During the last decade, gravitational lensing is one of the few areas of astronomical research which has suffered a major development. Gravitational lenses have been converted into a powerful astrophysical tool in a wide variety of research fields, including: the scale for cosmological distances, the cosmic structure of the matter at large scales, the mass and its distribution in galaxy clusters, the physics of quasars and high-redshift galaxies, the haloes of dark matter in galaxies, among many others.
A gravitational lens is produced when the light from a distant source is deviated by a massive object (e.g. a galaxy or a cluster of galaxies) which lies along the line of sight to the observer. This effect makes the light from the distant object to be magnified and extended, boosting the probability for detection and incrementing its observed surface brightness. The gravitational lensing effect have been categorised in three main classes; (a) strong-lensing: that which produces rings, arcs and multiple imaging (with separation between images from 0.3 to 30 arc-seconds); (b) weak-lensing; that which produces weak distortions of distant objects, and it is observed statistically at the edge of massive objects, for example produced by groups or massive galaxy clusters; and (c) micro-lensing; that which produces micro-images of milli-arcsecond separations and manifest by an increment (or decrement) in the source brightness when monitored as a function of time.
To develop this field, our research group has endeavoured various collaborative projects which cover the following aspects of gravitational lensing:
- Strongly lensed galaxies, taken from the H-ATLAS and HerMES using the ALMA telescope at sub-millimetre wavelengths and by the JVLA, eMERLIN and EVN telescopes at radio wavelengths,
- Strong lensing effect produced by galaxy clusters identified in images and spectra taken with the telescopes Gemini and Hubble Space Telescope,
- Strong and weak lensing effect using groups of galaxies identified in data taken from the SL2S survey (created by the CFHT telescope), and analysing spectra taken with the VLT telescope,
- Micro-lensing effect produced by compact objects (e.g. black holes, stars, planets) to background stars from the galactic bulge using data from the VVV survey (taken with the VISTA telescope),
- Micro-lensing effect on extragalactic sources produced by compact objects (e.g. stars or sub-structure in dark matter haloes) in the haloes of the foreground galaxy using spectra taken with theVLT, MMT and WHT.
- STRong-lensing Insights into the Dark Energy Survey (STRIDES) search for new lensed quasar systems for cosmological applications (the evolution of elliptical galaxies, dark matter content).
- COSmological MOnitoring of GRAvItational Lenses (COSMOGRAIL) aims to measure time delays for most of the known lensed quasars (including the recently discovered by STRIDES).
Primary researchers in this area:
Students: Alejandra Melo (PhD) - Ramsés Jerez (MSc)
Past students: Evelyn Puebla (BSc.), Irma Fuentes (BSc.), Karina Rojas (BSc, MSc, PhD), Daniela Barrios (BSc), Ramsés Jerez (BSc)
Summer Practice students: Nicol Pizarro (UDLA), Francisca Contreras (UChile)
Postdocs: Thomas Hughes, Alejandra Muñoz-Arancibia
Past postdocs: Tomás Verdugo, Roberto Muñoz, Gael Foëx, Juan Magaña