374 research outputs found
The constancy of \zeta in single-clock Inflation at all loops
Studying loop corrections to inflationary perturbations, with particular
emphasis on infrared factors, is important to understand the consistency of the
inflationary theory, its predictivity and to establish the existence of the
slow-roll eternal inflation phenomena and its recently found volume bound. In
this paper we show that \zeta-correlators are time-independent at large
distances at all-loop level in single clock inflation. We write the n-th order
correlators of \dot\zeta\ as the time-integral of Green's functions times the
correlators of local sources that are function of the lower order fluctuations.
The Green's functions are such that only non-vanishing correlators of the
sources at late times can lead to non-vanishing correlators for \dot\zeta\ at
long distances. When the sources are connected by high wavenumber modes, the
correlator is peaked at short distances, and these diagrams cannot lead to a
time-dependence by simple diff. invariance arguments. When the sources are
connected by long wavenumber modes one can use similar arguments once the
constancy of \zeta\ at lower orders was established. Therefore the conservation
of \zeta\ at a given order follows from the conservation of \zeta\ at the lower
orders. Since at tree-level \zeta\ is constant, this implies constancy at
all-loops by induction.Comment: 14 pages, 3 figure
CMB Anisotropies from a Gradient Mode
A linear gradient mode must have no observable dynamical effect on short
distance physics. We confirm this by showing that if there was such a gradient
mode extending across the whole observable Universe, it would not cause any
hemispherical asymmetry in the power of CMB anisotropies, as long as
Maldacena's consistency condition is satisfied. To study the effect of the long
wavelength mode on short wavelength modes, we generalize the existing second
order Sachs-Wolfe formula in the squeezed limit to include a gradient in the
long mode and to account for the change in the location of the last scattering
surface induced by this mode. Next, we consider effects that are of second
order in the long mode. A gradient mode generated in Single-field inflation is shown to induce an observable
quadrupole moment. For instance, in a matter-dominated model it is equal to
. This quadrupole can be canceled
by superposition of a quadratic perturbation. The result is shown to be a
nonlinear extension of Weinberg's adiabatic modes: a long-wavelength physical
mode which looks locally like a coordinate transformation.Comment: 21+8 pages. improved presentatio
A Line of Sight Approach to Cosmic Microwave Background Anisotropies
We present a new method for calculating linear cosmic microwave background
(CMB) anisotropy spectra based on integration over sources along the photon
past light cone. In this approach the temperature anisotropy is written as a
time integral over the product of a geometrical term and a source term. The
geometrical term is given by radial eigenfunctions which do not depend on the
particular cosmological model. The source term can be expressed in terms of
photon, baryon and metric perturbations, all of which can be calculated using a
small number of differential equations. This split clearly separates between
the dynamical and geometrical effects on the CMB anisotropies. More
importantly, it allows to significantly reduce the computational time compared
to standard methods. This is achieved because the source term, which depends on
the model and is generally the most time consuming part of calculation, is a
slowly varying function of wavelength and needs to be evaluated only in a small
number of points. The geometrical term, which oscillates much more rapidly than
the source term, does not depend on the particular model and can be precomputed
in advance. Standard methods that do not separate the two terms and require a
much higher number of evaluations. The new method leads to about two orders of
magnitude reduction in CPU time when compared to standard methods and typically
requires a few minutes on a workstation for a single model. The method should
be especially useful for accurate determinations of cosmological parameters
from CMB anisotropy and polarization measurements that will become possible
with the next generation of experiments. A programm implementing this method
can be obtained from the authors.Comment: 20 pages, 5 figures. Fortran code available from the author
Double Soft Limits of Cosmological Correlations
Correlation functions of two long-wavelength modes with several
short-wavelength modes are shown to be related to lower order correlation
functions, using the background wave method, and independently, by exploiting
symmetries of the wavefunction of the Universe. These soft identities follow
from the non-linear extension of the adiabatic modes of Weinberg, and their
generalization by Hinterbichler et. al. The extension is shown to be unique. A
few checks of the identities are presented.Comment: 18+16 page
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