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The deep seafloor covers around 70% of our planet’s surface and is home to a diverse community of microorganisms, mostly bacteria. These single-cell life forms inhabit some of the most extreme places in the world, with freezing waters, permanent darkness, high pressure and little food. ERC grantee Antje Boetius studies these microbes in the abyss and their important role for the Earth’s nutrient cycles.
How do proteins trigger complex signal processing tasks, such as neurotransmission, in cells? Thanks to the development of innovative molecular simulation techniques, this ERC-funded project has brought new insights into the transmission of messages inside and between cells.
Catalysts are essential for a lot of chemical production processes, accelerating and enhancing chemical reactions to produce plastics, medicines and fuels more efficiently. Now, thanks to EU-funded research, catalysts are being made more precise and effective with potentially significant benefits for industry and the environment, not least through the development of ultra-clean fuels.
Prof. Ian Thomas Baldwin received an ERC Advanced Grant to study the internal circadian clock of plants. In particular, he wants to understand the ecological consequences of plants fallings ‘out of synch’. In this interview, Prof. Baldwin shares some of his research findings and explains why he has chosen to make his study results openly available.
How can we explain the continuity of Chinese empires? Dr Hilde De Weerdt with her project "Chinese Empire" revisits this big question in world history.
When Prof. Heino Falcke obtained an ERC grant to study and identify the sources of ultra-high energy cosmic rays, back in 2008, he could not imagine that his research would provide an important clue to better understand lightning and thunderclouds much closer to us. His team indeed realized that cosmic rays, originating in outer space and striking the Earth from all directions, can provide a near instantaneous 'picture' of the electric fields in clouds. The unexpected finding, to be published this week in Physical Review Letters, is the result of a fruitful collaboration between astronomers, particle physicists and geophysicists. The measurements were performed with the LOFAR radio telescope, located in the Netherlands, and partly funded by the ERC.
An international research team led by astronomers from the Max Planck Institute for Radio Astronomy (MPIfR, Bonn, Germany) used a collection of large radio and optical telescopes to investigate a newly discovered pulsar, and its white dwarf companion. The observations revealed a system with unusual properties, which weighs twice as much as the Sun, making it the most massive neutron star to date. These findings partly result from the “BEACON” project led by ERC Starting grantee Dr Paulo Freire, and agree with Einstein’s theory on general relativity. They will be published in tomorrow’s issue of Science, April 26, 2013.