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Very High Frequency Radiation makes Dark Matter Visible December 14th, 2006 Original work: R. Benton Metcalf & S.D.M. White: High-resolution.

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Presentation on theme: "Very High Frequency Radiation makes Dark Matter Visible December 14th, 2006 Original work: R. Benton Metcalf & S.D.M. White: High-resolution."— Presentation transcript:

1 Very High Frequency Radiation makes Dark Matter Visible December 14th, 2006 http://www.mpg.de Original work: R. Benton Metcalf & S.D.M. White: High-resolution imaging of the cosmic mass distribution from gravitational lensing of pregalactic HI

2 Einstein's Theory of Gravity  As light travels to us from distant objects its path is bent slightly by the gravitational effects of the things it passes.  The bending causes a detectable distortion of the images of distant galaxies.  The strength of the distortion can be used to measure the strength of the gravity of the foreground objects and hence their mass.

3 Limitations of Telescopes  Even a big telescope in space can only see a limited number of background galaxies, and only about 200 galaxies is heavy enough to detect the image distortion in each patch of sky the size of the Full Moon.  Many of the distant galaxies whose distortion is measured lie in front of many of the mass lumps which one would like to map, and so are unaffected by their gravity.

4 New Sources  MPA scientists Ben Metcalf and Simon White have shown that radio emission coming to us from the epoch before the galaxies had formed can provide such sources.

5 Fig. 1: Image of the mass distribution over a patch of sky about one quarter of the area of the Full Moon. These images were made by PhD student Stefan Hilbert using the Millennium Simulation, the largest computer simulation of cosmic structure formation ever carried out. The left panel represents the kind of image which could be made by a low frequency radio telescope with a diameter of 100 kilometres, using the gravitational distortion of images of pregalactic structure in the neutral hydrogen distribution. The right panel represents the kind of image which could be made for the same region of the sky using an optical telescope in space to measure the gravitational distortion of distant galaxy images (The contrast of the second image is three times that of the first to make small features stand out.). Image: Max Planck Institute for Astrophysics

6 Fig. 1: The processes in the Universe after the Big Bang. The radio waves are much older than the light of galaxies. From the distortion of the images (curved lines) - caused by the gravitation of material between us and the light sources - it is possible to calculate and map the entire foreground mass.

7 The Neutral Hydrogen  About 400,000 years after the Big Bang, the Universe had cooled off sufficiently that almost all its ordinary matter turned into a diffuse, near-uniform and neutral gas of hydrogen and helium.  A few hundred million years later, the first stars and galaxies formed, and started to radiate ultraviolet light, which reheated the diffuse gas.  The 21cm emission/absorbsion line of the neutral hydrogen.

8 Conclusion  Metcalf and White show that gravitational distortion of pregalactic hydrogen would allow a radio telescope to produce high resolution images of the cosmic mass distribution which are more than ten times sharper than the best that can be made using galaxy distortions.  Metcalf and White also show that mass maps of a large fraction of the sky made with an instrument like SKA (Square Kilometre Array) could measure the properties of Dark Energy more precisely than any previously suggested method, more than 10 times as accurately as mass maps of similar size based on gravitational distortions of the optical images of galaxies.

9 THANK YOU VERY MUCH!!

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