456 research outputs found
The First Supernova Explosions in the Universe
We investigate the supernova explosions that end the lives of massive
Population III stars in low-mass minihalos (M~10^6 M_sun) at redshifts z~20.
Employing the smoothed particle hydrodynamics method, we carry out numerical
simulations in a cosmological set-up of pair-instability supernovae with
explosion energies of E_SN=10^51 and 10^53 ergs. We find that the more
energetic explosion leads to the complete disruption of the gas in the
minihalo, whereas the lower explosion energy leaves much of the halo intact.
The higher energy supernova expels > 90% of the stellar metals into a region ~1
kpc across over a timescale of 3-5 Myr. Due to this burst-like initial star
formation episode, a large fraction of the universe could have been endowed
with a metallicity floor, Z_min>10^-4 Z_sun, already at z>15.Comment: Published in ApJ Letter
The Era of Massive Population III Stars: Cosmological Implications and Self-Termination
The birth and death of the first generation of stars have important
implications for the thermal state and chemical properties of the intergalactic
medium (IGM) in the early universe. Sometime after recombination, the neutral,
chemically pristine gas was reionized by ultraviolet photons emitted from the
first stars, but also enriched with heavy elements when these stars ended their
lives as energetic supernovae. Using the results from previous high-resolution
cosmological simulations of early structure formation that include radiative
transfer, we show that a significant volume fraction of the IGM can be
metal-polluted, as well as ionized, by massive Population III stars formed in
small-mass (10^6-10^7 Msun) halos early on. If most of the early generation
stars die as pair-instability supernovae with energies up to 10^{53} ergs, the
volume-averaged mean metallicity will quickly reach Z ~ 10^{-4}Zsun by a
redshift of 15-20, possibly causing a prompt transition to the formation of a
stellar population that is dominated by low-mass stars. In this scenario, the
early chemical enrichment history should closely trace the reionization history
of the IGM, and the end of the Population III era is marked by the completion
of reionization and pre-enrichment by z=15. We conclude that, while the
pre-enrichment may partially account for the ``metallicity-floor'' in
high-redshift Lyman-alpha clouds, it does not significantly affect the
elemental abundance in the intracluster medium.Comment: Version accepted by ApJ. Minor revisions and a few citations adde
Dark Matter Halo Environment for Primordial Star Formation
We study the statistical properties (such as shape and spin) of high-z halos
likely hosting the first (PopIII) stars with cosmological simulations including
detailed gas physics. In the redshift range considered () the
average sphericity is , and for more than 90% of halos the
triaxiality parameter is , showing a clear preference for
oblateness over prolateness. Larger halos in the simulation tend to be both
more spherical and prolate: we find and , with and at z = 11.
The spin distributions of dark matter and gas are considerably different at
, with the baryons rotating slower than the dark matter. At lower
redshift, instead, the spin distributions of dark matter and gas track each
other almost perfectly, as a consequence of a longer time interval available
for momentum redistribution between the two components. The spin of both the
gas and dark matter follows a lognormal distribution, with a mean value at z=16
of , virtually independent of halo mass. This is in good
agreement with previous studies. Using the results of two feedback models (MT1
and MT2) by McKee & Tan (2008) and mapping our halo spin distribution into a
PopIII IMF, we find that at high- the IMF closely tracks the spin lognormal
distribution. Depending on the feedback model, though, the distribution can be
centered at (MT1) or (MT2). At later
times, model MT1 evolves into a bimodal distribution with a second prominent
peak located at as a result of the non-linear relation between
rotation and halo mass. We conclude that the dark matter halo properties might
be a key factor shaping the IMF of the first stars.Comment: 10 pages, 6 figures, accepted for publication in MNRA
Population III stars and the Long Gamma Ray Burst rate
Because massive, low-metallicity population III (PopIII) stars may produce
very powerful long gamma-ray bursts (LGRBs), high-redshift GRB observations
could probe the properties of the first stars. We analyze the correlation
between early PopIII stars and LGRBs by using cosmological
N-body/hydrodynamical simulations, which include detailed chemical evolution,
cooling, star formation, feedback effects and the transition between PopIII and
more standard population I/II (PopII/I) stars. From the Swift observed rate of
LGRBs, we estimate the fraction of black holes that will produce a GRB from
PopII/I stars to be in the range 0.028<f_{GRB}<0.140, depending on the assumed
upper metallicity of the progenitor. Assuming that as of today no GRB event has
been associated to a PopIII star, we estimate the upper limit for the fraction
of LGRBs produced by PopIII stars to be in the range 0.006<f_{GRB}<0.022. When
we apply a detection threshold compatible with the BAT instrument, we find that
the expected fraction of PopIII GRBs (GRB3) is ~10% of the full LGRB population
at z>6, becoming as high has 40% at z>10. Finally, we study the properties of
the galaxies hosting our sample of GRB3. We find that the average metallicity
of the galaxies hosting a GRB3 is typically higher than the critical
metallicity used to select the PopIII stars, due to the efficiency in polluting
the gas above such low values. We also find that the highest probability of
finding a GRB3 is within galaxies with a stellar mass <10^7 Msun, independently
from the redshift.Comment: 8 pages,3 figures. Submitted to MNRAS, revised version after
referee's comment
Formation of the First Supermassive Black Holes
We consider the physical conditions under which supermassive black holes
could have formed inside the first galaxies. Our SPH simulations indicate that
metal-free galaxies with a virial temperature ~10^4 K and with suppressed H2
formation (due to an intergalactic UV background) tend to form a binary black
hole system which contains a substantial fraction (>10%) of the total baryonic
mass of the host galaxy. Fragmentation into stars is suppressed without
substantial H2 cooling. Our simulations follow the condensation of ~5x10^6
M_sun around the two centers of the binary down to a scale of < 0.1pc. Low-spin
galaxies form a single black hole instead. These early black holes lead to
quasar activity before the epoch of reionization. Primordial black hole
binaries lead to the emission of gravitational radiation at redshifts z>10 that
would be detectable by LISA.Comment: 11 pages, 9 figures, revised version, ApJ in press (October 10, 2003
Astrophysics: Most distant cosmic blast seen
The most distant -ray burst yet sighted is the earliest astronomical object
ever observed in cosmic history. This ancient beacon offers a glimpse of the
little-known cosmic dark ages.Comment: Published in Nature News & View
The First Supernova Explosions: Energetics, Feedback, and Chemical Enrichment
We perform three-dimensional smoothed particle hydrodynamics simulations in a
realistic cosmological setting to investigate the expansion, feedback, and
chemical enrichment properties of a 200 M_sun pair-instability supernova in the
high-redshift universe. We find that the SN remnant propagates for a Hubble
time at z = 20 to a final mass-weighted mean shock radius of 2.5 kpc (proper),
roughly half the size of the HII region, and in this process sweeps up a total
gas mass of 2.5*10^5 M_sun. The morphology of the shock becomes highly
anisotropic once it leaves the host halo and encounters filaments and
neighboring minihalos, while the bulk of the shock propagates into the voids of
the intergalactic medium. The SN entirely disrupts the host halo and terminates
further star formation for at least 200 Myr, while in our specific case it
exerts positive mechanical feedback on neighboring minihalos by
shock-compressing their cores. In contrast, we do not observe secondary star
formation in the dense shell via gravitational fragmentation, due to the
previous photoheating by the progenitor star. We find that cooling by metal
lines is unimportant for the entire evolution of the SN remnant, while the
metal-enriched, interior bubble expands adiabatically into the cavities created
by the shock, and ultimately into the voids with a maximum extent similar to
the final mass-weighted mean shock radius. Finally, we conclude that dark
matter halos of at least M_vir > 10^8 M_sun must be assembled to recollect all
components of the swept-up gas.Comment: 16 pages, 14 figures, published in Ap
VIRGO sensitivity to binary coalescences and the Population III black hole binaries
We analyze the properties of VIRGO detector with the aim of studying its
ability to search for coalescing black hole binaries. We focus on the remnants
of the Population III stars, which currently should be massive black holes
(), some of them bound in binary systems. The
coalescence of such binaries due to emission of gravitational waves may be
currently observable. We use a binary population synthesis to model the
evolution of Population III binaries. We calculate the signal to noise ratios
of gravitational waves emitted by the system in each of the coalescence phase:
inspiral, merger and ringdown, and provide simple formulae for the signal to
noise ratio as a function of masses of the binaries. We estimate the detection
rates for the VIRGO interferometer and also compare them with the estimates for
the current LIGO. We show that these expected rates are similar to, or larger
than the expected rates from coalescences of Population I and II compact object
binaries.Comment: sumbitted to A&
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