This R&I action will focus on optimally combining traditional roll-to-roll (R2R) compatible fabrication technologies such as printing with unique R2R sputtering, ALD and heterogeneous integration for flexible, thin, large-area electronics applications. It is seen that the different R2R fabrication methods all have their strengths and weaknesses such that using a cost-performance-optimized combination of them for a single production will enable new levels of applicability for TOLAE devices for mass markets. The goal of the ROLL-OUT project is to create a multi-purpose technology for, thin, large-area, high-performance, smart, and autonomous systems comprising of integrated circuits (based on metal-oxide thin-film transistors), sensors, and electronics. They will be utilized in advancing the packaging, automotive interiors and textile industries beyond their traditional scope. The key features are high-performance circuits and components. To fabricate high-performance circuits, the project intends to use novel, hybrid, moderate-temperature, roll-to-roll processes, namely sputtering, Atomic Layer Deposition (ALD) and screen-printing on thin, flexible, large-area substrates. This will enable enormous value addition to the products of European industries without adding any significant extra cost. ROLL-OUT has 5 research organizations (RO) and 5 industrial partners (IND). The action has 6 work-packages (WPs) of which 3 are led by ROs and 3 by INDs. The technology development WPs are led by ROs and demonstration and exploitation WPs are led by INDs. The action intends to create 3 tangible industrial smart, autonomous system demonstrators that will be validated by the industrial partners in accordance with standard testing protocols. The action seeks EU funding of 3.66M€ for a period of 36 months. 356,5 person-months will be dedicated to the work. The consortium consists of partners from 7 EU member states with complimentary expertise essential for the action.

BioSupPBioSupPack goal is to deliver novel, cost-competitive and versatile bio-based packaging solutions based on PHA, that demonstrate high-performance for the packaging of food, cosmetics, homecare and beverage products as well as no environmental damage during & after their use, by means of: 1. Optimization of PHA based formulations based on significantly use of >85% w/w of renewable resources. 2. Upscale the different conversion processes as well as post-consumers waste sorting & recycling following advanced industry 4.0 approach. 3. Broad the range of rigid packaging applications by tailoring biobased materials & packaging properties through the optimization of the formulations in combination with plasma technology or grafted coatings. 4. Integrate plasma technology in 3 different points of the value chain(biomasss pre-treatment, packaging production & packaging waste pre-treatment) increasing: i)PHB production yield, ii)PHB purity, iii) packaging performance(high oxygen & water barrier) and iv effectiveness & yield of enzymatic recycling. 5. Demonstrate and increase recyclability through:i) setting up a real-time monitoring system for the selective separation of developed packaging after its use; ii) mechanical recycling of industrial scraps and selective enzymatic recycling of packaging waste as the best EoL, with the final recovery of carbon sources for feedstock fermentation. Thus, the new packaging is environmentally safe(sustainable and improved value from enzymatic recycling) and contributes to Circular Economy(CE). 6. Establish a new value chain including the development of logistics and management of both the brewery and packaging waste. Complying with the industry needs (cost/performance competitive vs. fossil-based non-biodegradable counterparts and legislative compliance),as well as with consumers´ awareness, BioSupPack will have a great impact on EU bioplastics & end users’ sectors, the biorefineries and biotechnology industries and on the society.

To succeed in the ambitious objective of achieving a climate-neutral EU by 2050 the nano-enabled bio-based materials sector shall respond to some specific risks in the short term. BIONANOPOLYS will address the following risks and challenges in order to strengthen the circularity of nano-enabled bio-based materials in the economy: › Acceptance of new technology by the market. › Seasonal sustainability of feedstocks. › Price competition and market. › Other risks: The existing legislation is costly in particular for small companies. For example, nano-ecotoxicology related to the use of nano-enabled materials in industry and/or food contact. Considering these challenges, BIONONAPOLYS Open Innovation Test Bed will improve technologies, processes, considering different feedstock. BIONANOPOLYS offers: › PILOT LINES: Cutting edge technology upgraded at TRL 7 with the objetive to produce nanoenabled biobased materials with multifunctional properties to be dispersed in cellulose and polymeric matrices assuring the best dispersion and the robustness of the final properties. Developed materials will be validated in application such as packaging, cosmetic, medical, foam, nonwoven, coating, 3D printing, textiles and cellulose-paper. › PRIMARY RAW MATERIALS FROM DIFFERENT FEEDSTOCKS: BIONANOPOLYS will use the most relevant feedstock in Europe to obtain bio-based nano-enabled composites. › HIGH VOLUME APPLICATIONS: BIONANOPOLYS offer solutions for more than the 50% of the applications that are currently using bio-based materials. › COMPLEMENTARY SERVICES: BIONANOPOLYS will offer to the industry a wide variety of services for the market uptake of a new bio-based nano-enabled products, such as safety protocols for bio-based nano-enabled materials, training for staff specialization, standardisation, business modelling, access to follow-on finance or IPR protection as a crucial mean of ensuring the capitalisation on the investments made by our stakeholders and other investors.

The Bio Innovation of a Circular Economy for Plastics (BioICEP) is a pan European-Chinese collaboration formed to reduce the burden of plastic waste in the environment. Different mixed plastic pollution environments are represented, with specific partners selected which have the expertise and facilities to carry out the necessary technical innovations. A number of innovative booster technologies are at the core of this solution accentuating, expediting, and augmenting mixed plastics degradation to levels far in excess of those current achievable. Our approach is The Bio Innovation of a Circular Economy for Plastics (BioICEP) consortium is a pan European-Chinese collaborative formed to reduce the burden of plastic waste in the environment. The countries have been selected to represent different mixed plastic pollution environments, with specific partners selected which have the expertise and facilities to carry out the necessary technical innovations. Three innovative booster technologies are at the core of this solution accentuating, expediting, and augmenting plastics degradation to levels far in excess of those current achievable. Our approach is a triple-action depolymerisation system where plastic waste will be broken down in three consecutive processes: 1) mechano-biochemical disintegration processes, including a new proprietary sonic-green-chemical technology to reduce the polymer molecular weight of the base polymer to make it amenable to biodegradation; 2) biocatalytic digestion, with enzymes enhanced through a range of innovative techniques including accelerated screening through novel fluorescent sensor and directed evolution; and 3) microbial consortia developed from best in class single microbial strains, which combined leads to highly efficient degradation of mixed plastic waste streams. The outputs from this degradation process will be used as building blocks for new polymers or other bioproducts to enable a new plastic waste-based circular economy.

BIO4COAT aims to validate at TRL 5 the use of 3 biobased building blocks (1,4-bioBDO, lcDCA, and biomethane) from Novamont’s biorefinery for producing safe and sustainable biobased coating solutions. Two value chains are planned: (1) Novamont will supply first-of-their kind polyester-polyols from 1,4-bioBDO and lcDCA for conversion into polyurethanes by FUNDITEC, to be used to create 1K PUD and 2K PUR in 7 prototypes under the guidance of ICAP-SIRA; (2) Aarhus University will purify biomethane for use by CEMECON in creating DLC coatings via CVD for high-temperature plastic processing tools, validated by LOGOPLASTE. Performance will be tested in terms of surface protection, printability, and controlled release under demanding conditions, with added recyclability, compostability, and no bioaccumulation, across 8 sectors (plastics, hygiene, textiles, agriculture, horticulture, furniture, energy, and construction). CERTH will implement a comprehensive SSbD methodology, guiding the development of biobased coatings with reduce (-20%) GHG emissions, allowing multiple EoL scenarios, and minimizing bioaccumulation risks. Upscaling insights(aligned with the CBE-JU TERRIFIC project), feasibility analyses, and business models will be supported by the University of Padua. KNEIA’s dissemination, exploitation, and communication efforts will maximize the visibility and impact of project outcomes. The analysis and engagement of stakeholder and the clustering activities will be performed at 2 levels: along the overall value chain by KNEIA, and with a focus on technical actors by EUBP which will establish 2 technical working groups with other EU-funded projects. Key impacts are expected in long-term progress in bio-based materials science and engineering, cost savings for industries by 30%, increased biodiversity and environmental health due to reduced pollution and sustainable resource use, expansion of the market for bio-based coatings, and enhanced competitiveness of EU SMEs