Agrochemicals (i.e., fertilizers and pesticides) are responsible for doubling crop yields over the last century. However, they cause multiple negative impacts on environmental and human health. To lessen their effects, the EU aims at reducing by 50% fertilizer losses and use of chemical pesticides by 2030. Controlled polymer-based delivery systems preventing agrochemical losses (e.g., lixiviation, volatilization) and resulting excessive inputs are available. However, they are based on non-biodegradable polymers and generate plastic pollution. Other agricultural plastics (mulch films and growth foams) are used to maintain a prosperous plant environment and prevent agrochemical wash-off, minimizing the quantities to be applied. However, they also result in significant amounts of non-biodegradable plastics being released into environment. PHAntastic tackles the reduction of agrochemicals and plastics pollution using PHAs, a family of bio-based biodegradable polymers. PHAntastic will develop two families of delivery systems (mulch films and growth foams) based on PHAs containing active bioproducts (amino acids & hydrolyzed proteins, microelements, elicitors and plant growth promoting rhizobacteria -PGPR) instead of synthetic agrochemicals. Products will be demonstrated with end users (TRL6) on horticultural crops and trees in Northern and Southern Europe. Experts in the Safe and Sustainable by Design framework will guarantee compliance. Market acceptance will be guaranteed through the development of business cases and exploitation strategies. PHAntastic will contribute to a significant reduction of agrochemicals (minimum 25% in fertilizers, 50% in pesticides, resulting in 23 K tons less of agrochemicals by 2050) and plastic (680 T microplastics less by 2050) in our agricultural systems. PHAntastic will thus contribute to a secure supply chain of food and a less impactful agriculture, boosting the sustainability, autonomy and competitiveness of vital EU value chains.

In the last years, extreme weather patterns of water scarcity (droughts) and water abundance (floods, rapid showers) are becoming more frequent and prolonged in the EU. If we do not remedy this situation, by 2050 water scarcity will lead to €12,2 billion losses per year and affect 17% of EU population. RAINS will contribute to improve the resilience of EU agriculture to water scarcity by demonstrating 10 solutions (irrigation practices, technologies and tools) that will increase the efficiency of water and nutrient management in agriculture and reduce the impact of extreme weather events. RAINS solutions include alternative forms of water supply, combined use of water and biofertilisers, improved soil water-retention, water-N/P modelling and some smart solutions (Optifangs-IA, WaterIQ) to contribute to decision-making and to integrated irrigation management across farm systems. Solutions will be demonstrated at 10 demo-farm systems representing agroecology, organic production, conventional, intensive and urban agriculture, replicated in Greece and Spain. We will also develop a hydrological and N/P model to optimised agriculture production at catchment level. A well, we will conduct co-creation workshops, knowledge transfer activities and create materials such as guidelines (2), White Papers (2) and Practice Abstracts (40). Policy focused sessions will deliver 3 sets of policy and incentives recommendations, engaging quadruple helix agricultural stakeholders, to pave the way for the uptake of sustainable irrigation and fertilization management solutions in practice in the EU. In the long term, RAINS will contribute to improve water efficiency by 50% in 12,700 ha. in more than 20 EU regions, and support >500 farmers in the transition to a more sustainable irrigation. And by 2050, the implementation of the RAINS project will save up to €6.1 billion, 244.348 million litres of water and 35.4 t CO2 eq. avoided emissions.

ReBioCycle proves a portfolio of bioplastic sorting and recycling technologies within 3 complementary waste-processor-centric HUB at DEMO scale and in the real operational environment the effective and efficient recycling of 3x types of bioplastics (PLA, PHA, Mater-Bi) to demonstrate higher impact of obtaining the same or superior grade recycled polymers and other higher value applications. - NL HUB chemical technology upscaling to TRL 6. Using TORWASH technology to recycle PLA & PHA polymers (500 kg each. KPI: at least 1 m3 solution of monomers from each of PLA/PHA free of solids. The NCTP Group waste sorting site of Heerenveen (Friesland, NL) and TEC, PBM, Corbion will be involved. - IT HUB chemical technology upscaling to TRL 7. NOVAMONT technology will be used to recycle 600 kg of mixed composites including Mater-Bi. Also PHA from the NL and ES Hub will be tested in the IT HUB to blend into further Mater-Bi bioplastic formulations. IREN Group waste sorting site of Borgaro Torinese (Piedmont, Italy) and NOVAMONT’s new dedicated bioplastics recycling section within its Terni (IT) plant will be involved. - ES HUB Enzymatic recycling technology brought to TRL 6 , producing 50 kg within reactors of 200 litre s (CSIC (supported by AIMPLAS pre-treatment). Microbial recycling technology (by the AD “short-circuited” technology of GPB and UCD via pure culture fermentation ) brought to TRL 7 resulting outcomes 100kg rPHA (PHBV & PHBHx) and 20 kg rPHBV. Mechanical Technology upscaling to TRL 7 with the KPI level to be achieved 250 kg bioplastic recycle (TCD, AIMPLAS involved). HUB activities in SAV waste sorting site of Manises (Valencia, Spain). ReBioCycle will verify the industrial grade specifications by biopolymer brand owners and via demonstration of real-world products: durable (ARAPAHA: PLA) and multi-use packaging (SULAPAC: PHA and Mater-Bi). The LCA analysis by ARCHA and tailored D&E plan by partners EUBP and MAGFI will facilitate KER uptake.