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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.
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.
Funded by the ERC, Prof. Anna Wienhard studies several new geometric forms that have been discovered over the past 20 years. These structures are closely related to the generalisation of Teichmüller space, which describes how the surface of a pretzel can be endowed with the geometry of an Escher painting.
Emulsions play a key role both in natural and industrial processes, as they allow the combination of two liquids that do not normally mix and make the blend stable. Yet, when materials solidify or freeze, the complex interactions that take place and affect the final microstructure of the solidified components, are still poorly understood. ERC grantee Sylvain Deville and his team at CNRS have showed that it is possible to use an optical imaging technique to study the freezing of emulsions while the process takes place, a novel method presented in the prestigious journal Science.
The increase of carbon dioxide (CO2) in the atmosphere as a result of human activity is impacting the natural carbon cycle, modifying how the element travels between land and atmosphere. How will our future climate impact this exchange? How will ever-growing concentrations of greenhouse gases influence future biosphere CO2 fluxes? The answer may lie at our feet; in the soil beneath us.
The Earth is made of layers, just like a big onion, composed of different materials. However, the compounds forming these layers are not static, flowing from one stratum to another, following patterns still not entirely understood. Prof. Patrick Cordier tries to model the real conditions minerals are subjected to beneath the Earth’s crust. His aim is to understand the forces driving tectonic plates so we can better comprehend phenomena like earthquakes and volcanic eruptions.
Through her work with the fruit fly Drosophila santomea, Dr Virginie Orgogozo aims to answer one of the most challenging questions of modern evolutionary biology: how do observable characteristics change between species and yet remain stable in a given species?
Researchers supported by the ERC have sampled magmatic gases derived from the Earth's mantle in the Eifel region in Germany. Their analysis of xenon, a rare and inert gas, sampled in bubbling mineral water could bring new insights into the origin of volatile elements, water and gases, that allowed life to develop on Earth.