DARKMATTERDARKENERGY

Understanding the Dark Universe with 3D Weak Gravitational Lensing

 Coordinatore UNIVERSITY OF DURHAM 

 Organization address address: STOCKTON ROAD THE PALATINE CENTRE
city: DURHAM
postcode: DH1 3LE

contact info
Titolo: Ms.
Nome: Wendy
Cognome: Harle
Email: send email
Telefono: +44 191 33 49303

 Nazionalità Coordinatore United Kingdom [UK]
 Totale costo 100˙000 €
 EC contributo 100˙000 €
 Programma FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013)
 Code Call FP7-PEOPLE-2007-4-3-IRG
 Funding Scheme MC-IRG
 Anno di inizio 2008
 Periodo (anno-mese-giorno) 2008-09-20   -   2014-01-27

 Partecipanti

# participant  country  role  EC contrib. [€] 
1    UNIVERSITY OF DURHAM

 Organization address address: STOCKTON ROAD THE PALATINE CENTRE
city: DURHAM
postcode: DH1 3LE

contact info
Titolo: Ms.
Nome: Wendy
Cognome: Harle
Email: send email
Telefono: +44 191 33 49303

UK (DURHAM) coordinator 0.00
2    THE UNIVERSITY OF EDINBURGH

 Organization address address: OLD COLLEGE, SOUTH BRIDGE
city: EDINBURGH
postcode: EH8 9YL

contact info
Titolo: Ms.
Nome: Angela
Cognome: Noble
Email: send email
Telefono: +44 131 650 9024
Fax: +44 131 650 9023

UK (EDINBURGH) participant 0.00

Mappa


 Word cloud

Esplora la "nuvola delle parole (Word Cloud) per avere un'idea di massima del progetto.

clusters    helping    telescope    scientists    particles    dune    universe    background    lensing    dark       invisible    space    esa    gravitational    observations    energy    scientific    collisions    observatory    darkmatterdarkenergy    hubble    techniques    substance    ray    almost    galaxies    data    galaxy    force    ground    mass    surveys    light   

 Obiettivo del progetto (Objective)

'Understanding the twin cosmological puzzles of dark matter and dark energy remains the most fundamental challenge in modern cosmology. Almost the entire contents of the universe consist of dark matter or dark energy, but they are invisible and almost nothing is known about them. They are most effectively probed via the gravitational deflection of light from distant galaxies, a process known as 'gravitational lensing'. This is a purely geometrical effect, which is uniquely clean of astrophysical assumptions. Several dedicated gravitational lensing experiements have recently begun throughout Europe, to exploit rapid developments in telescope technology on the ground and in space. These include the VST/KIDS and Pan-Starrs surveys, as well as ESA's proposed DUNE satellite. However, measurements of gravitational lensing require the extraction of a very subtle signal, and the exploitation of such data has reached a systematic floor due to limitations in data analysis techniques. A great deal of preparation is urgently needed before the scientific potential of these funded surveys can be fully exploited. My recent work in America generated the largest ever survey from the Hubble Space Telescope. Through that experience, I have built a unique toolset that can help tap Europe's new data. I have also been deeply involved in the development of proposed American satellites SNAP and GRALE, which have very similar goals to DUNE. As a member of scientific teams on both sides of the Atlantic, I will be able to foster closer links between these complementary efforts, as well as helping to advance the project in Europe. I plan to be based at the university of Edinburgh, a centre of excellence for gravitational lensing observations, and the only institute that is a member of all three major projects. With this timely confluence of new data and analysis techniques, I would expect to make a major contribution to Europe's leadership in understanding the dark universe.'

Introduzione (Teaser)

Collisions between massive galaxy clusters are helping European scientists to explain two of the greatest mysteries in our Universe, dark matter and dark energy.

Descrizione progetto (Article)

Dark matter is an invisible substance thought to make up 27 % of all matter in our Universe. The strength of its gravitational pull keeps galaxies from separating at the speed at which they whirl. Dark energy, on the other hand, is pushing the Universe apart, increasing the rate with which the cosmos expands. Scientists believe that dark energy could make up about 70 % of the Universe while known particles make up just 5 %.

What dark matter and dark energy actually has remained a mystery until today, despite many potential explanations suggested for both. Scientists working on the EU-funded 'Understanding the dark universe with 3D weak gravitational lensing' (DARKMATTERDARKENERGY) project have used the most successful technique yet developed to investigate this dark sector: gravitational lensing.

Dark matter does not interact with electromagnetic force operating between charged particles and therefore, does not emit or reflect light. However, it seems to play the most important role in shaping the Universe on large scales, interacting with the force of gravity. The curvature of time-space near gravitating mass, including dark matter, deflects passing rays of light, thereby distorting the images of background galaxies.

Measurements of the distribution of dark matter seen by gravitational lensing in 65 galaxy clusters were compared with the distribution of gas determined from X-ray emission and scattering of photons from the cosmic microwave background. This comparison led to unexpected findings, such as the luminosity-temperature relationship remaining constant for the past 5 million years in the clusters of varying mass.

Even more puzzling were the findings from the analysis of collision between galaxy clusters. In observations from the Hubble Space Telescope, the Chadra X-ray Observatory in space and the ESO Very Large Observatory on the ground, the DARKMATTERDARKENERGY team found four collisions. Together with the 'Bullet cluster' discovered in 2006, these collisions between galaxy clusters have provided some evidence that dark matter interacts with ordinary matter.

If these results are correct and dark matter interactions are more common than expected, that would confirm the existence of dark matter and dark energy. More importantly, they would provide a more accurate estimate of how much of this mysterious substance exists. For this purpose, scientists extended the work of the DARKMATTERDARKENERGY after its completion with new experiments such as ESA's Euclid telescope.

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