Strong gravitational lensing

Gravitational lensing

Introduction Formalism Strong lensing Microlensing Weak lensing
Strong lens systems Abell 1689 · Abell 2218 CL0024+17 · Bullet Cluster QSO2237+0305 · SDSSJ0946+1006 B1359+154 · QSO 0957+561
Surveys Strong: CLASS · SLACS (SDSS) Micro: OGLE Weak: DLS · Pan-STARRS · CFHTLS · DES · LSST · SNAP · DESTINY

Strong gravitational lensing is a gravitational lensing effect that is strong enough to produce multiple images, arcs, or even Einstein rings. Generally, the strong lensing effect requires the projected lens mass density greater than the critical density $\Sigma _{{cr}}\,$ . For point-like background sources, there will be multiple images; for extended background emissions, there can be arcs or rings. Topologically, the multiple image production is governed by the odd number theorem.

Galaxy lensing

A light source passes behind a gravitational lens (point mass placed in the center of the image). The aqua circle is a source as it would be seen if there was no lens, white spots are the multiple images of the source.

The foreground lens is a galaxy. When the background source is a quasar or resolved jet, the strong lensed images are usually point-like multiple images; When the background source is a galaxy or extended jet emission, the strong lensed images can be arcs or rings.

Cluster lensing

The foreground lens is a galaxy cluster. In this case, the lens is usually powerful enough to produce noticeable both strong lensing (multiple images, arcs or rings) and weak lensing effects (ellipticity distortions).

Physics

Mass profiles (DC problems)

Since gravitational lensing is an effect only depending on gravitational potential, it can be used to constrain the mass model of lenses. With the constraints from multiple images or arcs, a proposed mass model can be optimized to fit to the observables. The subgalactic structures currently interests lensing astronomers are the central mass distribution and dark matter halos.

Time delays (AC problems)

Since the light rays go through different paths to produce multiple images, they will get delayed by local potentials along the light paths. The time delay differences from different images can be determined by the mass model and the cosmological model. Thus, with observed time delays and constrained mass model, the cosmological constant like Hubble constant can be inferred.

References

Schneider, P.; Ehlers, J,; Falco, E., 1992, "Gravitational Lenses", Springer-Verlag.

External links

CLASS survey database

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