrochemicals traditionally derived from oil or natural gas (Afzal et al., Reference Afzal, Singh, Nicholson, Uekert, JS, ECD, Dutta, Carpenter, Baldwin and Beckham2023). Catalysts can be employed to enhance gas production efficiency, reduce tar formation and optimize syngas conversion. However, most available designs are non-catalytic due to high operational costs and the need to cope with catalyst deactivation issues.

A few operational plants exist for plastic waste gasification, along with some designs available for licensing. The Ebara Ube Process (Figure 3) uses a two-stage system consisting of a low-temperature fluidized bed (600–800°C) followed by a high-temperature gasifier (1,300–1,500°C). Fly ash is recovered as molten slag and reused as a construction material. The system began operating in 2003, with a 195 t/d plant run by Showa Denko (renamed as Resonac in 2023) at Kawasaki City, Japan. It produces hydrogen gas for ammonia synthesis from mixed plastic waste, including both municipal waste and, since 2020, crushed and molded used plastics from industrial sources.

Figure 3. Ebara Ube Process for plastic waste gasification (Adapted from EBARA Environmental Plant Co., Ltd., technical information).

Other designs have reached various stages of development. Since 2008, Chalmers University of Technology has operated a biomass gasification pilot plant in Gothenburg, Sweden, to explore the gasification of automotive shredder residues and several plastic wastes. As early as the late 1990s, AkzoNobel was involved in a waste-to-chemicals initiative aimed at converting non-recyclable waste, including PVC-rich plastics, into methanol in collaboration with the Canadian company Enerkem. The process used two circulating fluidized bed reactors operating at atmospheric pressure, with sand used to transfer heat between them. The first unit was a gasification reactor operating at 700–900°C, while the second, fed with additional air, burned residual tar and provided heat for the gasification process (Tukker et al., Reference Tukker, De Groot, Simons and Wiegersma1999). Despite promising research, the project did not progress beyond the study phase. This outcome underscores the technological and economic uncertainties associated with plastic gasification, a complex process that is more dependent on feedstock quality than simpler methods like pyrolysis. A recent example is Repsol’s Ecoplanta, following a final investment decision made in early 2025, with start-up expected around 2028–2029. Located in Tarragona, Spain, the plant will be a waste-to-methanol facility designed to convert up to 4,00,000 t/yr of non-recyclable municipal solid waste, including mixed plastics, into circular methanol for chemical and fuel applications. The project is supported by over €800 million in investment and an EU Innovation Fund grant.

Hydrothermal liquefaction

The third thermal plastic waste processing option is hydrothermal liquefaction, which uses subcritical or supercritical water (250–400°C) to convert plastics into naphtha or waxes, which can then be further processed into fuels (Chen et al., Reference Chen, Jin and Linda Wang2019). Supercritical water (>374°C, >22.1 MPa) offers advantages due to its ability to act as a solvent for organic compounds, making it especially effective for treating hydrophobic plastics without the need for harmful or flammable organic solvents. Supercritical water is able to break the tight molecular packing of crystalline regions, acting also as a reagent in processes like the nucleophilic substitution of chlorine atoms from PVC (Nagai et al., Reference Nagai, Smith, Inomata and Arai2007). Additionally, hydrothermal liquefaction can be carried out with the aid of catalysts, which may include bases like NaOH to promote C-C and C-O bond cleavage, acids like HCl or zeolites to facilitate cracking and dealkylation, and metals or metal oxides to enhance dehydrogenation and gasification reactions (Yang et al., Reference Yang, Jan, Chen, W-T and Wu2022).

High temperatures and pressures accelerate thermal depolymerization and cracking reactions, making hydrothermal liquefaction an effective method for processing mixed plastic waste, including hard-to-recycle types like PVC and multi-layer films. These conditions, along with the presence of water, also help minimize coke formation. More severe reaction conditions favor the production of gaseous products, such as syngas, and lighter liquid fractions that can serve as raw materials for fuels or chemical feedstocks. However, operating at high temperatures requires specialized reactors and corrosion-resistant materials, particularly when processing halogenated plastics. Additional challenges include the high energy input required and the need to handle variable feedstock compositions to maintain economic viability (Lu et al., Reference Lu, Jan and Chen2022).

Commercial-scale hydrothermal liquefaction plants for plastic waste are still under development. Licella’s Cat-HTR (Catalytic Hydrothermal Reactor) uses supercritical water to process mixed waste, including plastics and is being commercialized by Mura Technology Ltd. under the name Hydro-PRS (Hydrothermal Plastic Recycling Solution). This process has been in operation since 2023 at ReNew ELP in Teesside, UK, the world’s first commercial-scale plastics recycling plant using hydrothermal liquefaction. The facility has a capacity of 20,000 t/yr of mixed post-consumer plastic waste and runs at 350–420°C and over 22 MPa with a residence time of 20–25 minutes using a non-disclosed solid catalyst (Li et al., Reference Li, Aguirre-Villegas, Allen, Bai, Benson, Beckham, Bradshaw, Brown, Brown, Cecon, Curley, Curtzwiler, Dong, Gaddameedi, García, Hermans, Kim, Ma, Mark, Mavrikakis, Olafasakin, Osswald, Papanikolaou, Radhakrishnan, Sanchez Castillo, Sánchez-Rivera, Tumu, Van Lehn, Vorst, Wright, Wu, Zavala, Zhou and Huber2022). A feature of Mura is its relatively strict requirements on PVC content in raw materials. Other companies are also developing hydrothermal liquefaction plants to treat combined biomass and mixed waste, with several projects in pilot or demonstration stages. The technology is expanding due to its ability to process various waste types, although significant challenges remain.

Dissolution recycling

The most straightforward method is dissolution recycling, a purification process in which a polymer in mixed plastic waste is selectively dissolved in a solvent, allowing it to be separated and potentially recovered with high purity. Unlike the previously discussed thermal processes, and distinct from chemical depolymerization, which breaks polymers down into monomers or oligomers, requiring re-polymerization to create the same or similar products, solvent-based processes simply dissolve the polymer without altering its molecular structure. As a result, solvent approaches share similarities with mechanical recycling but offer the additional advantage of separating small molecules used as additives, improving product quality (Ügdüler et al., Reference Ügdüler, Van Geem, Roosen, Delbeke and De Meester2020).

The use of selective solvents is critical for recovering a specific polymer, even when mixed with other materials. In the solvent-antisolvent method, a dissolving solvent is heated with the plastic to the temperature needed to achieve a high recovery rate. After separating the non-dissolved materials, the solution is mixed with a cold antisolvent to induce precipitation. The polymer can then be separated, although the solvent and antisolvent must be purified before reuse. However, the process faces significant practical and economic challenges. Plastics dissolve only at low concentrations, requiring large amounts of solvent, and even then, the resulting solutions are viscous and difficult to handle. Contaminants in the feedstock, like printing ink resins, form gels, severely limiting the types of plastics that can be processed. Consequently, many dissolution operations cannot handle printed or multilayer packaging, and the high costs of solvent, recovery, and filtration make the technology economically sensitive.

An interesting variation uses supercritical CO₂ as an antisolvent, as demonstrated in the dissolution of polystyrene in p-cymene, followed by precipitation with supercritical CO₂ (Gutiérrez et al., Reference Gutiérrez, Rodríguez, Gracia, de Lucas and García2014). Alternatively, a single supercritical solvent can dissolve the polymer, and in this case, precipitation can be induced by reducing temperature, pressure or both, in a process called supercritical fluid extraction. This technique, although relatively new for plastic recycling, is already well-established in industries such as food, beverage, pharmaceuticals and cosmetics. Besides the advantage of having commercially viable industrial-scale plants, CO₂ offers the advantages of being non-toxic, non-flammable and simple to use for the selective extraction of additives. However, it has not yet been implemented at full scale for plastic recycling due to the need for high-pressure equipment (>7.4 MPa) and the energy-intensive compression of CO₂. An interesting variation is the temperature-swing method, which is similar to the solvent-antisolvent approach, with the difference that precipitation is induced by cooling instead of using an antisolvent. This method avoids the use of an antisolvent but requires more energy for the heating and cooling processes. Other methods, such as the use of ionic liquids, are still in the R&D stage (Mohan et al., Reference Mohan, Keasling, Simmons and Singh2022).

Solvent recovery of polymers is not a new concept. Sony’s Orange R-net was already in use in Japan in the 1990s for expanded polystyrene (EPS), using limonene as solvent, and was implemented in a full-scale plant in Ichinomiya that operated for several years A similar initiative was led by Solvay at the Vinyloop plant in Ferrara, aimed at recovering PVC from cables, with a capacity of 10,000 t/yr. However, they had to close due to challenges in separating EU-banned low molecular weight phthalate plasticizers. Other interesting development is Fraunhofer IVV’s CreaSolv Process, focused on recovering polystyrene (PS) from electronic waste and multi-layer packaging, using a proprietary solvent. Another example is PureCycle Technologies, which completed a commercial plant in Ironton, USA, in 2023. The facility is designed to process 50,000 t of recycled PP per year using a solvent-based method patented by Procter & Gamble in 2018, involving mixtures of aliphatic and olefinic hydrocarbons. Other initiatives are underway, although facing important challenges due to cost and regulatory issues.

Chemical depolymerization

Chemical depolymerization, also known as solvolysis, involves using chemicals, with or without catalysts, to break down polymer molecules into monomers or oligomers, primarily aimed at producing new plastics. These techniques are highly selective and, therefore, relatively insensitive to the presence of non-depolymerizable polymers, additives, or other contaminants. This selectivity can be advantageous in avoiding pre-processing stages (Clark and Shaver, Reference Clark and Shaver2024). The ability to recycle plastics that are mechanically non-recyclable makes solvolysis an attractive alternative to address the gap created by non-recyclable plastics. However, solvolysis is highly dependent on the chemical structure of the polymers, resulting in a wide range of processes with varying reaction conditions and products, depending on the raw plastic being processed.

Solvolysis is particularly effective for recycling condensation polymers such as polyesters, polyamides and polycarbonates. A well-known example is PET, which can undergo hydrolysis to produce terephthalic acid and ethylene glycol through nucleophilic attack on the carbonyl bonds. These are the original monomers used to synthesize PET, allowing them to be reintegrated into the polymer production cycle. PET can also undergo solvolysis with alcohols. For instance, methanolysis uses methanol to yield dimethyl terephthalate and ethylene glycol. Glycolysis involves ethylene glycol and produces bis(2-hydroxyethyl) terephthalate. When amines are used as reagent, the process is referred to as aminolysis, generating diamide compounds, while ammonia is used in ammonolysis to produce terephthalamide derivatives.

PET hydrolysis is typically carried out under alkaline, acidic, or neutral conditions at temperatures ranging from 100 to 250°C and pressures of 1–5 MPa. When hydrolysis is performed under neutral conditions (water only), higher pressures and temperatures are required, along with a large excess of water, due to the lower reactivity of water alone. PET melts at 250–260°C, and within this temperature range, depolymerization is favored. However, in many formulations, such as transparent water bottles, PET is essentially amorphous (which is why it is transparent), so it is not necessary to reach the high temperatures that would be required to process crystalline PET. In addition to acids (mineral acids, carboxylic acids, or acidic ionic liquids), metal salts like ZnI₂ can be used, which are thought to act as Lewis acids (Pereira et al., Reference Pereira, Savage and Pester2024). Acids lead to additional purification steps and may be corrosive, but they also help reduce the temperature required for the process. Hydrolysis assisted by H₂SO₄ (>85%) can proceed at temperatures as low as 100–120°C. Alkaline hydrolysis requires less concentrated media (10–20% NaOH) but necessitates higher temperatures and longer reaction times (several hours).

Methanolysis can be carried out under similar conditions (180–280°C, 2–4 MPa) using various catalysts such as zinc or lead acetate, metal oxides and hydroxides and carbonates (Pham and Cho, Reference Pham and Cho2021). Relatively mild conditions (200°C, 0.1 MPa, near the boiling point of ethylene glycol) are also required for glycolysis, which has the added advantage of yielding bis(2-hydroxyethyl) terephthalate, a compound that can enter PET production already esterified. Catalysts help achieve reasonable yields in shorter times. López-Fonseca et al. used sodium carbonate as a catalyst and obtained 80% conversion to bis(2-hydroxyethyl) terephthalate in 1 hour at 196°C (López-Fonseca et al., Reference López-Fonseca, Duque-Ingunza, de Rivas, Flores-Giraldo and Gutiérrez-Ortiz2011). Ammonolysis and aminolysis can be carried out under milder conditions (<100°C) due to the higher nucleophilicity of amines and ammonia, though they require more expensive reagents. Regardless of the type of solvolysis used, the development of catalysts to increase the reaction rate, product yield and reduce the need for harsh conditions is an active area of current research, including the use of green catalysts, which are less environmentally concerning compared to metal salts. These include ionic liquids and deep eutectic solvents, though they have the drawback of higher operating costs (Kumar et al., Reference Kumar, Kumar and Bharti2024).

Solvolysis is also being studied for polyamides (PA) such as nylon, which can undergo hydrolysis, ammonolysis, or aminolysis, like PET and are favored by acids, metal catalysts and the use of supercritical water. Polyamides can also be depolymerized using hydrogen. Kumar et al. demonstrated that PA can be reverted to diols and diamines using ruthenium as a catalyst at 150°C and 7.0 MPa of hydrogen pressure with DMSO as solvent (Kumar et al., Reference Kumar, von Wolff, Rauch, Zou, Shmul, Ben-David, Leitus, Avram and Milstein2020). The same process is valid for polyurethanes (PU). However, high energy inputs, low product yields, the use of solvents and the need for purification steps pose safety and economic concerns, making the recovery of polyamides and other condensation polymers, other than PET, still under laboratory development.

Commercial developments in PET recycling can be traced back to the 1990s when Eastman Kodak pioneered a methanolysis process to depolymerize post-consumer PET at its plant in Kingsport, Tennessee, USA. The plant, with a capacity of approximately 50,000 t/yr, operated at 180–280°C and 2–4 MPa to yield dimethyl terephthalate and ethylene glycol, which were then purified for the production of new PET (Figure 4). The process started with cleaning and shredding post-consumer waste, which was then fed into the depolymerization reactor. The reaction products were further purified through distillation or crystallization to achieve the desired purity levels for reuse. This process enabled the production of virgin-quality PET for polyester fiber or resin production, even from contaminated or colored post-consumer items that were unsuitable for mechanical recycling. The Kingsport plant was shut down in the early 2000s due to its complex logistics, high operational costs compared to mechanical recycling, and the declining prices of virgin PET resin, which made chemically recycled PET not competitive. Due to increased regulatory pressure, Eastman considered investing in an updated version of its original process; however, the project is reportedly on hold due to the current economic situation.

Figure 4. Eastman Kodak PET methanolysis process. Products: dimethyl terephthalate and ethylene glycol (Adapted from: Eastman Kodak technical information).

Other commercial initiatives are being planned in different parts of the world. Revalyu operates two commercial plants in Nashik, India, employing a glycolysis process to recycle 160 tons of PET waste per day into polyester polymers (a third one is in construction). The company has also begun constructing a new facility in the United States. Ioniqa was trying to run a demonstration pilot plant in the Netherlands using catalytic glycolysis of PET, but it went bankrupt in 2024. Garbo is building a plant in Cerano, Italy, to produce recycled bis(2-hydroxyethyl) terephthalate and chemically recycled PET, also using a glycolysis-based technology.

Solvolysis is particularly suitable for recycling plastics that are difficult to process mechanically, such as colored, multilayered, or contaminated materials. However, the method often requires high energy inputs and careful product purification, which can challenge its scalability and economic feasibility. Despite these limitations, solvolysis holds promise as part of a circular economy approach, especially when integrated with sustainable solvents and catalysts.

Enzymatic depolymerization

Enzymatic depolymerization uses microbial enzymes to break down plastics into their basic monomers. Closely related, biodegradation refers to the degradation caused by enzymatic processes resulting from the action of cells (excluding isolated enzymes). Both are biocatalytic approaches considered more environmentally friendly and potentially more efficient than conventional methods such as incineration or mechanical recycling. They require mild conditions (ambient temperature and pressure) and do not use solvents. However, enzymatic degradation and biodegradation are very complex processes. In particular, the degree of crystallinity affects the efficiency of enzymatic processes, as enzymes have difficulty accessing the crystalline domains of polymers (Ciuffi et al., Reference Ciuffi, Fratini and Rosi2024). Additionally, enzymes are highly specific, making them useless for many types of polymers. Specifically, polyolefins and polystyrene are particularly unsuitable and only polymers for which active enzymes are available, like polyesters or polyurethanes, can be broken down upon the action of esterases and urethanases.

Active research is focused on increasing efficiency, such as isolating microorganisms from the plastisphere, optimizing enzymes via protein engineering, or relying on microbial consortia rather than single species. However, in their current state, enzymatic degradation and biodegradation still require pretreatments such as thermal, oxidative, or mechanical processes, which can undermine their viability (Ali et al., Reference Ali, Elsamahy, Al-Tohamy, Zhu, Mahmoud, Koutra, Metwally, Kornaros and Sun2021). Concerning operational plants, there is an interesting case with Carbios in Longlaville, France, which has been trying to build the first industrial-scale enzymatic PET recycling plant. The process uses PET hydrolases that are expected to yield 90% conversion to terephthalate in 10 hours. The plant is still in the planning stages due to financing problems, which are largely dependent on public subsidies.

Electrochemical recycling

Finally, electrochemical recycling uses electricity to drive chemical reactions that break down plastics into valuable monomers, fuels or other chemicals, often under milder conditions than traditional thermal or chemical processes. The reaction occurs in a liquid electrolyte with additives or catalysts and may proceed through reductive or oxidative pathways, involving sacrificial or mediator species, such as anode-produced methoxide anions (Weber, Reference Weber2024).

However, electrochemical recycling faces significant challenges due to the low solubility of polymers in electrolytes, their high molecular weight, which limits the diffusion rate toward the electrode surface, and their low reactivity, especially in large particles, where the electrochemical reaction can only take place on the surface. These factors favor parasitic reactions that lower the faradaic efficiency of the process. This issue is the subject of intense research, including the development of electrodes with large pores, ionic liquid electrolytes and catalysts designed to improve the selectivity of electrochemical reactions (Li et al., Reference Li, Chen, Zhang, Matos, Wang and Yang2024).

The presence of impurities in waste streams is another critical problem if real waste plastics are to be used, as they may damage the electrodes or the membrane separating the anode from the cathode. Finally, separating the products from the electrolytes may be difficult or energy-intensive (Zhang et al., Reference Zhang, Killian and Thevenon2024). Despite recent innovations, such as coupled systems with biological or photochemical degradation and improved flow cell designs for continuous processing, electrochemical plastic recycling remains in a pre-competitive status.

Globally, the circular economy for plastics remains in its early stages, particularly in non-OECD countries, where recycling rates generally remain below 10%, with the notable exceptions of China and India, primarily due to limited infrastructure. Despite these challenges, the circular plastics economy has the potential to significantly reduce the demand for hydrocarbon feedstocks in the petrochemical industry, possibly resulting in negative growth in the sector over the next decade (Kapustin and Grushevenko, Reference Kapustin and Grushevenko2023). The OECD has outlined several potential scenarios for plastic waste management, depending on the intensity and coordination of regulatory efforts, but even under the most ambitious projections, the complete elimination of plastic leakage into the environment is not expected before 2040–2060. Moreover, achieving that goal would require coordinated action across all stages of the plastic life cycle, an outcome that currently appears unlikely.