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Briefing

Biodegradable and compostable plastics — challenges and opportunities

Briefing Published 27 Aug 2020 Last modified 07 Sep 2020
11 min read
Photo: © SuSanA Secretariat on Flickr
More and more plastic products are labelled as ‘compostable’, ‘biodegradable’, ‘oxo-degradable’ or ‘bio-based’. However, plastics made from bio-based materials are not necessarily compostable or biodegradable. Moreover, plastics that do biodegrade can be made from fossil fuel-based materials. What is the difference between compostable and biodegradable? What happens to biodegradable and compostable plastics when they are littered? Can citizens compost such products in their own gardens? Can such plastics be recycled? This briefing aims to answer these questions.

Key messages

  • If and how quickly a plastic item biodegrades depends on: (1) if it is designed for biodegradation or composting and (2) the conditions it is exposed to after use and for how long.
  • The conditions in home composters and in the open environment are very different compared to industrial composting plants and this affects the rate and extent of breakdown.
  • Biodegradable, compostable and bio-based plastics need clearer labelling and repeated awareness-raising campaigns targeting users to ensure their correct disposal and treatment.
  • In a circular economy, all plastics should be recycled into new plastics in the first instance. Compostable plastics that can be treated with bio-waste offer environmental benefits for specific applications and situations, provided their use is aligned with the bio-waste treatment infrastructure.

What are the challenges?


Plastics are a key material in modern life. They are versatile, light and can be produced at relatively low cost. Currently, only about 1 % of plastics and plastic products on the global market are considered bio-based, compostable and/or biodegradable (European Bioplastics e.V., 2020b).

Most plastics continue to be made from fossil fuels in a process that contributes to increased greenhouse gas emissions along their value chain. Indeed, plastics pollute throughout their life cycle from production, to use and finally through their disposal.

Recycling rates of plastic are low and plastics leak into the environment through, for example, littering, improper waste management and wear and tear of products. They can stay in nature for many years and potentially enter the food chain. Contamination with plastic particles is a particular challenge in terms of keeping compost made from separately collected bio-waste clean (EEA, 2020).

Biodegradable, compostable and bio-based plastics are increasingly promoted as a solution to some of these challenges. More and more consumer products, such as plastic bags, packaging and single-use cups, are labelled as ‘compostable’, ‘biodegradable’ or ‘bio-based’. But what exactly do these terms mean? To what extent can biodegradable, compostable and bio-based plastics help solve the sustainability challenges posed by plastics? And do they create new ones?

Biodegradable, compostable, bio-based — what does it all mean?

Biodegradable and compostable materials can be broken down by microorganisms into water, carbon dioxide, mineral salts and new biomass within a defined period of time. Whether a biodegradable or compostable plastic item biodegrades and how quickly that happens, strongly depends on the conditions it is exposed to during disposal. These include temperature, duration, the presence of microorganisms, nutrients, oxygen and moisture (De Wilde et al., 2013; van den Oever et al., 2017).

Different types of biodegradable and compostable plastics are designed to biodegrade under specified conditions (Box 1). In other conditions, they might biodegrade slowly or not at all  or fragment into microplastics.

Box 1. Overview of types of plastic

Biodegradable plastics are designed to biodegrade in a specific medium (water, soil, compost) under certain conditions and in varying periods of time.

Industrially compostable plastics are designed to biodegrade in the conditions of an industrial composting plant or an industrial anaerobic digestion plant with a subsequent composting step.

Home compostable plastics are designed to biodegrade in the conditions of a well-managed home composter at lower temperatures than in industrial composting plants. Most of them also biodegrade in industrial composting plants.

Bio-based plastics are fully or partly made from biological raw materials as opposed to the fossil raw material (oil) used in conventional plastics.

Non-biodegradable plastics last for long periods of time. They can disintegrate into smaller pieces, forming microplastics, and accumulate in the environment.

Oxo-degradable plastics include additives that, through oxidation, lead to their fragmentation into microplastics or chemical decomposition.

Biodegradable or compostable plastics can be produced from either bio-based or fossil raw material (feedstock) (Figure 1). They can be produced to have similar functionality to or the same functionality as conventional plastics (WRAP, 2020). The sustainability of bio-based materials, just as of fossil-based plastics, depends on production practices, the products’ lifetime and end-of-life treatment (EEA, 2018). The term bioplastics is sometimes used for plastics that are either bio-based or biodegradable, or both (European Bioplastics e.V., 2020c). Given that these have very different properties, consumers could misunderstand the rather vague term ‘bioplastics’.

 

Figure 1. Bio-based, bio-degradable and compostable plastics


Source:
ETC/WMGE and EEA.

Standards, labels and logos

European standards exist for assessing the compostability of plastics in industrial composting plants and the biodegradability of mulch films in soil for use in agriculture. Plastic materials or products fulfilling these standards may be certified and labelled accordingly (Table 1). To date, there is no European standard for assessing biodegradability in water. This is because the very variable conditions in freshwater and marine environments make standardisation difficult. However, the International Organization for Standardization is developing standards for testing biodegradability in specific marine environments.

Table 1. European standards for compostability and biodegradability of plastics in different environments and selected logos and certification schemes


Sources:
TÜV AUSTRIA (2012a, 2012b, 2012c, 2013, 2019), DIN CERTCO (2016, 2017, 2018), Hilton et al. (2020), European Bioplastics e.V. (2019, 2020a, 2020b), CIC (2020). Logos reproduced with permission from TÜV Austria Belgium NV, European Bioplastics e.V., DIN CERTCO and CIC — Consorzio Italiano Compostatori.

Any claim of compostability or biodegradability should be precise and clearly related to the conditions under which the properties apply. Certifications guarantee that a product complies with an established standard or a set of conditions defined by the certifier. Nevertheless, real-life conditions can differ from these conditions and hamper biodegradation. This is especially of concern for home composting and for biodegradability in soil and water (Hilton et al., 2020).

Industrially compostable plastic products are designed to biodegrade under specific, controlled conditions in industrial composting plants. They do not necessarily (fully) compost in semi-controlled home composters or in the uncontrolled conditions of the natural environment. Although labels for industrial compostability usually refer to the standard used for certification, bad practice exists in the consumer market (Hilton et al., 2020). Providing additional information beyond the label itself would enhance understanding of how to dispose of the product.

Consumer behaviour

The differences between ‘compostable in industrial composting plants’, ‘home compostable’, ‘biodegradable in soil/freshwater/marine water’ and ‘bio-based’ are not easy to understand. For example, in a survey in Germany, 58 % of respondents thought that all ‘bioplastics’ were compostable (Blesin et al., 2017). Many consumers struggle to understand environmental claims and labels and do not differentiate between certified labels and self-declared labels (EC et al., 2014).

Experience from bio-waste (food and garden waste) collection shows that measures that depend on consumer behaviour are only adopted by a certain share of the population. To increase participation, the measures need to be accompanied by customised awareness-raising and information campaigns (EEA, 2020). Teaching children about labels and correct waste sorting can also play an important role. How to correctly dispose of products made of industrially compostable plastics also depends on the local waste management system and treatment infrastructure.

Therefore, repeated, targeted and clear communication with consumers is needed to explain the differences between compostability and biodegradability in different environments. Additional measures, such as standardised colouring for industrially compostable bags or QR codes providing further information, could improve clarity.

There are fears that consumers might misunderstand biodegradability or compostability claims as a ‘licence to litter’, but evidence supporting or refuting these fears is scarce (Hilton et al., 2020).

Waste management of biodegradable and compostable plastics

A circular economy retains the value of products and materials in the economy as much as possible. Although biodegradable and compostable plastics are technically recyclable, they are currently not recycled back into plastic material. Rather, they are treated as an impurity in the recycling of conventional plastics when collected together. Increasing market shares in future could aggravate the situation but could also make recycling of certain biodegradable or compostable plastics economically viable (Crippa et al., 2019). Nevertheless, further research, innovation and investment into recycling plastics is required.

 

Anaerobic digestion treats bio-waste without the presence of oxygen. It generates a digestate and biogas, which is a renewable energy source.

Although compostable plastics do not add nutrient value to compost (Burgstaller et al., 2018), they have a role in supporting sustainable bio-waste management. Bio-waste from households and other sources is increasingly collected separately from other waste across Europe. Digesting or composting bio-waste in industrial digestion or composting plants results in compost or digestate that can be used as soil improver and fertiliser, as long as they comply with national quality requirements. Separate collection or home-composting of bio-waste will be mandatory in all EU Member States from the end of 2023 onwards (EU, 2018).

Contamination with conventional plastics is an increasing challenge for compost quality (EEA, 2020). Replacing conventional plastics with certified compostable plastics for items that are often mixed with or attached to food waste, e.g. fruit stickers or tea bags, can help reduce contamination with conventional plastics (Crippa et al., 2019; Hilton et al., 2020).

Experience shows that using compostable plastic bags increases the capture rate of food waste because consumers find them convenient (Burgstaller et al., 2018). Some municipalities and waste collectors therefore recommend or require the use of certified compostable plastic bags for collecting bio-waste. Others will not accept compostable plastic bags. The strategy also depends on the existing bio-waste treatment infrastructure (e.g. typical composting period, treatment capacity, anaerobic digestion technology, strategy for removing impurities, including plastics) (Burgstaller et al., 2018; Hilton et al., 2020).

Implications for Europe’s policy actions

The 2020 circular economy action plan envisages creating a clear policy framework for plastics with biodegradable properties (EC, 2020). This may entail:

  • harmonised rules for defining and labelling compostable and biodegradable plastics
  • finding out in which applications using such plastics has environmental benefits.

For example, compostable plastics have a potential environmental benefit in specific applications such as bio-waste collection bags and items attached to bio-waste (Hilton et al., 2020). This is provided that the technical set-up of the local bio-waste management infrastructure guarantees effective collection and biodegradation of such plastics. Agricultural mulch film is another example. Using biodegradable mulch film instead of conventional mulch film can potentially avoid long-term plastic accumulation in soil. This is because mulch films made of conventional plastics are difficult to completely remove from farmland (Crippa et al., 2019).

A labelling system needs to avoid confusing consumers. Awareness-raising campaigns and clear communication with consumers will improve their understanding of the labels used on plastics and ensure their correct disposal. Applications that increase the risk of littering or contamination of compost with plastics (including those that are compostable or biodegradable) might have to be restricted. They may need to be prevented from being marketed as biodegradable or compostable.

Biodegradable and compostable plastics can offer environmental benefits if developed for specific situations and applications. Further improvements are urgently needed. The market for such products is likely to grow in the coming years. However, compostable and biodegradable plastics are far from providing a general, stand-alone solution to the challenges Europe faces with plastics today.

References

Blesin, J. M., et al., 2017, Bevölkerungsrepräsentative Online-Befragung in Deutschland zu Biokunststoffen, Arbeitsbericht Oktober 2017, Hochschule Hannover, Hochschule Weihenstephan-Triesdorf, Hannover, Germany, accessed 20 June 2020.

Burgstaller, M., et al., 2018, Gutachten zur Behandlung biologisch abbaubarer Kunststoffe, TEXTE 57/2018, Umweltbundesamt, Dessau-Rosslau, Germany, accessed 19 June 2020.

CIC, 2020, ‘Guaranteeing biodegradability and compostability of materials and products’, Consorzio Italiano Compostatori, accessed 20 June 2020.

Crippa, M., et al., 2019, A circular economy for plastics: insights from research and innovation to inform policy and funding decisions, Publications Office of the European Union, Luxembourg.

De Wilde, B., et al., 2013, Report on current relevant biodegradation and ecotoxicity standards, Deliverable 6.1, OWS, Ghent, Belgium, accessed 20 June 2020.

DIN CERTCO, 2016, ‘Certification Scheme - Products made of compostable materials for home and garden composting according to AS 5810 and/or NF T 51-800’, DIN CERTCO, accessed 2 July 2020.

DIN CERTCO, 2017, ‘Certification Scheme - Products made of compostable materials (DIN-Geprüft) according to DIN EN 13432, if applicable, in connection with DIN EN 14995, ISO 17088, ISO 18606, AS 4736’, DIN CERTCO, accessed 2 July 2020.

DIN CERTCO, 2018, ‘Certification scheme biodegradable in soil according to DIN EN 17033’, DIN CERTCO, accessed 20 June 2020.

EC, et al., 2014, Consumer market study on environmental claims for non-food products. Final report, Publications Office of the European Union, Luxembourg, accessed 10 March 2020.

EC, 2020, Communication from the Commission to the European Parliament, the Council, the Economic and Social Committee and the Committee of the Regions ‘A new circular economy action plan for a cleaner and more competitive Europe’ (COM(2020) 98 final of 11 March 2020).

EEA, 2018, The circular economy and the bioeconomy — partners in sustainability, EEA Report No 8/2018, European Environment Agency, accessed 20 June 2020.

EEA, 2020, Bio-waste in Europe — turning challenges into opportunities, EEA Report No 4/2020, European Environment Agency, accessed 20 June 2020.

EU, 2018, Directive (EU) 2018/851 of the European Parliament and of the Council of 30 May 2018 amending Directive 2008/98/EC on waste (OJ L 150, 14.6.2018, p. 109-140).

European Bioplastics e.V., 2019, ‘Guidelines for the use of the seedling logo’, accessed 20 June 2020.

European Bioplastics e.V., 2020a, Accountability is key — environmental communication guide for bioplastics, accessed 20 June 2020.

European Bioplastics e.V., 2020b, ‘Bioplastics market data’, accessed 10 March 2020.

European Bioplastics e.V., 2020c, ‘What are bioplastics?’, accessed 8 July 2020.

Hilton, M., et al., 2020, Relevance of biodegradable and compostable consumer plastic products and packaging in a circular economy, Project conducted under Framework Contract No ENV.B.3/FRA/2017/005 for the European Commission DG Environment, accessed 20 April 2020.

TÜV AUSTRIA, 2012a, ‘OK biodegradable SOIL: initial acceptance tests’, accessed 20 June 2020.

TÜV AUSTRIA, 2012b, ‘OK compost HOME: initial acceptance tests’, accessed 20 June 2020.

TÜV AUSTRIA, 2012c, ‘OK compost INDUSTRIAL: initial acceptance tests’, accessed 20 June 2020.

TÜV AUSTRIA, 2013, ‘OK biodegradable WATER: initial acceptance tests’, accessed 20 June 2020.

TÜV AUSTRIA, 2019, ‘OK biodegradable MARINE: Initial acceptance tests’, accessed 3 July 2020.

van den Oever, M., et al., 2017, Bio-based and biodegradable plastics: facts and figures — focus on food packaging in the Netherlands, Report No 1722, Wageningen University, Wageningen, accessed 6 November 2019.

WRAP, 2020, Understanding plastic packaging and the language we use to describe it, Waste and Resources Action Programme, Banbury, UK, accessed 19 March 2020.

Identifiers

Briefing no. 09/2020
Title: Biodegradable and compostable plastics — challenges and opportunities
PDF - TH-AM-20-009-EN-N - ISBN 978-92-9480-257-6 ISSN 2467-3196 doi: 10.2800/552241
HTML - TH-AM-20-009-EN-Q - ISBN 978-92-9480-258-3 - ISSN 2467-3196 - doi: 10.2800/230365
The withdrawal of the United Kingdom from the European Union did not affect the production of this briefing. Data reported by the United Kingdom are included in all analyses and assessments contained herein, unless otherwise indicated.

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