Julien Devriendt

Merger Histories in Warm Dark Matter Structure Formation Scenario

(2001)

Authors:

Alexander Knebe, Julien Devriendt, Asim Mahmood, Joseph Silk

Star formation losses due to tidal debris in `hierarchical' galaxy formation

ArXiv astro-ph/0105152 (2001)

Authors:

BF Roukema, S Ninin, J Devriendt, F Bouchet, B Guiderdoni, GA Mamon

Abstract:

Bottom-up hierarchical formation of dark matter haloes is not as monotonic as implicitly assumed in the Press-Schechter formalism: matter can be ejected into tidal tails, shells or low density `atmospheres'. The implications that the possible truncation of star formation in these tidal `debris' may have for observational galaxy statistics are examined here using the ArFus N-body plus semi-analytical galaxy modelling software. Upper and lower bounds on stellar losses implied by a given set of N-body simulation output data can be investigated by choice of the merging/identity criterion of haloes between successive N-body simulation output times. A median merging/identity criterion is defined and used to deduce an upper estimate of possible star formation and stellar population losses. A largest successor merging/identity criterion is defined to deduce an estimate which minimises stellar losses. In the N-body simulations studied, the debris losses are short range in length and temporary; maximum loss is around 16%. The induced losses for star formation and luminosity functions are strongest (losses of 10%-30%) for low luminosity galaxies and at intermediate redshifts (1 < z < 3). This upper bound on likely losses is smaller than present observational uncertainties. Hence, Press-Schechter based galaxy formation models are approximately valid despite ignoring loss of debris, provided that dwarf galaxy statistics are not under study.

Star formation losses due to tidal debris in `hierarchical' galaxy formation

(2001)

Authors:

BF Roukema, S Ninin, J Devriendt, F Bouchet, B Guiderdoni, GA Mamon

Probing galaxy formation with high energy gamma-rays

AIP CONF PROC 558 (2001) 463-478

Authors:

JR Primack, RS Somerville, JS Bullock, JEG Devriendt

Abstract:

We discuss how measurements of the absorption of gamma -rays from GeV to TeV energies via pair production on the extragalactic background light (EBL) can probe important issues in galaxy formation. We use semi-analytic models (SAMs) of galaxy formation, set within the hierarchical structure formation scenario, to obtain predictions of the EEL from 0.1 to 1000 mum. SAMs incorporate simplified physical treatments of the key processes of galaxy formation - including gravitational collapse and merging of dark matter halos, gas cooling and dissipation, star formation, supernova feedback and metal production - and have been shown to reproduce key observations at low and high redshift. Here we also introduce improved modelling of the spectral energy distributions in the mid-to-far-IR arising from emission by dust grains. Assuming a flat ACDM cosmology with Omega (m) = 0.3 and Hubble parameter h = 0.65, we investigate the consequences of variations in input assumptions such as the stellar initial mass function (IMF) and the efficiency of converting cold gas into stars. We conclude that observational studies of the absorption of gamma -rays with energies from similar to 10 Gev to similar to 10 TeV will help to determine the EEL, and also help to explain its origin by constraining some of the most uncertain features of galaxy formation theory, including the IMF, the history of star formation, and the reprocessing of light by dust.

Source-lens clustering effects on the skewness of the lensing convergence

ArXiv astro-ph/0012200 (2000)

Authors:

Takashi Hamana, Stephane T Colombi, Aurelien Thion, Julien EGT Devriendt, Yannick Mellier, Francis Bernardeau

Abstract:

The correlation between source galaxies and lensing potentials causes a systematic effect on measurements of cosmic shear statistics, known as the source-lens clustering (SLC) effect. The SLC effect on the skewness of lensing convergence, $S_3$, is examined using a nonlinear semi-analytic approach and is checked against numerical simulations. The semi-analytic calculations have been performed in a wide variety of generic models for the redshift distribution of source galaxies and power-law models for the bias parameter between the galaxy and dark matter distributions. The semi-analytic predictions are tested successfully against numerical simulations. We find the relative amplitude of the SLC effect on $S_3$ to be of the order of five to forty per cent. It depends significantly on the redshift distribution of sources and on the way the bias parameter evolves. We discuss possible measurement strategies to minimize the SLC effects.