ERC FUNDED PROJECTS

To satisfy our growing energy demand while reducing reliance on fossil fuels, a switch to renewable energy sources is vital. The intermittent nature of the latter means innovations in energy storage technology is a key grand challenge. Cost and sustainability issues currently limit the widespread use of electrochemical energy storage technologies, such as lithium ion and redox flow batteries. As the scale for energy storage is simply enormous, the only option is to look for abundant materials. However, compounds that fulfil the extensive requirements entailed at low cost has yet to be reported. While it is possible that the holy grail of energy storage will be found, for example by advanced computational tools and machine learning to design “perfect” abundant molecules, a more flexible, innovative solution to sustainable and cost-effective large-scale energy storage is required. Bi3BoostFlowBat will develop game changing strategies to widen the choice of compounds utilizable for batteries to simultaneously satisfy the requirements for low cost, optimal redox potentials, high solubility and stability in all conditions. The aim of this project is to develop cost-efficient batteries by using solid boosters and by eliminating cross over. Two approaches will be pursued for cross-over elimination 1) bio-inspired polymer batteries, where cross-over of solubilized polymers is prevented by size-exclusion membranes and 2) biphasic emulsion flow batteries, where redox species are transferred to oil phase droplets upon charge. Third research direction focuses on systems to maintain a pH gradient, to allow operation of differential pH systems to improve the cell voltages. Limits of different approaches will be explored by taking an electrochemical engineering approach to model the performance of different systems and by validating the models experimentally. This work will chart the route towards the future third generation battery technologies for the large-scale energy storage.

1 499 880 €

Start date: 2021-01-01, End date: 2025-12-31

The demand for donated organs vastly outnumbers the supply, leading each year to the death of thousands of people and the suffering of millions more. Engineered tissues and organs following Tissue Engineering approaches are a possible solution to this problem. However, a prevascularization solution to irrigate complex engineered tissues and assure their survival after transplantation is currently elusive. In the human body, complex organs and tissues irrigation is achieved by a network of blood vessels termed capillary bed which suggests such a structure is needed in engineered tissues. Previous approaches to engineer capillary beds reached different levels of success but none yielded a fully functional one due to the inability in simultaneously addressing key elements such as correct angiogenic cell populations, a suitable matrix and dynamic conditions that mimic blood flow. CapBed aims at proposing a new technology to fabricate in vitro capillary beds that include a vascular axis that can be anastomosed with a patient circulation. Such capillary beds could be used as prime tools to prevascularize in vitro engineered tissues and provide fast perfusion of those after transplantation to a patient. Cutting edge techniques will be for the first time integrated in a disruptive approach to address the requirements listed above. Angiogenic cell sheets of human Adipose-derived Stromal Vascular fraction cells will provide the cell populations that integrate the capillaries and manage its intricate formation, as well as the collagen required to build the matrix that will hold the capillary beds. Innovative fabrication technologies such as 3D printing and laser photoablation will be used for the fabrication of the micropatterned matrix that will allow fluid flow through microfluidics. The resulting functional capillary beds can be used with virtually every tissue engineering strategy rendering the proposed strategy with massive economical, scientific and medical potential

1 499 940 €

Start date: 2018-11-01, End date: 2024-04-30

The central research theme of this proposal is the study of social change (skills, productivity, attitudes and beliefs) in Europe along cohort lines and as a function of changing age composition. Using demographic methods, age-specific and cohort-specific changes shall be quantitatively disentangled. The impact of migration flows as well as fertility differentials combined with intergenerational transmissions will be taken into account. It is expected that viewed together, these analyses will result in significant new insights and represent frontier research about likely social and economic challenges associated with ageing and demographic change in Europe and the appropriate policies for coping with them. Unlike projections of long-term economic growth or energy use, demographic forecasts tend to have comparatively low margins of error, even for forecasts half a century ahead. Traits that change systematically along age or cohort lines may therefore be projected with some degree of accuracy, which in turn can allow governments and individuals to better foresee and improve policies for predictable social change. The study will investigate two major topics, the first relating to human capital, skills, and work performance; the second relating to beliefs and attitudes in Europe. Understanding age variation in productivity and how to improve senior workers skills and capacities are paramount for ageing countries. Moreover, individual-level demographic behaviour can have aggregate level implications, including changing societal values and belief structures. The binding element is how such projections will improve one s capacity to foresee and hence develop more targeted policies that relate to ageing societies.

981 415 €

Start date: 2009-10-01, End date: 2015-03-31

The chronology of ancient Egypt is a golden thread for the memory of early civilisation. It is not only the scaffolding of four millennia of Egyptian history, but also one of the pillars of the chronology of the entire ancient Near East and eastern Mediterranean. The basic division of Egyptian history into 31 dynasties was introduced by Manetho, an Egyptian historian (c. 280 BC) writing in Greek for the Ptolemaic kings. Despite the fact that this scheme was adopted by Egyptologists 200 years ago and remains in use until today, there has never been an in-depth analysis of Manetho’s kinglist and of the names in it. Until now, identifying the Greek renderings of royal names with their hieroglyphic counterparts was more or less educated guesswork. It is thus essential to introduce the principles of textual criticism, to evaluate royal names on a firm linguistic basis and to provide for the first time ever an Egyptological commentary on Manetho’s kinglist. Just like Manetho did long ago, now it is necessary to gather all inscriptional evidence on Egyptian history: dated inscriptions, biographic and prosopographic data of royalty and commoners, genuine Egyptian kinglists and annals. These data must be critically evaluated in context, their assignment to specific reigns must be reconsidered, and genealogies and sequences of officials must be reviewed. The results are not only important for Egyptian historical chronology and for our understanding of the Egyptian perception of history, but also for the interpretation of chronological data gained from archaeological excavations (material culture) and sciences (14C dates, which are interpreted on the basis of historical chronology, e.g., via ‘Bayesian modelling’). The applicant has already shown the significance of this approach in pilot studies on the pyramid age. Further work in cooperation with international specialists will thus shed new light on ancient sources in order to determine the chronology of early civilisation.

1 499 992 €

Start date: 2018-03-01, End date: 2023-02-28