* DIGITS-AU is the essential Airspace User complement to the DIGITS project (Demonstration of ATM Improvements Generated by Initial Trajectory Sharing). DIGITS was granted under H2020-SESAR-2015-2, SESAR.ID-VLD.Wave1-27-2015, and its continuation is dependent on the participation of Airspace Users (AU). * As required, DIGITS-AU brings together Airspace Users - who operate (even partially) in the airspace of ANSPs participating to DIGITS, namely DFS, ENAV, MUAC and NATS and - who will receive through this Call new onboard avionics capability which allows to downlink trajectory predictions, the so-called Extended Projected Profile (EPP), for sharing with Air Traffic Control. * This proposal addresses also the interface with other SESAR 2020 projects, by nature with PJ31 DIGITS, but also with PJs 01, 09, 10 and 18 in order to contribute to the identification of benefit potentials facilitated by this new airborne technology. The capture of real fuel burn reduction for DIGITS-AU flights is not possible due to the fact that ground ATC systems are used in an pre-operational or shadow mode, based on which air traffic controllers may not alter their instructions. Nevertheless "what-if" cases shall be identified as far as observations possibly allow and the theoretical fuel burn gain calculated.

Oil is the most important source of energy worldwide, accounting for 35% of primary energy consumption and the majority of chemical feedstocks. The quest for sustainable resources to meet demands of a constantly rising global population is one of the main challenges for mankind this century. To be truly viable such alternative feedstocks must be sustainable, that is "have the ability to meet 21st century energy needs without compromising those of future generations." Development of efficient routes to large-scale chemical intermediates and commodity chemicals from renewable feedstocks is essential to have a major impact on the economic and environmental sustainability of the chemical industry. While fine chemical and pharmaceutical processes have a diverse chemistry and a need to find green alternatives, the large scale production of petrochemical derived intermediates is surely a priority issue if improved overall sustainability in chemicals manufacture is to be achieved. For example, nylon accounts for 8.9% of all manmade fibre production globally and is currently sourced exclusively from petrochemicals. It is one of the largest scale chemical processes employed by the chemicals sector. Achieving a sustainable chemicals industry in the near future requires 'drop in' chemicals for direct replacement of crude oil feedstocks. The production of next-generation advanced materials from the sustainably-sourced intermediates is a second key challenge to be tackled if our reliance on petrochemicals is to end The project will develop new heterogeneously catalysed processes to convert cellulose derivatives to high value platform and commodity chemicals. We specifically target sustainable production of intermediates for manufacture of polyamides and acrylates, thereby displacing petroleum feedstocks. Achieving the aims of the project requires novel multifunctional catalyst technology which optimises the acid-base properties, hydrogen transfer and deoxygenation capability. Using insights into catalyst design gleaned from our previous work, a directed high-throughput (HT) catalyst synthesis and discovery programme will seek multifunctional catalyst formulations for key biomass transformations. Target formulations will be scaled up and dispersed onto porous architectures for study in lab-scale industrial-style reactors. We will also seek to exploit multi-phase processes to improve selectivity and yield. This will be combined with multi-scale systems analysis to help prioritise promising pathways, work closely with industry to benchmark novel processes against established ones, develop performance measures (e.g. life cycle analysis (LCA)) to set targets for catalytic processes and explore optimal integration strategies with existing industrial value chains. Trade-offs between optimising single product selectivity versus allowing multiple reaction schemes and using effective separation technology in a "multiproduct" process will be explored. The potential utilization of by-products as fuels, sources of hydrogen, or as chemical feeds, will be evaluated by utilizing data from parallel programmes.

The SESAR work programme is in the Airline TEAM 2020 consortiums’ understanding an integrated Programme, involving all relevant stakeholders, where SESAR Solutions are matured for integration into the European ATM network in order to enhance its operational and economic efficiency, safety, security and capacity. It further develops and delivers the necessary operational and technical materials (specifications, procedures, prototypes, validation reports, etc.) for the progressive industrialisation, deployment and operation of a new ATM system. The consortium expects that SESAR 2020 will bring new ideas to the market and increase the pace of change in ATM, being part of the technology pillar of the European Union’s Single European Sky (SES). Ultimately, this means greater mobility and choice for our passengers in Europe; a more collaborative and better performing network. SESAR 2020 is also addressing the technology improvements as virtualisation and ATC contingency readiness, needed for better air traffic management in case of strikes and disruptions Aviation is a global industry and interoperability together with global harmonisation are key for its safe and sustained growth. The consortium will operationally support by this offer a project which will demonstrate the benefits for Airspace User (AU) in the operation of cross-border Arrival Management systems (AMAN) with an extended horizon in accordance with the Pilot Common Project (PCP) First Air Traffic Management (ATM) Functionality (AF#1), as well as the demonstration of AU involvement in the operation of two AMAN-related advanced concepts: the Target Time (TT) management concept and the Arrival Flexibility (A-FLEX) concept, which connect the Extended AMAN concept to the PCP Fourth ATM Functionality (AF#4). The consortium will ensure the required operational capabilities of European airspace users to contribute to the overall project objectives of SESAR 2020 PJ 25.