The PRISM model
The Netherlands, like Europe, aims to have a 100% circular economy by 2050. This is a difficult task as the entire system needs to be adapted. This transition goes hand in hand with – and at the same time reinforces – the energy transition that must drastically reduce greenhouse gas emissions. In order to investigate the opportunities for circular plastics and low-CO2 plastics, TNO is working on its own Plastic Recycling Impact Scenario Model: PRISM.
This model makes it possible to create future scenarios concerning the circularity of plastics. Using this model, TNO has carried out an initial study into the maximum circular plastic system of 2050.
The foundation for this scenario is our forecast of the future composition of plastic waste, which is based on the market growth in the various relevant sectors (packaging, construction, mobility, electronics, etc.), the trends related to plastic application in these sectors and the recyclability of the applied plastics.
The PRISM model then selects the desired recycling technologies for the different (mixtures of) polymers in order to achieve the desired goals in terms of (lifecycle) CO2 emissions and material production (quantity and quality).
Circular plastic scenario
Our methodology differs from most other models because we assume that the collection and sorting of the plastic will be adapted accordingly. The maximum circular plastic scenario is exploratory rather than predictive and is shown in the box (together with the most important assumptions). Work is currently underway to extend the model to include costs so that economic factors can also be included in the scenarios.
Future circular economy scenario for 2050
The maximum circular plastic scenario 2050 is illustrated by the Sankey diagram.
The first column (left) indicates the various raw materials used by the chemical industry for the production of different polymers (second column). The third column contains the market segments of these polymers and the fourth and fifth columns indicate the methodology used to collect and sort these plastic products and to process them (recycled, reconditioned or incinerated).
The last column (on the far right) shows the circularity of the system: a total of 87% of plastic waste can be processed into new products (as input on the left); from the remaining 12%, the energy is recovered. This is dependent on the efficient adaptation of the collection and sorting system to the conditions of the recycling technologies used. 1% leaves the system as litter, including microplastics.
The figure shows a flow chart (a Sankey diagram) that represents how plastics can "flow" through our society in a circular economy in 2050, from raw material to end of life. Each color of the flow reflects a different process, and the thickness of the flow equals the size of the stream. The flow chart starts with raw material, which is either fossil (such as oil), recyclate (already recycled plastic) or bio-based (from agricultural products). The next column presents the type of polymers made from this. The third column shows the different product groups made from these polymers, such as packaging or electronics. Column four shows the flow of different methods of plastic waste collection and what the optimal recycling option is in 2050. Column five then shows how much new raw material we can produce from plastics by applying recycling.
The most important assumptions, as input for the PRISM model, are:
- Plastic waste in the Netherlands will increase by 50% by 2050.
- Plastics in different sectors have different lifespans, resulting in plastic waste in differing quantities.
- Plastic products are reused or reconditioned as much as possible.
- Sorting is optimal for all recycling techniques
- As a result of this, 50% less material will be lost during recycling.
- Litter will be reduced to 50% of the current share or recovered efficiently.
- Fossil raw materials will have been partially replaced by bio-based raw materials.
- Nothing is being dumped anymore.
Transition to a circular plastics economy
Our PRISM analysis of the plastics ecosystem shows that an accelerated transition from a linear to a circular plastics economy is technologically feasible up to about 87%. In addition to the obvious focus on technological developments in the field of sorting and recycling, requirements must also be met in order to complete this enormous task: firm policy, consumer acceptance and a sense of responsibility amongst producers and the entire value chain. These have not been included in the analysis.
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Pieter ImhofFunctie:Business developer and Cluster lead Circular Plastics
Pieter has always had a drive for technological, societal, financial and environmental innovations that contribute to a sustainable future. The combination of people skills, leadership ability and technological expertise have helped him throughout his career to counter complex challenges, build bridges across the entire value chain, and open the door to the new economy.
Toon van HarmelenFunctie:Project manager
With more than 30 years of experience in international energy and environmental policy, Toon van Harmelen is highly regarded for his work and vision in the field of industrial research. In his capacity at TNO, Toon concerns himself with identifying and evaluating sustainable technological solutions for the chemical industry, e.g. biobased economy, carbon capture, use and storage (CCUS), and electrification of chemical production. Of particular interest to Toon is his work on modelling a circular plastics system that incorporates mass flow analysis, dynamic stock modelling, cost optimisation and system impact assessment.
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Solving the dark side of today's plastic
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