Permanent staff researchers:
M.Arnaud, H.Aussel, F.Bournaud, E.Daddi, P.-A. Duc, D.Elbaz (head), E.Le Floc’h, S.Juneau, R.Lehoucq, M.Pierre
(10 staff + 5 PhD + 15 postdocs)
Main research interests : The research activities of the LCEG group are primarily related to understanding :
- the main physical mechanisms responsible for the growth of galaxies in stellar and black hole mass
- what controls the mass assembly of galaxies at cosmological scales from a statistical perspective and in their environment
- the dominant physics governing large-scale structure formation, accounting for the roles of dark matter and dark energy.
Main instrumentation/observational perspective :
- Space far-infrared (Spitzer, Herschel) / "sub-mm" (Planck) / X-ray (XMM, Chandra) / optical (HST) astronomy
- Ground-based sub-mm/mm/radio (IRAM, JVLA), optical imaging and spectroscopy (CFHT, Keck & VLT)
Main modelling perspective :
- High-resolution numerical simulations from Mpc to sub-pc scale.
- Spectral energy distribution of galaxies, luminosity functions, galaxy counts, scaling laws of star-formation
- Structural and scaling properties of the galaxy cluster population across cosmic time
Broad picture and scientific identity of the LCEG team :
During the last five years, the members of the LCEG group have been actively involved in the observation and modelling of the formation/evolution of galaxies and galaxy clusters. Specific emphasis was put on the determination of the fundamental scaling laws describing the observational properties of star-forming galaxies and present-day galaxy clusters.
For galaxy formation, extending these fundamental relations to z>2 and understanding their physical origin has now become a major source of investigation worldwide. For galaxy clusters, scaling law evolution, selection effects and precision cosmological applications represent the next challenges.
These findings were made possible thanks to major observational programs with particular emphasis on the mid to far-infrared/sub-mm and X-ray domains of the electromagnetic spectrum. These important results build on the involvement of the SAp in the construction of Herschel and XMM instruments, on our participation in the Planck consortium and ground-based observations with IRAM in particular.
Bridging the multi-scale physics from Mpc to sub-pc scales, our interpretation of these results have strongly beneficiated from our numerical simulations of the sub-pc-scale physics regulating star-formation at galaxy scales. These simulations have revealed the key role of dynamical instabilities driven by cosmological infall of matter onto galaxies in explaining scaling laws at galactic scales.
maj : 18-01-2013 (977)