The field of matter-wave interferometry is emerging as a highly-promising interdisciplinary field, at the interface between fundamental science and quantum technologies/photonics/semiconductor European industry. The primary goals of MAWI are to use the exquisite control of ultracold quantum matter to implement guided matter-wave interferometers and to train young researchers in the emerging fields of matter-wave interferometry and quantum sensors based on interferometric schemes. The remit of MAWI is in the area of novel quantum sensing devices, with potential sensitivity enhancement of several orders of magnitude with respect to existing devices. Achieving this goal requires training the next generation of “quantum interferometry researchers” to a broad range of topics from fundamental to applied science, including both experimental developments and modelling, with strong connections to industry and emerging technological trends. Our training network focuses on the combination of optimal preparation of initial ultracold atomic sources and potentials to control and guide the atoms; their combination to build integrated guided atom interferometers for precision measurements, e.g., of rotations and accelerations; and technological advances towards their miniaturisation. The end goal of a fully-integrated cold atom quantum device could become a major commercial tool in the coming decade, complementing, or potentially even hybridising with, parallel developments in the photonics and semiconductor industries. Supported by our state-of-the-art facilities, our complementary expertise and skills, the participation of well-known European companies and a broad range of established external partners, we are poised to make lasting contributions to the scientific and technological developments of integrated matter-wave architectures and to the training of the next generation of research leaders who will propel quantum technologies even beyond our current expectations.

Five leading European supercomputing centres are committed to develop, within their respective national programs and service portfolios, a set of services that will be federated across a consortium. The work will be undertaken by the following supercomputing centres, which form the High Performance Analytics and Computing (HPAC) Platform of the Human Brain Project (HBP): ▪ Barcelona Supercomputing Centre (BSC) in Spain, ▪ The Italian supercomputing centre CINECA, ▪ The Swiss National Supercomputing Centre CSCS, ▪ The Jülich Supercomputing Centre in Germany, and ▪ Commissariat à l'énergie atomique et aux énergies alternatives (CEA), France (joining in April 2018). The new consortium will be called Fenix and it aims at providing scalable compute and data services in a federated manner. The neuroscience community is of particular interest in this context and the HBP represents a prioritised driver for the Fenix infrastructure design and implementation. The Interactive Computing E-Infrastructure for the HBP (ICEI) project will realise key elements of this Fenix infrastructure that are targeted to meet the needs of the neuroscience community. The participating sites plan for cloud-like services that are compatible with the work cultures of scientific computing and data science. Specifically, this entails developing interactive supercomputing capabilities on the available extreme computing and data systems. Key features of the ICEI infrastructure are: ▪ Scalable compute resources; ▪ A federated data infrastructure; and ▪ Interactive Compute Services providing access to the federated data infrastructure as well as elastic access to the scalable compute resources. The ICEI e-infrastructure will be realised through a coordinated procurement of equipment and R&D services. Furthermore, significant additional parts of the infrastructure and R&D services will be realised within the ICEI project through in-kind contributions from the participating supercomputing centres.

Lasers4EU is incorporating the major laser research infrastructures, in a large number of European member states, into a comprehensive virtual distributed laser research infrastructure that is offering to a broad user community, from academia and industry, access to an exceptional portfolio of technical and scientific capabilities. This unique set of instruments together with the specific scientific expertise at the host facilities allows Lasers4EU users to carry out high-level research in an extremely wide range of high-impact topics in life sciences, materials nano-processing, etc. Laser technology has experienced remarkable advances and breakthroughs and is now a key innovation driver for highly diversified societal applications and products, thereby substantially contributing to economic growth and to solving challenges in the areas of health, environment and energy. Through its strategic approach, Lasers4EU aims to strengthen Europe’s leading position and competitiveness. It facilitates long-term coordination of the laser research activities within the European Research Area and provides concerted and efficient services to scientific, industrial and medical researchers. The main objectives of Lasers4EU are to: • provide coordinated access to high-quality services based on a coherent and comprehensive consortium of 27 leading European laser installations offering to users from academia as well as from industry cutting-edge performances at the forefront of the laser technologies, • structure the European landscape of laser Research Infrastructure through enhanced access, extended geographical coverage, novel science diplomacy activities, improved synergies with other European networks and projects, • increase European human resources in the field of laser science by implementing training activities towards researchers from new domains of science and technology and from geographical regions where laser communities are still less developed.