We describe results from a fully self-consistent three-dimensional hydrodynamical simulation of the formation of one of the first stars in the Universe. In current models of structure formation, dark matter initially dominates, and pregalactic objects form because of gravitational instability from small initial density perturbations. As they assemble via hierarchical merging, primordial gas cools through ro-vibrational lines of hydrogen molecules and sinks to the center of the dark matter potential well. The high-redshift analog of a molecular cloud is formed. As the dense, central parts of the cold gas cloud become self-gravitating, a dense core of ∼100 M ⊙ (where M ⊙ is the mass of the Sun) undergoes rapid contraction. At particle number densities greater than 10 9 per cubic centimeter, a 1 M ⊙ protostellar core becomes fully molecular as a result of three-body H 2 formation. Contrary to analytical expectations, this process does not lead to renewed fragmentation and only one star is formed. The calculation is stopped when optical depth effects become important, leaving the final mass of the fully formed star somewhat uncertain. At this stage the protostar is accreting material very rapidly (∼10 −2 M ⊙ year −1 ). Radiative feedback from the star will not only halt its growth but also inhibit the formation of other stars in the same pregalactic object (at least until the first star ends its life, presumably as a supernova). We conclude that at most one massive ( M ≫ 1 M ⊙ ) metal-free star forms per pregalactic halo, consistent with recent abundance measurements of metal-poor galactic halo stars.
We present the first results on the history of star formation in the universe based on the 'cosmic spectrum,' in particular the volume-averaged, luminosity-weighted, stellar abs...
view Abstract Citations (419) References (178) Co-Reads Similar Papers Volume Content Graphics Metrics Export Citation NASA/ADS Spectrophotometric Evolution of Elliptical Galaxi...
We study the constraints that high-redshift structure formation in the universe places on warm dark matter (WDM) dominated cosmological models. We modify the extended Press-Sche...
We present observations of SDSSp J104433.04--012502.2, a luminous quasar at z=5.80 discovered from Sloan Digital Sky Survey (SDSS) multicolor imaging data. This object was selec...
(abridged) We present measurements of galaxy-galaxy weak lensing from early commissioning imaging data from the Sloan Digital Sky Survey (SDSS). We measure a mean tangential she...
Social media, news, blog, policy document mentions