REMINDER aims to develop an embedded DRAM solution optimized for ultra-low-power consumption and variability immunity, specifically focused on Internet of Things cut-edge devices. The objectives of REMINDER are : i) Investigation (concept, design, characterization, simulation, modelling), selection and optimization of a Floating-Body memory bit cell in terms of low power and low voltage, high reliability, robustness (variability), speed, reduced footprint and cost. ii) Design and fabrication in FDSOI 28nm (FD28) and FDSOI 14nm (FD14) technology nodes of a memory matrix based on the optimized bit-cells developed. Matrix memory subcircuits, blocks and architectures will be carefully analysed from the power-consumption point of view. In addition variability tolerant design techniques underpinned by variability analysis and statistical simulation technology will be considered. iii) Demonstration of a system on chip application using the developed memory solution and benchmarking with alternative embedded memory blocks. The eventual replacement of Si by strained Si/SiGe and III-V materials in future CMOS circuits would also require the redesign of different applications, including memory cells, and therefore we also propose the evaluation of the optimized bit cells developed in FD28 and FD14 technology nodes using these alternative materials. The fulfilment of the objectives above will also imply the development of: i) New techniques for the electrical characterization of ultimate CMOS nanometric devices. This will allow us to improve the CMOS technology by boosting device performance. ii) New behavioural models, incorporating variability effects, to reach a deep understanding of nanoelectronics devices iii) Advanced simulation tools for nanoelectronic devices for state of the art, and emerging devices. iv) Extreme low power solutions The consortium supporting this proposal is ideally balanced with 2 industrial partners, 2 SMEs, 2 research centers and 3 universities.

Green hydrogen is one of the most promising solutions for the decarbonisation of society. Alkaline water electrolysis (AWE) is already a mature technology but its large footprint makes it inadequate for producing the energy vector at GW scale. Proton exchange membrane water electrolysis (PEMWE) on the other hand is compact but its dependence on iridium and other expensive materials poses a serious threat for up-scaling. Anion exchange membrane water electrolysis (AEMWE) combines the benefits of both technologies. However, its key performance indicators (KPI) do not reach commercial requirements and are lacking competitiveness. NEWELY project aims to redefine AEMWE, surpassing the current state of AWE and bringing it one step closer to PEMWE in terms of efficiency but at lower cost. The three main technical challenges of AEMWE: membrane, electrodes and stack are addressed by 3 small-medium-enterprises (SME) with their successful markets related to each of these topics. They are supported by a group of 7 renowned R&D centres with high expertise in polymer chemistry and low temperature electrolysis. The SMEs and one of the largest hydrogen companies in the world will oversee that the new developments have a clear commercial perspective, placing Europe at the lead of AEMWE technology in three years. In this period , the NEWELY consortium will develop a prototypic 5-cell stack with elevated hydrogen output pressure. It will contain highly conductive and stable anionic membranes as well as efficient and durable low-cost electrodes. It will reach twice the performance of the state of the art of AEMWE operating with pure water feedstock only. The targeted performance of the NEWELY prototype will be validated in a 2,000 hours endurance test. The new AEMWE stack will lead to a significant cost reduction of water electrolysis having a relevant impact in the cost of green hydrogen.

Pathogens are a determining factor in emergency response due to their life-threatening nature, both for the public as well as for the safety of first responders. In many cases, pathogen contaminations are difficult to detect, and require specialized technologies, tools and procedures to handle them. Pathogens can easily spread via water, and may cause contaminations of large areas far from their origin. Waterborne pathogen contamination events can occur anywhere, and may be caused by various natural events or they can be the result of human activity, either accidental or malicious. During these emergencies, first responders may need to operate within a certain pre-defined incident area, and are likely to be exposed to contaminated water originating from various sources, such as surface water, wastewater or drinking water. This can pose a significant risk of illness, disease or even death, through skin contact, ingestion or inhalation. The overall objective of the PathoCERT project is to strengthen the coordination capability of the first responders in handling waterborne pathogen contamination events. This will increase the first responders’ capabilities, allowing the rapid and accurate detection of pathogens, improving their situational awareness, and improving their ability to control and mitigate emergency situations involving waterborne pathogens. To achieve this objective, the project will research and demonstrate Pathogen Contamination Emergency Response Technologies (PathoCERT), a collection of novel, cost-effective and easy-to-use technologies, tools and guidelines, which will be field-validated by the first responders.