Beecroft Institute for Particle Astrophysics and Cosmology

The dusty, albeit ultraviolet bright infancy of galaxies

(2009)

Authors:

J Devriendt, C Rimes, C Pichon, R Teyssier, D Le Borgne, D Aubert, E Audit, S Colombi, S Courty, Y Dubois, S Prunet, Y Rasera, A Slyz, D Tweed

The Skeleton: Connecting Large Scale Structures to Galaxy Formation

ArXiv 0911.3779 (2009)

Authors:

Christophe Pichon, Christophe Gay, Dmitry Pogosyan, Simon Prunet, Thierry Sousbie, Stephane Colombi, Adrianne Slyz, Julien Devriendt

Abstract:

We report on two quantitative, morphological estimators of the filamentary structure of the Cosmic Web, the so-called global and local skeletons. The first, based on a global study of the matter density gradient flow, allows us to study the connectivity between a density peak and its surroundings, with direct relevance to the anisotropic accretion via cold flows on galactic halos. From the second, based on a local constraint equation involving the derivatives of the field, we can derive predictions for powerful statistics, such as the differential length and the relative saddle to extrema counts of the Cosmic web as a function of density threshold (with application to percolation of structures and connectivity), as well as a theoretical framework to study their cosmic evolution through the onset of gravity-induced non-linearities.

The Skeleton: Connecting Large Scale Structures to Galaxy Formation

(2009)

Authors:

Christophe Pichon, Christophe Gay, Dmitry Pogosyan, Simon Prunet, Thierry Sousbie, Stephane Colombi, Adrianne Slyz, Julien Devriendt

Einstein's Theory of Gravity and the Problem of Missing Mass

(2009)

Authors:

Pedro G Ferreira, Glenn Starkmann

Einstein's Theory of Gravity and the Problem of Missing Mass

ArXiv 0911.1212 (2009)

Authors:

Pedro G Ferreira, Glenn Starkmann

Abstract:

The observed matter in the universe accounts for just 5 percent of the observed gravity. A possible explanation is that Newton's and Einstein's theories of gravity fail where gravity is either weak or enhanced. The modified theory of Newtonian dynamics (MOND) reproduces, without dark matter, spiral-galaxy orbital motions and the relation between luminosity and rotation in galaxies, although not in clusters. Recent extensions of Einstein's theory are theoretically more complete. They inevitably include dark fields that seed structure growth, and they may explain recent weak lensing data. However, the presence of dark fields reduces calculability and comes at the expense of the original MOND premise -- that the matter we see is the sole source of gravity. Observational tests of the relic radiation, weak lensing, and the growth of structure may distinguish modified gravity from dark matter.