Liliya L.R. Williams
Associate Professor (Astronomy)
353 Tate, 624-1084, email llrw @ astro.umn.eduhttp://www.astro.umn.edu/~llrw/
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Most of my work has to do with dark matter: measuring the amount,
and spatial distribution of dark matter on a wide range of
astrophysical scales, from sub-galactic to super-cluster.
I am also working on the dynamics of dark matter halos in galaxies and clusters.
Local Organizing Committee, "Dark Side of the Universe", Fine Theoretical Physics Institute (FTPI), UMN, 2007, NSF Proposal Review Panel, 2007, NASA Astrophysics Theory Proposal Review Panel, 2006, Chandra X-ray Observatory Cycle 8 Proposal Review Panel, 2006, Local Organizing Committee, "Probing Early Structure Formation with Mass, Light and Chemistry", FTPI,UMN, 2005, Hubble Space Telescope Cycle 13 Proposal Review Panel, 2004, NSF Proposal Review Panel, 2004, Committee on the Status of Women of the American Astronomical Society, 2001-2004, Local Organizing Committee, "CMB and its Polarization", FTPI, UMN, 2003, Organizing Committee Member, ``Women in Astronomy II: Ten Years After'', 2003, Hubble Space Telescope Cycle 12 Proposal Review Panel, 2003, Local Organizing Committee, "Low Z at low z and high z", FTPI, UMN, 2002
Research Areas: Cosmology; distribution of dark matter; gravitational lensing; formation of structure [Research Group Web Page]
Current Research
Most of my work has to do with dark matter: measuring the amount,
and, more importantly, its spatial distribution on a wide range of
astrophysical scales, from sub-galactic to super-cluster.
Detailed knowledge of dark matter distribution will enable astronomers
and physicists to place constraints on the physical properties of
dark matter particles. Since dark matter is invisible, mapping out
its distribution must rely on indirect methods. While a few mass
reconstruction methods exist, gravitational lensing is the optimal
one, as it does not rely on any assumptions about the physical
state of the dark matter. Another interesting aspect of dark matter
is the study of its dynamics in galaxies and clusters. In the last
decade we have learned much about the properties of dark matter halos
from numerical computer simulations, however, understanding the
physics behind these results is still an open issue. This is the
other major direction of my research.
Selected Publications
Rudnick, L., Brown, S., and Williams, L.L.R., “Extragalactic Radio Sources and the WMAP Cold Spot.”, ApJ, (2007)
Saha, P., Williams, L.L.R., and Ferreras, I., “Meso-structure in Three Strong Lensing Systems”, ApJ (2007)
Barnes, E.I., Williams, L.L.R., Babul, A., and Dalcanton, J.J., “Velocity Distributions from Non- extensive Thermodynamics”, ApJ (2007)
Barnes, E.I., Williams, L.L.R., Babul, A., and Dalcanton, J.J., “Density Profiles of Collisionless Equilibria. II Anisotropic Spherical Systems”, ApJ (2007)
Saha, P., and Williams, L.L.R., “Gravitational Lensing Model Degeneracies: Is Steepness All Important?”, ApJ, (2006)
Education
Ph.D. 1995, Univ. of Washington