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European Synchrotron Radiation Facility

Coordinates: 45°12′31″N 5°41′24″E / 45.20861°N 5.69000°E / 45.20861; 5.69000
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European Synchrotron
Radiation Facility
Installation européenne
de rayonnement synchrotron
FormationSeptember 30, 1994; 30 years ago (1994-09-30)
HeadquartersGrenoble, France
Official languages
English
LeaderFrancesco Sette
Websitewww.esrf.fr
ESRF-EBS
General properties
Accelerator typeSynchrotron
Beam typeElectron
Target typeLight source
Beam properties
Maximum energy6 GeV
Maximum brightness3.56×1021 ph./s/0.1%/mm2/mrad2
Physical properties
Circumference843.977 metres (2,768.95 ft)
LocationGrenoble, France
Coordinates45°12′31″N 5°41′24″E / 45.20861°N 5.69000°E / 45.20861; 5.69000
InstitutionESRF
Dates of operation2020 - present

The European Synchrotron Radiation Facility (ESRF) is a joint research facility situated in Grenoble, France, supported by 22 countries (13 member countries: Belgium, Denmark, Finland, France, Germany, Italy, the Netherlands, Norway, Russia, Spain, Sweden, Switzerland, and the UK; and 9 associate countries: Austria, the Czech Republic, Hungary, India, Israel, Poland, Portugal, Slovakia, and South Africa).[1]

Some 8,000 scientists visit this particle accelerator each year, conducting upwards of 2,000 experiments and producing around 1,800 scientific publications.[2]

History

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Inaugurated in September 1994, it has an annual budget of around 100 million euros,[3] employs over 630 people and is host to more than 7,000 visiting scientists each year.

In 2009, the ESRF began a first major improvement in its capacities. With the creation of the new ultra-stable experimental hall of 8,000 m2 in 2015, its X-rays are 100 times more powerful, with a power of 100 billion times that of hospital radiography devices.[4]

The second improvement to the facilities, now named the "Extremely Brilliant Source" (ESRF-EBS), took place between 2018 and 2020. and again improved its X-ray power by a factor of 100,[5] or 10,000 billion more powerful than X-rays used in the medical field. It became the first fourth-generation high-energy synchrotron in the world.[6]

The first electron beam tests began on November 28, 2019.[7] The facility reopened to users on August 25, 2020.[8]

General description

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Top view of the ring

The ESRF physical plant consists of two main buildings: the experiment hall, containing the 844 metre circumference ring and forty tangential beamlines; and a block of laboratories, preparation suites, and offices connected to the ring by a pedestrian bridge. The linear accelerator electron gun and smaller booster ring used to bring the beam to an operating energy of 6 GeV are constructed within the main ring. Until recently bicycles were provided for use indoors in the ring's circumferential corridor. Unfortunately they have been removed after some minor accidents. But even before this it was not possible to cycle continuously all the way around, since some of the beamlines exit the hall.

Research at the ESRF focuses, in large part, on the use of X-ray radiation in fields as diverse as protein crystallography, earth science, paleontology, materials science, chemistry and physics. Facilities such as the ESRF offer a flux, energy range and resolution unachievable with conventional (laboratory) radiation sources.

Study results

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In 2014, ancient books destroyed by the eruption of Mount Vesuvius in 79 were read for the first time in the ESRF. These 1840[clarification needed] fragments were reduced to the status of charred cylinders.[9][10]

In 2015, scientists from the University of Sheffield used the ESRF's X-rays to study the blue and white feathers of the jay, and found that the birds use well-controlled changes to the nanostructure of their feathers to create the vivid colours of their plumage. This research opened new possibilities for creating non-fading, synthetic colours for paints and clothing.[11]

In July 2016, a team of South African researchers scanned a complete fossilized skeleton of a small dinosaur discovered in 2005 in South Africa and more than 200 million years old. The dentition of heterodontosauridae, when scanned, revealed palate bones less than a millimeter thick.[12][13]

On December 6, 2017, the journal Nature unveiled the discovery at the European synchrotron of a new species of dinosaur with surprising characteristics that lived about 72 million years ago. It is a biped, with some features of a velociraptor, an ostrich and a swan, with a crocodile-like muzzle and penguin-like wings. With a height of about 1.2 meters (4 ft) and with killer claws, it could hunt his prey on the ground or by swimming in the water, which is a novelty for scientists in the study of dinosaurs.[14]

In November 2021, researchers demonstrated a novel X-ray imaging technique, "HiP-CT", for 3D cellular-resolution scans of whole organs, using the ESRF's "Extremely Brilliant Source". The published online Human Organ Atlas includes the lungs from a donor who died with COVID-19.[15][16][17]

In October 2024, First Light Fusion, in collaboration with the University of Oxford's Department of Engineering Science, performed an experiment on inertial fusion on the ID19 beamline to investigate the formation and transit of shock waves through some of First Light Fusion’s amplifiers.[18]

Access

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The ESRF site forms part of the "Polygone Scientifique", lying at the confluence of the rivers Drac and Isère about 1.5 km from the centre of Grenoble. It is served by Grenoble tramway system and local bus lines of Semitag (C6, 22 and 54). It is served by Grenoble–Isère Airport and Lyon–Saint-Exupéry Airport.

The ESRF shares its site with several other institutions including the Institut Laue-Langevin (ILL), the European Molecular Biology Laboratory (EMBL) and the Institut de biologie structurale [fr]. The Centre national de la recherche scientifique (CNRS) has an institute across the road.

People

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See also

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References

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  1. ^ "Members and associates". ESRF.
  2. ^ nature.com 29 March 2016, 24 hours at the X-ray factory.
  3. ^ "Facts and figures". ESRF.
  4. ^ dpaonthenet.net, World's brightest X-ray source shuts down for next-gen 100x more powerful.
  5. ^ (in French) france3-regions.francetvinfo.fr, Grenoble : le premier faisceau de rayons X observé dans le synchrotron nouvelle génération.
  6. ^ ESRF-EBS, The first high-energy fourth-generation synchrotron.
  7. ^ White, Simon; Carmignani, Nicola; Carver, Lee; Chavanne, Joel; Farvacque, Laurent; Hardy, Laurent; Jacob, Jörn; Le Bec, Gaël; Liuzzo, Simone; Perron, Thomas; Qin, Qing; Raimondi, Pantaleo; Revol, Jean-Luc; Scheidt, Kees (2021). "Commissioning and Restart of ESRF-EBS". Proceedings of the 12th International Particle Accelerator Conference. IPAC2021. doi:10.18429/JACoW-IPAC2021-MOXA01.
  8. ^ ESRF-EBS opens to users
  9. ^ "Ancient books destroyed by the eruption of Mount Vesuvius 'read' for the very first time".
  10. ^ "Des papyrus antiques carbonisés déchiffrés à la lumière des rayons X". Le Monde (in French). 2015-01-20.
  11. ^ "Nature's unique way of controlling colour explains why birds never go grey". sheffield.ac.uk. 21 December 2015.
  12. ^ htxt.co.za Tiny Karoo fossil scanned by world’s largest X-ray machine.
  13. ^ bbc.com Paul Rincon, X-rays reveal complete dino skeleton.
  14. ^ www.eurekalert.org, Synchrotron sheds light on the amphibious lifestyle of a new raptorial dinosaur.
  15. ^ "From whole-organ to cellular resolution: synchrotron X-ray images reveal COVID-19 lung damage". Physics World. 16 November 2021. Retrieved 11 December 2021.
  16. ^ "Brightest ever X-ray shows lung vessels altered by COVID-19". University College London. Retrieved 11 December 2021.
  17. ^ Walsh, C. L.; Tafforeau, P.; Wagner, W. L.; Jafree, D. J.; Bellier, A.; Werlein, C.; Kühnel, M. P.; Boller, E.; Walker-Samuel, S.; Robertus, J. L.; Long, D. A.; Jacob, J.; Marussi, S.; Brown, E.; Holroyd, N.; Jonigk, D. D.; Ackermann, M.; Lee, P. D. (December 2021). "Imaging intact human organs with local resolution of cellular structures using hierarchical phase-contrast tomography". Nature Methods. 18 (12): 1532–1541. doi:10.1038/s41592-021-01317-x. ISSN 1548-7105. PMC 8648561. PMID 34737453.
  18. ^ "Europe overtakes the USA and takes a giant step towards nuclear fusion thanks to the world's largest synchrotron in Grenoble - The Vanguard". Retrieved 2024-10-12.
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