312 research outputs found
An Indicator of Nonlinear Gravitational Clustering
Alignment of velocity and acceleration before shell crossing, and later
misalignment are used to define velocity contrast, an indicator of dynamical
state of matter undergoing gravitational collapse. We use this to study bias in
clustering properties of dynamically nonlinear mass.Comment: 4 pages, uuencoded postscript file. To appear in 'Clusters, Lensing,
and the Future of the Universe' ed. V.Trimble and A.Reisenegge
A New Statistical Indicator to Study Nonlinear Gravitational Clustering and Structure Formation
In an expanding universe, velocity field and gravitational force field are
proportional to each other in the linear regime. Neither of these quantities
evolve in time and these can be scaled suitably so that the constant of
proportionality is unity and velocity and force field are equal. The Zeldovich
approximation extends this feature beyond the linear regime, until formation of
pancakes. Nonlinear clustering which takes place {\it after} the breakdown of
Zeldovich approximation, breaks this relation and the mismatch between these
two vectors increases as the evolution proceeds. We suggest that the difference
of these two vectors could form the basis for a powerful, new, statistical
indicator of nonlinear clustering. We define an indicator called velocity
contrast, study its behaviour using N-Body simulations and show that it can be
used effectively to delineate the regions where nonlinear clustering has taken
place. We discuss several features of this statistical indicator and provide
simple analytic models to understand its behaviour. Particles with velocity
contrast higher than a threshold have a correlation function which is biased
with respect to the original sample. This bias factor is scale dependent and
tends to unity at large scales.Comment: 12 pages, 8 figures, LaTeX with uuencoded figures, uses MN.sty and
epsf.sty; Discussion has been enlarged to clarify a few points. Introduction
has been added. Some figures have change
Critical Index and Fixed Point in the Transfer of Power in Nonlinear Gravitational Clustering
We investigate the transfer of power between different scales and coupling of
modes during non-linear evolution of gravitational clustering in an expanding
universe. We start with a power spectrum of density fluctuations that is
exponentially damped outside a narrow range of scales and use numerical
simulations to study evolution of this power spectrum. Non-Linear effects
generate power at other scales with most power flowing from larger to smaller
scales. The ``cascade'' of power leads to equipartition of energy at smaller
scales, implying a power spectrum with index . We find that such a
spectrum is produced in the range for density contrast
. This result continues to hold even when small scale power is added to
the initial power spectrum. Semi-analytic models for gravitational clustering
suggest a tendency for the effective index to move towards a critical index
in this range. For n<n_c, power in this range grows faster than
linear rate, while if n>n_c, it grows at a slower rate - thereby changing the
index closer to n_c. At scales larger than the narrow range of scales with
initial power, a k^4 tail is produced. We demonstrate that non-linear small
scales do not effect the growth of perturbations at larger scales.Comment: Title changed. Added two figures and some discussion. Postscript file
containing all the figures is available at
http://www.ast.cam.ac.uk/~jasjeet/papers/powspec.ps.gz Accepted for
publication in the MNRA
Comments on the size of the simulation box in cosmological N-Body simulations
N-Body simulations are a very important tool in the study of formation of
large scale structures. Much of the progress in understanding the physics of
high redshift universe and comparison with observations would not have been
possible without N-Body simulations. Given the importance of this tool, it is
essential to understand its limitations as ignoring the limitations can easily
lead to interesting but unreliable results. In this paper we study the
limitations arising out of the finite size of simulation volume. This finite
size implies that modes larger than the size of the simulation volume are
ignored and a truncated power spectrum is simulated. If the simulation volume
is large enough then the mass in collapsed haloes expected from the full power
spectrum and from the truncated power spectrum should match. We propose a
quantitative measure based on this approach that allows us to compute the
minimum box size for an N-Body simulation. We find that the required box size
for simulations of LCDM model at high redshifts is much larger than is
typically used. We can also use this approach to quantify the effect of
perturbations at large scales for power law models and we find that if we fix
the scale of non-linearity, the required box size becomes very large as the
index becomes small. The appropriate box size computed using this approach is
also an appropriate choice for the transition scale when tools like MAP (Tormen
and Bertschinger, 1996) that add the contribution of the missing power are
used.Comment: 7 pages, 8 figures, Accepted for publication in the MNRA
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