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27-11-2019 | © Guenter Albers, Shutterstock 3 mins read

Richer understanding of terrestrial carbon cycles aids more accurate climate change modelling

Quantifying the carbon storage potential of terrestrial ecosystems will have to take account of the relative contributions of photosynthesis and respiration to the global carbon cycle. The SOLCA project developed an ambitious approach to tackle this challenge.

08-03-2018 | © C. Maitre INRA 2 mins read

Bottom up climate change research

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.

15-07-2016 | © picture 2 mins read

Minerals reveal the flow patterns inside the Earth

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.

12-07-2016 | Researcher picture ©Olga NAGY 2 mins read

Evolution of species: different, but not so different

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?

26-04-2016 | Illustration © Eifel forest near the Viktoriaquelle water well. - Photo © Centre de Recherches Petrographiques et Geochimiques 2 mins read

A trace gas analysed in mineral spring water in Germany gives clues on the origins of the Earth

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.

10-11-2015 | Image:©Takashi Ishiuchi & Maria-Elena Torres-Padilla 4 mins read

An international career to push the frontiers of epigenetics

With her degree in biology, Dr Maria-Elena Torres-Padilla left Mexico and embarked on an international career in epigenetics. She completed her PhD at the Pasteur Institute in Paris and then moved to Cambridge University. In 2006 she joined IGBMC in Strasbourg working as a group leader. She has just been appointed Director of the Institute of Epigenetics and Stem Cells of the Helmholtz Zentrum in Munich. Supported by an ERC grant, she studies the mechanisms controlling embryonic cellular plasticity with the aim of shedding new light on today's fertility issues. In this interview she shares her story as a non-European scientist in Europe.

21-03-2014 | Portrait ©Julia Frey | Image ©Alain Anglade / ©shutterstock - Littlesam 5 mins read

A hot topic for mermaids

To study something in detail you need to look at it from all directions, whether it is the Venus de Milo statue in the Louvre Museum, a car you are thinking of buying, or when using a CAT-scanner to image inside the human body. In the ERC-funded GLOBALSEIS project Professor Guust Nolet is doing this on a truly global scale, by developing a worldwide network of marine-based seismic-wave sensors that can give a much better picture of deep-earth structures and resolve a major paradox in geoscience.

27-08-2013 | Cells of coccolithophore genera Gephyrocapsa grown in laboratory culture 3 mins read

Marine algae reveal close link between past climate and CO2

The ocean is filled with microscopic algae that take up carbon dioxide (CO2) from the atmosphere in order to grow. A new study by researchers from the Geology Department at the University of Oviedo (Spain) shows that the algae may adapt to rising levels of atmospheric CO2 much sooner than previously thought, and in an unexpected way. This study, published today in Nature and co-authored by ERC grantee Heather Stoll, also provides evidence for a much closer link between atmospheric CO2 decrease and cooling and glaciations in the geological past.

09-07-2012 | Cells of coccolithophore genera Gephyrocapsa grown in laboratory culture 3 mins read

Tiny fossils can lead to huge gains in understanding

The ocean is filled with microscopic algae that take up carbon dioxide (CO2) from the atmosphere in order to grow. A new study by researchers from the Geology Department at the University of Oviedo (Spain) shows that the algae may adapt to rising levels of atmospheric CO2 much sooner than previously thought, and in an unexpected way. This study, published today in Nature and co-authored by ERC grantee Heather Stoll, also provides evidence for a much closer link between atmospheric CO2 decrease and cooling and glaciations in the geological past.