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The increasing development of wearable technology sparks the need for new, innovative ways to interact with our shiny gadgets. Deviating from the conventional approach based on touch-sensitive devices, Prof. Jürgen Steimle aims at producing body-worn user interfaces that can be applied directly on the skin. Highly personalised, biocompatible and ultrathin, these devices will seamlessly blend with the human skin to create a technological extension of our body.
One of the biggest drawbacks of electric vehicles – that they require hours and hours to charge – could be obliterated by a new type of liquid battery that is roughly ten times more energy-dense than existing models, according to Professor Lee Cronin, the Regius Chair of Chemistry at the University of Glasgow, UK.
ERC grantee Dr Kazuya Koyama, originally from Japan, tests gravity, specifically whether Albert Einstein’s general theory of relativity can be applied beyond our solar system. At present general relativity works in our galaxy but is less convincing at the far borders of our universe which is rapidly expanding and needs weird energy to explain this. Dr Koyama is hoping that observations in deep space will show that the theory can be modified to work on a larger scale so that this strange 'dark energy' is not needed – removing one of cosmology's biggest mysteries.
On the occasion of the signing of a new agreement with the Japanese Science and Technology Agency to encourage top Japanese researchers to temporarily join ERC-funded teams in Europe, the ERC interviewed Dr Kazuya Koyama about his international career and how he believes this helps strengthen scientific partnerships between researchers in Europe and Japan.
Will spacecraft follow a similar evolution to computers? While information processing in the last century was performed by large mainframe computers, today, networked smart phones dominate the market. In spacecraft engineering a similar paradigm shift is apparent: from traditional single, large, and multifunctional satellites towards groups of very small satellites that cooperate together. Professor Klaus Schilling, in his ERC project “NetSat”, addresses crucial challenges to enable small satellite formations to self-organise. This offers innovative application perspectives in areas like Earth observation, science exploration or telecommunications.
The amount of currently available biomedical data is overwhelming. Large databases exist at different scales, from genes, to proteins, to patients' histories. But what do scientists do with all this information? Serbian-born Professor Nataša Pržulj, from University College London, works with Big Data to establish patterns and gain knowledge that could revolutionise how we treat diseases.
Water is a peculiar liquid. In fact, it's thanks to some of its peculiarities that our "blue" planet looks the way it does, and that life has evolved most of the characteristics we recognise today. ERC grantee Prof. Anders Nilsson has made his career out of studying water, in particular trying to understand the secret double life water leads at extremely cold temperatures.
Group theory, functional analysis and ergodic theory – three distinct areas of mathematics that meet within the theory of von Neumann algebras. The RIGIDITY project, funded by the ERC, aims to classify families of von Neumann algebras.
Understanding complex structures means separating irrelevant information to get to something simpler and easier to understand. When you look at something from a distance – although you don’t see all the details, you can still describe what you see. ERC grantee Balázs Szegedy has developed several mathematical tools for providing a compressed yet useful view of complex structures.
How does one infer the dynamics of a DNA minicircle in solution? How does one align the neuronal firing patterns of several neurons across individuals? These questions are intrinsically statistical, but nevertheless escape the traditional tools of statistics. The ComplexData project investigated such questions from a mathematical and an applied context.
Once limited to modelling physical problems in engineering, today Partial Differential Equations (PDEs) are used by a diverse array of fields, from natural resources to meteorology, aeronautics, oil and gas and biomedicine – to name only a few. But key mathematical issues remain unsolved, particularly when addressing their control, a must in technological transfer. The ERC-funded DYCON project aims to find answers.