What are plastics?

The modern word ‘plastics’ refers to human-made materials, primarily composed of large organic molecules called polymers, which can be moulded into shape. Plastics are generally either thermoplastics, which are made of linear polymeric chains, or thermosets, which are made of cross-linked polymer networks. Only thermoplastics can be melted and remoulded. Thermosets are much harder to recycle, though innovation in this field is emerging (Wu et al., Reference Wu, Hartmann, Berne, De Bruyn, Cuminet, Wang, Zechner, Boese, Placet, Caillol and Barta2024). Plastics also typically contain chemical additives to enhance their properties, such as flexibility, heat and light resistance (Hahladakis et al., Reference Hahladakis, Velis, Weber, Iacovidou and Purnell2018).

While there are hundreds of different types of plastics, mass production is dominated by just eight kinds, which together account for more than 90% of the global plastic waste generation (after OECD, 2022). These are polypropylene, low- and high-density polyethylene, polyethylene terephthalate, polystyrene, polyvinyl chloride, polyurethane, and the synthetic fibre class mainly constituted of polyesters, polyamides, and polyacrylates. Other important plastics are polymethyl methacrylate (PMMA), a lightweight transparent thermoplastic often used to replace glass, and polytetraflouroethylene (PTFE or Teflon), often used for seals and non-stick coatings. Waste mismanagement leads to these materials reaching the environment (via the atmosphere, land, oceans and rivers) where they accumulate and degrade.

How much plastic is there, and how much of it becomes waste?

The global production of plastics is estimated by the UN Environmental Program to have increased exponentially over the past few decades to 400 million tons per year. Geyer et al. (Reference Geyer, Jambeck and Law2017) identify packaging as the largest use of plastics. About 85% of plastic ends up in landfills or is released to the environment. Annually, nearly 8 million tons of plastic waste end up in the marine environment through rivers. Some 5.25 trillion microplastic particles are estimated to be currently floating in the global ocean (Harris et al., Reference Harris, Maes, Raubenheimer and Walsh2023). The weight of plastic products will increase to 1,100 million tonnes by 2050 if the growth trend continues, although an increasing proportion is biodegradable. Approximately 1.14 million tons of biodegradable plastics were produced in 2022 (Omura et al., Reference Omura, Isobe, Miura, Ishii, Mori, Ishitami, Kimura, Hidaki, Komiyama, Suzuki, Kasuya, Nomaki, Nakajima, Tsuchiya, Kawagucci, Mori, Nakayama, Kunioki, Kamino and Iwata2024). All of this material constitutes part of the archaeological record, an archive characterising the Plastic Age (see Godin et al., Reference Godin, Pétursdóttir, Praet and Schofield2025).

Does size matter?

In the plastic pollution field, large items, that is anything bigger than 25 mm, are referred to as macroplastic, anything between 5 and 25 mm are mesoplastics, debris between 5 mm and 1 μm are called microplastics (Thompson, Reference Thompson, Bergmann, Gutow and Klages2015) and the smallest size range, below 1 μm, are typically referred to as nanoplastics. These definitions and size thresholds remain a subject of debate between different branches of science (including colloid science, environmental science, oceanography, chemistry and nanotechnology; e.g., Song et al., Reference Song, Wang and Li2024; see also Gigault et al., Reference Gigault, ter Halle, Baudrimont, Pascal, Gauffre, Phi, El Hadri, Grassl and Reynaud2018, Gigault et al., Reference Gigault, El Hadri, Nguyen, Grassl, Rowenczyk, Tufenkji, Feng and Wiesner2021, Lassen et al., Reference Lassen, Foss Hansen, Magnusson, Noren, Bloch Hartmann, Rehne Jensen, Gisel Nielsen and Brinch2015, Rani-Borges and Ando, Reference Rani-Borges and Ando2024, 4).

Microplastics are categorised as either primary or secondary. Primary microplastics include any plastic fragments or particles that are already 5 mm in size or less before entering the environment (Boucher and Friot, Reference Boucher and Friot2017). These include microfibres from clothing, microbeads, plastic pellets, powders and cosmetic products. Secondary microplastics arise from the degradation of larger plastic products through natural weathering processes after entering the environment. These processes, which include ultraviolet (UV) light, heat, winds and waves (Galgani et al., Reference Galgani, Hanke, Maes, Bergmann, Gutow and Klages2015), are the n-transforms that accompany the path of plastics from the systemic to the archaeological context. Such sources of secondary microplastics include water and soda bottles, fishing nets, plastic bags, microwave containers, tea bags and tyre wear.

The size of plastics is important because it dictates the kind of impact they can have, notably on living beings. For example: (i) macroplastics can have lethal consequences for animals as a result of entanglement, lacerations, lesions or blockades (Vanavermaete et al., Reference Vanavermaete, Lusher, Strand, Abad, Farré, Kallenbach, Dekimpe, Verlé, Primpke, Aliani and De Witte2024); (ii) mesoplastics are ingested by birds; (iii) microplastics are reportedly accumulating inside organs; and (iv) nanoplastics can cross cell membranes. The size of objects also partly determines how they respond to c- and n-transforms and their visibility and accessibility as an archaeological record.

How do plastics enter the archaeological record?

Harrison and Schofield (Reference Harrison and Schofield2010) describe how post-1950 discard differs from the prior archaeological record, listing a number of key new contributors. In addition to the introduction of new human-made materials (such as plastics), these new contributors include, for example, mass manufacture, mass discard, single-use objects, the growth of landfills, the wholesale demolition of buildings and infrastructure and an exponential increase in the mass of material use due to population growth.

Given this diversity, there are inevitably multiple pathways into the archaeological record. Edgeworth’s (Reference Edgeworth, Godin, Pétursdóttir, Praet and Schofield2025) overview of ‘how plastics get into the ground’, distinguished plastics deliberately buried as infrastructure (e.g., pipes and cables), plastics as litter, those incorporated into the agricultural treatment of soils, landfill and pollution (e.g., tyre and brake-pad degradation). Once in the archaeological record (i.e., post discard, whether deliberate or accidental), c- and n-transforms come into play.

Fishing provides a good example of an industrial pathway and the impact of c- and n-transforms on shaping the archaeological record. In terms of c-transforms, fishing fleets create plastic waste through lost or discarded fishing gear, ghost nets and the domestic waste thrown overboard due to the lack of storage space on board vessels (see Finska et al., Reference Finska, Ivanova, Jakobsen, Rapp Nilsen, Normann and Solski2022 for data related to waste management practices on fishing boats and legislative frameworks). In terms of scale, this is significant as fishing gear is estimated to contribute over 50% of plastic waste in some parts of the ocean (Apete et al., Reference Apete, Martin and Iacovidou2024; see also Li et al., Reference Li, Tse and Fok2016). This fishing waste is then distributed by n-transforms in the form of ocean currents.

Building on Edgeworth’s (Reference Edgeworth, Godin, Pétursdóttir, Praet and Schofield2025) observations, and characteristic of archaeologies of earlier periods, the subsurface (or pedosphere) provides an important context for plastics, where c- and n-transforms include agricultural activities (fertiliser applications, irrigation and ploughing), landfilling and water and wastewater treatment plant discharge. Secondary microplastics proliferate in the subsurface, resulting from the decomposition and weathering of macroplastics, car-tyre wear, degradation of furniture, washing of clothes (which leaks microfibres into wastewater), breakdown of litter and airborne dust (after Dong et al., Reference Dong, Yu, Huang, Gao and Gao2022; Guo et al., Reference Guo, Huang, Xiang, Wang, Li, Li, Cai, Mo and Wong2020; Haque and Fan, Reference Haque and Fan2023). Within the subsurface, plastics can move both horizontally and vertically, the transforms disrupting neat stratigraphic sequencing. For example, recent work in York has demonstrated the presence of microplastics in deeply buried archaeological deposits, likely to be the result of water discharge (Rotchell et al., Reference Rotchell, Mendrik, Chapman, Flintoft, Panter, Gallio, McDonnell, Liddle and Schofield2024a).

Archaeologists often distinguish human activities that occur ‘on-site’ from those occurring ‘off-site’ (after Foley, Reference Foley1981). On-site refers to key locations where people lived and worked, and where much of the archaeological evidence has therefore accumulated (Wagstaff, Reference Wagstaff and Schofield1991). Off-site is characterised by a low-density background scatter of human debris, representing more dispersed and less intensive activities. For the Plastic Age, on-site activities will include places where rubbish has accumulated through domestic use (e.g., in cities) and places of mass disposal (e.g., landfill). However, unusually, plastic waste also accumulates off-site. For example, vast accumulations of human waste from multiple locations mass in oceanic locations known as garbage patches (Lebreton et al., Reference Lebreton, Slat, Ferrari, Sainte-Rose, Aitken, Marthouse, Hajbane, Cunsolo, Schwartz, Levivier and Noble2018).

Waste is also accumulating both on- and off-site in extremely remote areas, such as in the cryosphere. There has been an awareness of fishing marine debris in Antarctica since the 1980s, and active monitoring since the early 1990s (Convey et al., Reference Convey, Barnes and Morton2002). Plastic equipment used at scientific stations, the clothing of scientists and support staff, wastewater treatment systems and polyethylene terephthalate (or PET)-based- wayfinding flags (an essential element of Antarctic establishments) all produce microplastics that are distributed in the Antarctic environment (Aves et al., Reference Aves, Revell, Gaw, Ruffell, Schuddeboom, Wotherspoon, LaRue and McDonald2022). This often involves deposition onto snow, which forms the ice sheet and ice shelves of Antarctica—the ultimate fates of which are either calving into the ocean or melting. Within this extreme environment, some studies suggest that plastics emerge from sea spray and are driven by wind to on-shore freshwater environments or onto glacier surfaces (González-Pleiter et al., Reference González-Pleiter, Edo, Velázquez, Casero-Chamorro, Leganés, Quesada, Fernández-Piñas and Rosal2020; González-Pleiter et al., Reference González-Pleiter, Lacerot, Edo, Pablo Lozoya, Leganés, Fernández-Piñas, Rosal and Teixeira-de-Mello2021).

Plastic is also a component of debris in Earth orbit, deep space and on planetary surfaces (Gorman, Reference Gorman, Godin, Pétursdóttir, Praet and Schofield2024; Olatunji, Reference Olatunji2024), meaning that the outer limit of the technosphere is coterminous with the furthest human spacecraft (Voyager 1). Plastics sent to space are designed to be robust in local conditions, such as temperature extremes and radiation exposure. They are widely used on spacecraft as internal insulation for delicate electronics and as external insulation in the form of aluminised Kapton polyimide blankets (Gorman, Reference Gorman, Godin, Pétursdóttir, Praet and Schofield2024). However, once discarded in space, these plastics rarely re-enter terrestrial systems of use and discard. In Earth’s orbit, there are an estimated 36,000 pieces of space junk over 10 cm in size, including defunct satellites, fragments of exploded spacecraft and mission-related debris (Cacioni, Reference Cacioni2022). Space junk weighs ~9,000 tons, but the proportion of plastic in this mass is unknown (NASA Orbital Debris Program Office, n.d., FAQ #3). The amount of plastic in Earth’s orbit has radically increased with the launch of thousands of satellites in mega constellations, such as Starlink. Debris under about 2,000 km in altitude is eventually drawn back towards Earth by atmospheric drag, where it incinerates in the atmosphere.

Finally, it is not just the plastics themselves that can be incorporated into the archaeological record. Plastics in the environment interact with their surroundings and are known to act as vectors for biota (Naik et al., Reference Naik, Naik, D’Costa and Shaikh2019), metals (Brennecke et al., Reference Brennecke, Duarte, Paiva, Caçador and Canning-Clode2016) and chemicals (Rodrigues et al., Reference Rodrigues, Duarte, Santos-Echeandía and Rocha-Santos2019). Although part of a broader concern for planetary mixing (e.g., water vectors, neobiota and industrial emissions), floating plastics can also act as a transport pathway for rafting marine species (González-Ortegón et al., Reference González-Ortegón, Demmer, Robins and Jenkins2024). This can change the species’ dispersal, allowing them to travel to new locations and extending their spatial distribution.

Redefining biota as an archaeological context

As well as being in the air, clouds, soil and rainwater, micro- and nanoplastics are also found in human and non-human biota (e.g., Leonard et al., Reference Leonard, Liddle, Atherall, Chapman, Watkins, Calaminus and Rotchell2024) and in the waste that bodies create (Rotchell et al., Reference Rotchell, Austin, Chapman, Atherall, Liddle, Dunstan, Blackburn, Mead, Filart, Beeby, Cunningham, Allen, Draper and Guinn2024b). Plastic particles routinely infiltrate biological bodies, meaning that components of all biota now contain a plastic decay product. This archaeological record exists inside the bodies of plants and animals, as no other artefact type has done before (unless we define geochemical traces as artefacts, in which case radiocarbon, strontium, lead, mercury, etc., will have preceded plastics as examples).

Plants and animals ingest plastics, some of which make their way out of the body during their lifetime, and others of which remain until the entity’s death, sometimes being the cause of it. Thus, animal and plant bodies bearing assemblages of plastics become archaeological sites in themselves, with archaeological ‘depth’ as a reflection of how far plastic particles have penetrated the different levels of the body. Living bodies size-sort plastics as efficiently as a river current, with layers of barriers sieving the particles to the point where nanoparticles pass through the cell membranes. While these plastics may or may not be attributable to a specific source, they will likely map onto the broader distribution of plastic producers and consumers.

The interaction of plastics with biota attracts significant research interest. However, there is insufficient evidence regarding long-term accumulation in the tissues or cells and the specific type of effects they may have on humans. Micro- and nanoplastics in aquatic environments integrate with biota and move through the food webs to accumulate in seafood organisms (Smith et al., Reference Smith, Love, Rochman and Neff2018), which are available for humans through their diet. Additionally, the localization of plastics in soil and potential accumulation in fruits and vegetables (Aydın et al., Reference Aydın, Yozukmaz, Şener, Temiz and Giannetto2023) represent another vector of micro- and nanoplastics distribution. The health effects on humans can vary depending on the size of the plastic particles. The potential risk increases with smaller particles <1 μm, which affect various organs, tissues and cells of human bodies. Studies have documented accumulation in fat tissue (Abbasi et al., Reference Abbasi, Soltani, Keshavarzi, Moore, Turner and Hassanaghaei2018), penetration through blood barriers (Leonard et al., Reference Leonard, Liddle, Atherall, Chapman, Watkins, Calaminus and Rotchell2024) and cell membranes (Järvenpää et al., Reference Järvenpää, Perkkiö, Laitinen and Lahtela-Kakkonen2022). The presence of microplastics in human faeces (Yan et al., Reference Yan, Liu, Zhang, Zhang, Ren and Zhang2021) can give an idea of further potential pathways. In summary, the main consequences of plastic and biota interaction include physical damage, chronic toxicity, cell damage and inflammation, inducing oxidative stress, among others (Wright et al., Reference Wright, Thompson and Galloway2013; Eltemsah and Bøhn, Reference Eltemsah and Bøhn2019).

How (and how far) do plastics degrade? How long will they last?

Plastics have only been around for seven to eight decades. Despite extravagant claims about their longevity, it is difficult to know exactly how long their degradation process will take and what their final form will be in archaeological records in the distant future. Once reduced to nanoplastics, will they forever stay in that form or decompose back to their monomer of origin or into even smaller molecules like CO₂ and water? To start answering these questions, and replicate the long time frames present in archaeological contexts, scientists are using accelerated weathering experiments aiming to predict how long the degradation processes may take in different environmental matrices (e.g., under the sun, in seawater and in soil), with reported estimates spanning from decades to more than a thousand years (e.g., Chamas et al., Reference Chamas, Moon, Zheng, Qiu, Tabassum, Jang, Abu-Omar, Scott and Suh2020). The large variations seen in these forecasts are at least in part due to the fact that many variables, beyond the plastic type itself, influence degradation. For instance, one of the reported ways that plastics become integrated with the natural environment is through the genesis of plastiglomerates (Corcoran et al., Reference Corcoran, Moore and Jazvac2014), a new type of geological formation, such as pyroplastics, plasticrusts and plastitars, which represent the combination of plastics and solid particles (gravel, sand, silt and clay) under the influence of mechanical and chemical weathering. Resulting from n-transforms, plastiglomerates were recently found in the Canary Islands (Domínguez-Hernández et al., Reference Domínguez-Hernández, Villanova-Solano, Sevillano-González, Hernández-Sánchez, González-Sálamo, Ortega-Zamora, Díaz-Peña and Hernández-Borges2022) and in various locations in the Mediterranean (Saliu et al., Reference Saliu, Compa, Becchi, Lasagni, Collina, Liconti, Suma, Deudero, Grech and Suaria2023).

As we have seen, once they have entered the archaeological record, plastics break down into smaller debris under the action of mechanical friction, UV, temperature, in association with prolonged exposure to oxygen and water, and with the help of microorganisms, such as hydrocarbon-eating bacteria (Valenzuela-Ortega et al., Reference Valenzuela-Ortega, Suitor, White, Hinchcliffe and Wallace2023). These external factors challenge the integrity of plastics via both physical and chemical processes. In the former, plastics are cracked, chipped or abraded, while the latter refers to the breaking of chemical bonds via oxidation and hydrolysis reactions typically initiated by light or temperature. Entire scientific journals are dedicated to advancing our understanding of plastic degradation (e.g., Polymer Degradation and Stability), including in the context of recycling (e.g., Progress in Rubber, Plastics and Recycling Technology).

The decay of plastics in the archaeological record in space has not previously been specifically considered beyond the life of individual spacecraft, but is important for the sustainable use of space environments (e.g., Gorman, Reference Gorman2023, Reference Gorman, Godin, Pétursdóttir, Praet and Schofield2024). The plastics in Elon Musk’s red Tesla sports car, launched into solar orbit in 2018 and unshielded from radiation, will likely already be heavily degraded through radiation and interplanetary dust impacts (Gorman, Reference Gorman, Godin, Pétursdóttir, Praet and Schofield2024). On the Moon, it is expected that the famous nylon US flags at the six Apollo sites will have broken down under UV radiation. The Apollo landing vehicles were encased in aluminised Kapton blankets, which have been subjected to micrometeorite bombardment and dust abrasion (Gorman, Reference Gorman, Godin, Pétursdóttir, Praet and Schofield2024). This creates microplastics, which are now incorporated into the regolith of the sites. It is not known how long such plastics can be expected to survive on an airless world or in what ways they will have been broken into smaller particles, but they may now have a widespread distribution across the Moon.

What variables can influence degradation?

Most plastics are considered non-biodegradable because they can persist in the environment for many years; however, this could be a perception created by the short time span that we have available for observation. What is clear is that plastics, in terrestrial, extra-terrestrial and marine environments, break down into smaller particles through photo-, thermo- and/or biodegradation (Andrady, Reference Andrady2011) and through mechanical stress (e.g., wave action). Plastic formulations often include plasticisers (e.g., diethylhexylphthalate and bisphenol A) to increase flexibility and tensile strength. Under exposure to UV radiation, temperature changes and mechanical stress or when microorganisms attach to the plastic objects and fragments, these additives can leach out, weakening the plastic and leaving a distinct chemical signature (Rochman et al., Reference Rochman, Hoh, Kurobe and Teh2013; Magnusson and Norén, Reference Magnusson and Norén2014).

In the aquatic environment, plastics are often colonised by microorganisms (bacteria, microalgae, fungi and viruses), forming novel ecological habitats known as plastispheres (Zettler et al., Reference Zettler, Mincer and Amaral-Zettler2013). This phenomenon is considered to be a planetary-scale consequence of the Anthropocene. The algal bacterial biofilm that forms on the plastic surfaces attracts bigger organisms (such as Protista and invertebrates), leading to the establishment of multilayered biological deposits, which can affect the buoyancy of the plastics. As a result, plastic particles start to submerge and move from the surface to deeper water columns.

In the ocean water column, some bacteria secrete enzymes that can degrade polymers into monomers and oligomers. These marine processes are similar to those occurring in rivers or terrestrial environments (e.g., Yoshida et al., Reference Yoshida, Hiraga, Takehana, Taniguchi, Yamaji, Maeda, Toyohara, Miyamoto, Kimura and Oda2016). It has also been reported that some fungal species can degrade plastics, particularly polypropylene (Samat et al., Reference Samat, Carter and Abbas2023). Interestingly, recent studies suggest that newly developed biodegradable plastics (e.g., polylactic acid, or PLA) can be degraded by microorganisms in the deeper layers of the ocean, but with less efficiency compared to the coastal environment (Omura et al., Reference Omura, Isobe, Miura, Ishii, Mori, Ishitami, Kimura, Hidaki, Komiyama, Suzuki, Kasuya, Nomaki, Nakajima, Tsuchiya, Kawagucci, Mori, Nakayama, Kunioki, Kamino and Iwata2024).

In open space, plastics break down much more quickly. Atomic oxygen, common in Earth’s ionosphere, is highly damaging, as the single O atom bonds easily with the organics in plastic, breaking the chemical bonds. Ionising radiation breaks polymers up into intermediate products, such as free radicals and atomic elements (Aldas et al., Reference Aldas, Valle, Aguilar, Pavon, Santos and Luna2020, 2). In Low Earth Orbit, where the majority of spacecraft and space junk circulates, the synergistic effect of atomic oxygen corrosion and exposure to vacuum UV radiation has been described as having an ‘aggressive’ effect on polymers (Shuvalov et al., Reference Shuvalov, Tokmak and Reznichecnko2016, 442; see also Zhao et al., Reference Zhao, Shen, Xing and Ma2005). This deleterious effect, however, is utilised in additives to make plastics biodegradable by simulating the effects of atomic oxygen (Aldas et al., Reference Aldas, Valle, Aguilar, Pavon, Santos and Luna2020).

Planetary environments have specific factors that contribute to plastic degradation. On airless bodies, such as the Moon, Mercury, asteroids and comets, there is radiation exposure and impact gardening, creating an electrostatic charge and causing a constant turnover of the surface. External plastics, such as thermal insulation, would eventually break down under this bombardment. Mars is a high radiation environment as it has no magnetic field to protect it; it also has mechanical factors such as constant dust storms. On Venus, several USSR spacecraft successfully navigated the sulphuric acid-rich cloud decks to land on the surface with their internal plastics intact. If there are external plastics, slow dust abrasion may contribute to their degradation.

How do plastics move within the archaeological record?

As previously discussed, plastics enter the environment from terrestrial and aquatic pathways, including sewage and wastewater systems, riverine inputs, aquaculture and fishing activities. However, some of these pathways are poorly understood. In broad terms, the study of plastics has, to date, focused mostly on the hydrosphere, with far fewer analyses of the role of the subsurface (Haque and Fan, Reference Haque and Fan2023).

Within the marine environment, plastics, especially micro- and nanoplastics, behave as any other inert particle with specific buoyancy properties, depending on the currents and turbulence they are subjected to. Depending on hydrodynamic conditions in coastal areas, debris can be washed ashore, or it can sink to the seafloor in deeper ocean layers, as free-floating particles or embedded within dejections from aquatic organisms that have consumed them with their natural food. The fate of plastics in the abyssal environment, below 4,000 m, is unknown.

The transport and persistence of microplastics in the subsurface (the traditional domain for archaeological investigation) is influenced by a wide range of factors that need to be considered in interpreting their concentrations in soils and groundwater samples. These particular n-transforms are less well understood but include (after Dong et al., Reference Dong, Yu, Huang, Gao and Gao2022; Guo et al., Reference Guo, Huang, Xiang, Wang, Li, Li, Cai, Mo and Wong2020; Haque and Fan, Reference Haque and Fan2023) the following: (i) particle size, morphology, density and concentration; (ii) fauna and flora, including the presence of microorganisms; (iii) porous media and fluid properties; and (iv) aggregation, recognising that many of these factors are interrelated.

Contreras–Llin and Diaz-Cruz (Reference Contreras–Llin and Diaz-Cruz2024) found that microplastics are retained to different degrees within different mixtures of sand, compost, wood chips and clay, concluding that sand was the least effective in retaining them. This manifested in the distribution of microplastics (along the flow path) within reactive barriers, whereby upstream sediment contained the highest microplastic concentrations, except in barriers containing only sand, in which the most upstream sediments had the lowest concentrations. The microbial activity within porous materials with higher organic proportions, such as compost, was thought to add to the retention capacity and foster favourable conditions for microplastic breakdown. Whether or not microbes transform or degrade, the microplastic signature over time remains unclear. Sands and other highly permeable porous media are unlikely to retain an archaeological record of microplastics, whereas other porous media types may be more likely to. Some porous media likely provide a stronger record of load where microplastics change the properties of the media (e.g., Li et al., Reference Li, Wang, Zhu, Zhu, Yi and Fu2024b), such that an accumulation is encountered in horizons within the soil where the pore space (or void) has been interrupted through microplastic aggregation and clogging. Although this process has yet to be encountered in published field studies of groundwater systems, Li et al. (Reference Li, Huang, Wang, Cheng, Chen, Zhou, Xiao, Li, Du and Xu2024a) describe the types of controlling factors that are likely to affect microplastic transport and accumulation in porous media.

Progress on links between microplastic characteristics and causes, pathways and residence times is summarised by Lee et al. (Reference Lee, Cha, Ha and Viaroli2024) and Li et al., Reference Li, Huang, Wang, Cheng, Chen, Zhou, Xiao, Li, Du and Xu2024a. They report a lack of research into the pathways through which microplastics travel within groundwater systems, including the many mechanisms affecting their transport that differ from other groundwater-borne contaminants, including other colloids. He et al. (Reference He, McDonald, Zainab, Guo, Chen and Xu2024) analysed reports of microplastics within aquifers at various sites across the globe, finding that open groundwater sites (springs and karst systems) produced microplastics of higher abundance, larger particles and greater colour diversity relative to closed groundwater sites (other aquifer types). They also noted that microplastics in agricultural areas are more likely to be transparent, probably due to the mulches used. The lack of standardised detection protocols for assessing microplastic pollution of groundwater inhibits the current understanding of their characteristics attributable to specific causes (He et al., Reference He, McDonald, Zainab, Guo, Chen and Xu2024). This could also limit the utility of microplastic analyses in archaeological investigations.

An unresolved question is at what point microplastics become non-diagnostic. The composition of microplastics varies depending on the source and pathway through the subsurface (Li et al., Reference Li, Wang, Zhu, Zhu, Yi and Fu2024b). Given this, it is likely that the compositional signature of a sample can be traced to its origins, as is standard practice in modern environmental tracer studies (e.g., Cartwright et al., Reference Cartwright, Werner and Woods2019). An assessment by Lee et al. (Reference Lee, Cha, Ha and Viaroli2024) of polymer types encountered at field sites from across the globe showed that polypropylene and polyethylene were the most common. The composition of polymers showed wide variation between sites. The assessment of eight different polymers demonstrated specific signatures, although the list of polymer types found in groundwater is much larger. Lee et al. (Reference Lee, Cha, Ha and Viaroli2024) found that the variability in polymer types was likely related to the degree of contamination exposure, whereby sites of greater contamination tended to have a wider variability. More generally, the breadth of polymer types appears to be relatable to the land use, even if signatures specific to certain land-use types have not been defined in a systematic way.

Plastics move through sea ice in the Arctic and Antarctic regions, which are perhaps only a ‘temporary sink’ (Peeken et al., Reference Peeken, Primpke, Beyer, Gutermann, Katlein, Krumpen, Bergmann, Hehemann and Gerdts2018). Sea ice takes in microplastics present in the seawater, and the vertical composition then reflects microplastic concentrations in different locations as the sea ice forms during its drift. One study suggests long-range oceanic transport into the Arctic Ocean from the Atlantic and Pacific Oceans, and perhaps rivers, as well as localised inputs from increasing Arctic shipping traffic (Peeken et al., Reference Peeken, Primpke, Beyer, Gutermann, Katlein, Krumpen, Bergmann, Hehemann and Gerdts2018). Other studies suggest that sea ice contains higher concentrations of microplastics than the underlying seawater (Kanhai et al., Reference Kanhai, Gardfeldt, Krumpen, Thompson and O’Connor2020).

Plastics in space form their own ecosystem, with limited points of contact to the atmosphere and hydrosphere. These points of contact are objects, including trash, returned from crewed missions, reusable launch vehicles and space junk, which are robust enough to survive the re-entry process. Plastics in satellites or rocket stages in Low Earth Orbit, up to ~1,000 km above Earth, are eventually pulled back into the thermosphere to burn up. This process may take hundreds of years. Byproducts of atmospheric incineration are mostly soot and alumina. Burning plastics releases toxins, but their contribution to atmospheric pollution is likely to be negligible compared to the metal alloys that form the bodies of most rockets and satellites. The demise of the International Space Station will be a single event that will leave plastics scattered between space, the atmosphere and the ocean floor at Point Nemo. Point Nemo is a location in the South Pacific Ocean that is furthest from land in all directions. It has become a ‘spacecraft graveyard’ where space stations and other spacecraft are sent in controlled re-entries, where possible, to minimise environmental impacts.