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A Short Talk on… Gravitational Lensing Presented by: Anthony L, James J, and Vince V. What is Gravitational lensing? ● ● ● A process where light is bent due to gravity of a massive body. Results in multiple images of the source created. Massive bodies such as galaxy clusters and blackholes serves as a gravitational lens. Origin of Gravitational Lensing ● First predicted by Albert Einstein in 1905 when he was working on his theory of General Relativity. • Einstein’s predictions were confirmed by Sir Arthur Eddington in 1919 through his observations of the solar eclipse in Principe, Africa. Eddington’s Experiment The Deflection Angle ● ● One notion to keep in mind is that we will be deriving the deflection angle in the Schwarzschild exterior vacuum space-time. In the Schwarzschild space-time the deflection angle is given by the expression 4GM 2 c ● ● This is just twice the expression that Newton’s theory of gravity predicts, RS provided that For a three-dimensional mass distribution with a volume density r , the deflection angle becomes 4G 2 ' 2 d ' ' 2 c ' The Lens Equation ● Since RS , 1 . Thus by imposing the small angle approximation we can find an expression for the true position of a source as Dds Dd Ds The Lens Equation Con’t ● The scaled deflection angle in terms of the mass density is ● ● where ' 1 Dd cr d ' ' 2 2 with ' ' 2 Ds c2 cr 4 G Dd Dds For the case where cr , the mass distribution will produce several images. Thus cr is the dividing line between ‘weak’ and ‘strong’ gravitational lenses. Strong Gravitational Lensing ● ● Strong gravitational lensing is an effect that is strong enough to produce multiple images, arcs, or even Einstein rings. Almost always, there are an odd number of images formed. Weak Gravitational lensing ● ● ● In most cases the lens is not strong enough to form multiple images or arcs. The background galaxies, however, are still distorted They are stretched and magnified, but by such small amounts that it is difficult to measure. Gravitational Microlensing ● ● Microlensing occurs when a massive foreground object passes between the observer and the source being observed. The Einstein angle is angular radius of the Einstein ring in the event of perfect alignment given by 4GM d S d L E c2 dS d L ● During a microlensing event, the brightness of the source is amplified by an amplification factor A, given by A u ● u2 2 u u2 4 In practice, source size effects set a limit to how large an amplification can occur for a very close alignment. Applications of Gravitational Lensing Expanding the range of our observations Data on older and more distant galaxy populations provides tests for models of galactic evolution “Weighing” galaxies and galaxy clusters, mapping mass distribution (including dark matter) Measuring constants such as H0 Searching for dark matter in the Milky Way (particularly in the halo, and towards the galactic bulge) Planet hunting Strong and Weak Lensing Determining the degree by which light from the source is deflected allows calculation of the lens mass The shape and distribution of the images produced by the lensing effect reveal the distribution of mass within the lensing object Different images of the same source object represent light which has taken different paths from the source to us; different paths means different transit time Time delay between various images is proportional to Hubble's constant, the shape of the lens, and the relative distances between us, the lens and the source Thus Hubble's constant can be estimated based on the lensing effect Mapping dark matter Large-scale maps of dark matter distribution can be derived from analysis of weak lensing effects over large areas of sky <== Map derived from COSMOS survey Also useful on smaller scales, for studying individual galaxy clusters Bullet Cluster Optical image from HST Chandra X-ray image showing distribution of hot intergalactic gas (probably most of the cluster's baryonic mass) Tomographic map of overall mass distribution, based on weak lensing studies Microlensing Surveys of microlensing events within the Milky Way search for dark matter in the form of Massively Compact Halo Objects MACHOs are “normal” baryonic matter such as brown dwarfs Based on surveys to date, only a small percentage (<20%) of halo dark matter can be attributed to MACHOs Surveys also conducted towards the galactic bulge – one remarkable image at left is a reconstructed image of MOA 2002-BLG-33, a highly microlensed source star, accurate to within 4 x 10-8 arcsec Planet hunting Planets in orbit around microlensing stars cause telltale distortions in the source star's light curve OGLE 2005-BLG-390Lb