{"id":8077,"date":"2016-03-20T07:58:49","date_gmt":"2016-03-20T07:58:49","guid":{"rendered":"http:\/\/revoscience.com\/en\/?p=8077"},"modified":"2016-03-20T07:58:49","modified_gmt":"2016-03-20T07:58:49","slug":"discovery-of-potential-gravitational-lenses-shows-citizen-science-value","status":"publish","type":"post","link":"https:\/\/www.revoscience.com\/en\/discovery-of-potential-gravitational-lenses-shows-citizen-science-value\/","title":{"rendered":"Discovery of potential gravitational lenses shows citizen science value"},"content":{"rendered":"

Citizen scientists have helped an international team of researchers to discover 29 new gravitational lens candidates in galaxies far away.<\/strong><\/em><\/p>\n

\n

\"How<\/a>
How one galaxy\u2019s image appears distorted due to another galaxy (source: Kavli IPMU)<\/figcaption><\/figure>\n

Around 37,000 citizen scientists combed through 430,000 images to help an international team of researchers to discover 29 new gravitational lens candidates through Space Warps, an online classification system which guides citizen scientists to become lens hunters.<\/span>

Gravitational lens systems are massive galaxies that act like special lenses through their gravity, bending the light coming from a distant galaxy in the background and distorting its image. Dark matter around these massive galaxies also contributes to this lensing effect, and so studying these gravitational lenses gives scientists a way to study this exotic matter that emits no light.<\/span>

<\/p>\n

[pullquote]\u201cComputer algorithms have been somewhat successful in identifying gravitational lenses, but they can miss lensed images that appear similar to other features commonly found in galaxies”.[\/pullquote]<\/p>\n

Since gravitational lenses are rare, only about 500 of them have been discovered to date, and the universe is enormous, it made sense for researchers to call on an extra pair of eyes to help scour through the mountain of images taken from the Canada-France-Hawaii Telescope Legacy Survey (CFHTLS). Details of the discoveries will be published in Monthly Notices of the Royal Astronomical Society.<\/span>

\u201cComputer algorithms have been somewhat successful in identifying gravitational lenses, but they can miss lensed images that appear similar to other features commonly found in galaxies, for example the blue spiral arms of a spiral galaxy,\u201d said Anupreeta More, co-principal investigator of Space Warps and project researcher at the University of Tokyo\u2019s Kavli Institute for the Physics and Mathematics of the Universe.<\/span>

\u201cAll that was needed was the ability to recognise patterns of shapes and colours,\u201d said citizen scientist and paper co-author Christine Macmillan from Scotland. \u201cIt was fascinating to look at galaxies so far away, and realize that there is another behind it, even further away, whose light gets distorted in an arc.\u201d<\/span>

<\/p>\n

\"29<\/a>
29 gravitational lens candidates found through Space Warps (credit: Space Warps, Canada-France-Hawaii Telescope Legacy Survey)<\/figcaption><\/figure>\n

Not only did this project give the public a chance to make scientific discoveries, it also gave them a chance to develop as researchers themselves. \u201cI benefited from this project with an increase of my knowledge and some experience on making models of lenses,\u201d said citizen scientist and paper co-author Claude Cornen from France.<\/span>

More, and two other collaborators, Phil Marshall at the Kavli Institute for Particle Astrophysics and Cosmology, Stanford University, and Aprajita Verma at the Department of Physics, University of Oxford, are co-principal investigators of Space Warps, which taps into the unique strength of humans in analysing visual information essential for finding gravitational lenses.<\/span>

The team will now move onto studying some of the interesting gravitational lens candidates by observing them with telescopes to uncover some of the mysteries related to dark matter. They are keen to work together with more volunteers in the near future as they are preparing new images from other ongoing imaging surveys to discover many more lenses.<\/span><\/p>\n","protected":false},"excerpt":{"rendered":"

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