• Edmund Bertschinger
• Claude Canizares
• Alan Guth
• Jacqueline Hewitt
• Paul Schechter
• Max Tegmark

Observational tests of the standard cosmological model during the last decade have ushered in a new era of precision cosmology. The standard model is specified by the size, spatial geometry (open, closed, or flat), and composition of the universe as well as the nature and statistical properties of the small-amplitude initial fluctuations that seeded the formation of galaxies and large scale structure in the universe. Astrophysical cosmology focuses on measuring the parameters of the standard model and studying the formation, evolution, and properties of cosmic structures. These structures include not only galaxies and the larger structures in which they congregate but also the supermassive black holes at their cores and the gas between galaxies.

The cosmic microwave background radiation offers stringent tests of the standard model through its fluctuations in temperature and polarization. Recent measurements strongly support a nearly spatially flat universe with small-amplitude density fluctuations having the power spectrum and other properties predicted by the inflationary model of Alan Guth. The next few years will see a wealth of new data offering much stronger tests of key parameters as well as signatures of the phenomena associated with galaxy formation such as cosmic reionization of hydrogen when the universe was about a tenth its present age. Theoretical work on the cosmic microwave background radiation is pursued by Edmund Bertschinger.

Accreting supermassive black holes, or quasars, provide a second probe of cosmological parameters and the physics of structure formation. Quasars serve as powerful light sources for studying intergalactic gas by absorption-line spectroscopy. As a member of the Sloan Digital Sky Survey, Burles has access to thousands of new quasars that will be followed up using the Magellan telescopes. Quasar absorption line spectroscopy provides a way to study many other phenomena occurring after cosmic reionization. The Magellan telescopes, with superb seeing and an adaptive optics program led by Paul Schechter, allow MIT astronomers to study objects at what is, effectively, the edge of the universe.

Gravitational lensing offers a third way to probe the fundamental cosmological parameters. In the last few years, astronomers using supernovae as standard candles have deduced that the expansion rate is currently increasing. Within the standard cosmological model, this surprising result implies that most of the energy density in the universe has a large negative pressure. Using both radio (Jacqueline Hewitt) and optical (Paul Schechter) techniques, MIT astronomers are measuring time delays in the multiple images of gravitationally lensed quasars to refine the measurement of the cosmic expansion history and thereby to deduce the equation of state on large scales in the universe.

MIT faculty are also active in the study of cosmic structure formation including galaxy formation and clustering. These studies involve theoretical modeling as well as observations spanning the electromagnetic spectrum from radio frequencies to gamma rays. Paul Schechter is a pioneer in the study of large scale structure through galaxy redshift surveys. Claude Canizares studies the physics of X-ray emitting plasma in clusters of galaxies and developed an instrument for high-resolution spectroscopy on the Chandra X-ray Observatory, one of NASA's four "great" observatories in space. Paul Schechter and Edmund Bertschinger have contributed to the basic theory through analytical models and computer simulations of structure formation.

Jacqueline Hewitt is a leader in a new international radio interferometer project called LOFAR, which will serve as a prototype for the Square Kilometer Array to be built about a decade from now. These instruments will study the beginning stages of galaxy formation occurring before the era of cosmic reionization several hundred million years after the big bang.

We now know that gamma-ray bursts occur in distant galaxies and, in about one minute, release a significant fraction of a solar mass of energy in MeV photons. While the cause of these explosions is still unclear, their occurrence at cosmological distances makes them a potentially powerful probe of cosmic structure formation. MIT developed the HETE satellite to rapidly identify and localize gamma ray bursts allowing prompt followup observations with the Magellan telescopes and other instruments.

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